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The bacterial Sm-like protein Hfq: A key player in RNA transactions
Abstract
The conserved RNA-binding protein Hfq, originally discovered in Escherichia coli as a host factor for Qbeta replicase, has emerged as a pleiotropic regulator that modulates the stability or the translation of an increasing number of mRNAs. During the past 5 years, Hfq-mediated control has been an area of increasing focus because the protein has been linked to the action of many versatile RNA-based regulators that use basepairing interactions to regulate the expression of target mRNAs. The recent findings that Hfq assists in bimolecular RNA-RNA interactions and is similar structurally and functionally to eukaryotic Sm proteins have further fueled interest in this important post-transcriptional regulator. Here, we summarize the history of Hfq and highlight results that have led to an important gain in insight into the physiology, biochemistry and evolution of Hfq and its homologues.
... These proteins were not necessarily expected in archaea due to the absence of introns in their genes and their primitive RNA processing machinery [21]. On the other hand, bacterial Hfq proteins have many cellular functions [6]. For example, one of the identified functions of Hfq corresponds to its interaction with the sRNAs that regulate gene expression, cooperating as an RNA chaperone by facilitating the binding of regulatory sRNAs to their target mRNAs [22]. ...
... The Sm protein superfamily includes Sm and like-Sm (Lsm), found in the Eukarya and Archaea domains, respectively, and Hfq proteins, found in the Bacteria domain, and only one archaeon species, Methanocaldococcus jannaschii [1][2][3][4][5]. The Sm and Lsm proteins differ at the amino acid sequence level from Hfq; however, they show striking similarities in their tertiary and quaternary structure levels [3,6,7]. The Sm protein superfamily has a bipartite sequence known as the Sm motif, which consists of two segments, the Sm1 and Sm2 motifs, separated by a region of variable amino acid sequence and length [7]. ...
The Sm protein superfamily includes Sm, like-Sm (Lsm), and Hfq found in the Eukarya, Archaea, and Bacteria domains. Archaeal Lsm proteins have been shown to bind sRNAs and are probably involved in various cellular processes, suggesting a similar function in regulating sRNAs by Hfq in bacteria. Moreover, archaeal Lsm proteins probably represent the ancestral Lsm domain from which eukaryotic Sm proteins have evolved. In this work, Haloferax mediterranei was used as a model organism because it has been widely used to investigate the nitrogen cycle and its regulation in Haloarchaea. Predicting this protein’s secondary and tertiary structures has resulted in a three-dimensional model like the solved Lsm protein structure of Archaeoglobus fulgidus. To obtain information on the oligomerization state of the protein, homologous overexpression and purification by means of molecular exclusion chromatography have been performed. The results show that this protein can form hexameric complexes, which can aggregate into 6 or 12 hexameric rings depending on the NaCl concentration and without RNA. In addition, the study of transcriptional expression via microarrays has allowed us to obtain the target genes regulated by the Lsm protein under nutritional stress conditions: nitrogen or carbon starvation. Microarray analysis has shown the first universal stress proteins (USP) in this microorganism that mediate survival in situations of nitrogen deficiency.
... Later, it was found to involve in the virulence of Salmonella typhimurium [3]. Hfq could be identified as post transcriptional regulator for small RNA-mRNA complexes in many Bacteria [4]. Hfq and HfQ dependent small RNAs and their network are major contributors of virulence and development in Salmonella [5]. ...
... Hfq and HfQ dependent small RNAs and their network are major contributors of virulence and development in Salmonella [5]. Hfq suppress the translation by guarding sRNA so that it binds to 5' region of mRNA, thereby making 5' region inaccessible [4]. HfQ and RNAseE binds with similar region on RNA which facilitates coupled degradation of sRNA and its target mRNA in Escherichia coli [6]. ...
Hfq, RNA binding protein, is widely found in most of the prokaryotes. It plays a key role in gene regulation by binding with small RNA and facilitates mRNA pairing there by suppress or boost translation according to RNA structures. Interaction between sRNAs and HfQ in Salmonella SL1344 were screened using Co-Immuno Precipitation (HfQ-CoIP) studies earlier. We have formulated an In silico approach, to model the 3D structures of 155 sRNA and studied their interactions with HfQ proteins. We have reported the key interacting PHE42, LEU7, VAL27, PHE39 and PRO21 residues of HfQ binds with many small RNAs. Further mutation of PHE42 in to ALA42 in HfQ leads to loss of sRNA binding efficiency. We have differentiated the interactions in to HfQ binding and non-binding sRNAs, based on Atomic Contact Energy and area. This methodology may be applied generically for functional grouping of small RNAs in any organism.
... The transcriptome and proteome analysis of S. enterica revealed the role of Hfq under spaceflight conditions, similar to that identified in P. aeruginosa (Wilson et al., 2007). Hfq is an RNA-binding protein that is conserved in both prokaryotes and eukaryotes (Valentin-Hansen et al., 2004). It is known to be important for regulating the expression of various genes involved in virulence and stress resistance in several opportunistic pathogens, by stabilizing small regulatory RNAs and interfering with their interaction with mRNA molecules (Ding et al., 2004;Sittka et al., 2007;Sonnleitner et al., 2003;Valentin-Hansen et al., 2004). ...
... Hfq is an RNA-binding protein that is conserved in both prokaryotes and eukaryotes (Valentin-Hansen et al., 2004). It is known to be important for regulating the expression of various genes involved in virulence and stress resistance in several opportunistic pathogens, by stabilizing small regulatory RNAs and interfering with their interaction with mRNA molecules (Ding et al., 2004;Sittka et al., 2007;Sonnleitner et al., 2003;Valentin-Hansen et al., 2004). Another study involving a different species, Micrococcus luteus, reported an increase in production of extracellular polysaccharides and enhanced biofilm formation under spaceflight conditions (Mauclaire and Egli, 2010). ...
Microbial research in space is being conducted for almost 50 years now. The closed system of the International Space Station has acted as a microbial observatory for past ten years, conducting research on adaptation and survivability of microorganisms exposed to space conditions. This adaptation can either be beneficial or detrimental to crew members and spacecraft. Therefore, it becomes crucial to identify the impact of two primary stress conditions, namely, radiation and microgravity, on microbial life aboard the ISS. Elucidating the mechanistic basis of microbial adaptation to space conditions aids in development of countermeasures against their potentially detrimental effects and allows us to harness their biotechnologically important properties. Several microbial processes have been studied, either in spaceflight or using devices that can simulate space conditions. However, at present, research is limited to only a few microorganisms, and extensive research on biotechnologically important microorganisms is required to make long-term space missions self-sustainable.
... Intriguingly, a homolog of the RNA chaperone Hfq (encoded by Synpcc7942_1926) was also highly enriched by co-IP with both EbsA::FLAG and PilB::FLAG baits (Fig. 2). Hfq is a central bacterial regulator that acts at the posttranscriptional level by mediating mRNA-small RNA interactions (40)(41)(42)(43). These co-IP data suggest a tripartite complex of EbsA, PilB, and Hfq. ...
... The 79 proteins that are less abundant specifically in the hfqX mutant (Fig. 5C) may represent an indirect effect of the Hfq RNA chaperone on protein expression or secretion. Numerous studies of Hfq in heterotrophic bacteria revealed its involvement in the regulation of translation (40)(41)(42)(43). A role for cyanobacterial Hfq as an RNA chaperone has not been demonstrated yet; however, it is possible that it exerts translation regulation and that, consequently, the less abundant proteins unique to the hfqX mutant represent the outcome of the impact of Hfq on translation. ...
Protein secretion as well as the assembly of bacterial motility appendages are central processes that substantially contribute to fitness and survival. This study highlights distinctive features of the mechanism that serves these functions in cyanobacteria, which are globally prevalent photosynthetic prokaryotes that significantly contribute to primary production. Our studies of biofilm development in the cyanobacterium Synechococcus elongatus uncovered a novel component required for the biofilm self-suppression mechanism that operates in this organism. This protein, which is annotated as “hypothetical,” is denoted EbsA (essential for biofilm self-suppression A) here. EbsA homologs are highly conserved and widespread in diverse cyanobacteria but are not found outside this clade. We revealed a tripartite complex of EbsA, Hfq, and the ATPase homolog PilB (formerly called T2SE) and demonstrated that each of these components is required for the assembly of the hairlike type IV pili (T4P) appendages, for DNA competence, and affects the exoproteome in addition to its role in biofilm self-suppression. These data are consistent with bioinformatics analyses that reveal only a single set of genes in S. elongatus to serve pilus assembly or protein secretion; we suggest that a single complex is involved in both processes. A phenotype resulting from the impairment of the EbsA homolog in the cyanobacterium Synechocystis sp. strain PCC 6803 implies that this feature is a general cyanobacterial trait. Moreover, comparative exoproteome analyses of wild-type and mutant strains of S. elongatus suggest that EbsA and Hfq affect the exoproteome via a process that is independent of PilB, in addition to their involvement in a T4P/secretion machinery.
IMPORTANCE
Cyanobacteria, environmentally prevalent photosynthetic prokaryotes, contribute ∼25% of global primary production. Cyanobacterial biofilms elicit biofouling, thus leading to substantial economic losses; however, these microbial assemblages can also be beneficial, e.g., in wastewater purification processes and for biofuel production. Mechanistic aspects of cyanobacterial biofilm development were long overlooked, and genetic and molecular information emerged only in recent years. The importance of this study is 2-fold. First, it identifies novel components of cyanobacterial biofilm regulation, thus contributing to the knowledge of these processes and paving the way for inhibiting detrimental biofilms or promoting beneficial ones. Second, the data suggest that cyanobacteria may employ the same complex for the assembly of the motility appendages, type 4 pili, and protein secretion. A shared pathway was previously shown in only a few cases of heterotrophic bacteria, whereas numerous studies demonstrated distinct systems for these functions. Thus, our study broadens the understanding of pilus assembly/secretion in diverse bacteria and furthers the aim of controlling the formation of cyanobacterial biofilms.
... This indicates that although it is well established that Hfq is the element able of binding the mRNAs of the genes under carbon catabolite repression, when Crc is absent this repression is not exerted; even when CrcZ is absent and P. aeruginosa presents a constitutive hyperrepression phenotype. Hfq is an RNA chaperon ubiquitously distributed among several bacterial species, including those Escherichia coli that do not produce Crc (35). In the case of P. aeruginosa, it has been recently described that Hfq participates in the regulation of a variety of post-transcriptionally regulated bacterial pathways, besides carbon catabolic repression (20). ...
Pseudomonas aeruginosa is an opportunistic bacterial pathogen able to colonize a variety of habitats. Its success in colonizing these habitats relies on its metabolic robustness and its capability of efficiently using available carbon sources in a hierarchical way. P. aeruginosa carbon catabolic repression is post-transcriptionally regulated by Hfq and Crc, which form a complex that binds and impedes the translation of their target mRNAs. Under no catabolic repression conditions, the complex is sequestered by the small RNA CrcZ, allowing the translation of the involved mRNAs. In addition to regulating carbon sources use, Crc and Hfq modulate P. aeruginosa virulence and antibiotic resistance. In the absence of CrcZ, catabolic repression should be constitutive, severely impairing P. aeruginosa fitness. A Δ crcZ mutant was generated. As predicted, it presents severe fitness defects and alterations in virulence and antibiotic resistance. Pseudo-revertants that restore P. aeruginosa fitness, antibiotic resistance, and virulence were selected. Notably, most pseudo-revertants presented mutations in crc , despite Hfq, not Crc, being the RNA-binding protein of the complex. The analysis of several traits, including antibiotic resistance and bacterial virulence of these mutants, indicates that they can be grouped into two categories, those in which Crc is fully inactivated and those presenting smaller structural changes. The phenotypes of the latter resembling those of the wild-type strain. Notably, even when Hfq is not sequestered by CrcZ, in the Δ crcZ mutant, the lack of Crc impedes a proficient catabolic repression, indicating that Crc is strictly required for keeping P. aeruginosa metabolic robustness, virulence, and antibiotic resistance.
IMPORTANCE
Hfq and Crc regulate P. aeruginosa carbon catabolic repression at the post-transcriptional level. In vitro work has shown that Hfq binds the target RNAs and Crc stabilizes the complex. A third element in the regulation is the small RNA CrcZ, which sequesters the Crc-Hfq complex under no catabolic repression conditions, allowing the translation of the target mRNAs. A Δ crcZ mutant was generated and presented fitness defects and alterations in its virulence potential and antibiotic resistance. Eight pseudo-revertants that present different degrees of fitness compensation were selected. Notably, although Hfq is the RNA binding protein, most mutations occurred in Crc. This indicates that Crc is strictly needed for P. aeruginosa efficient carbon catabolic repression in vivo . The compensatory mutations restore in a different degree the alterations in antibiotic susceptibility and virulence of the Δ crcZ mutant, supporting that Crc plays a fundamental role linking P. aeruginosa metabolic robustness, virulence, and antibiotic resistance.
... H fq (host factor 1) is a highly conserved protein found in about two-thirds of bacteria 1 . In Gram-negative bacteria, it is implicated in the post-transcriptional stress response through its RNA chaperone function and modulates mRNA translation using small noncoding RNAs (sRNA) 2,3 . Containing an Sm-like globular domain 4 , Hfq assembles into a homohexameric ring with structurally unlike surfaces, characterized by an electropositive proximal and a non-polar distal face, both of which can interact with RNA [5][6][7] , as well as the convex rim 8 . ...
Hfq is a pleitropic actor that serves as stress response and virulence factor in the bacterial cell. To execute its multiple functions, Hfq assembles into symmetric torus-shaped hexamers. Extending outward from the hexameric core, Hfq presents a C-terminal region, described as intrinsically disordered in solution. Many aspects of the role and the structure of this region remain unclear. For instance, in its truncated form it can promote amyloid-like filament assembly. Here, we show that a minimal 11-residue motif at the C-terminal end of Hfq assembles into filaments with amyloid characteristics. Our data suggest that the full-length Hfq in its filamentous state contains a similar molecular fingerprint than that of the short β-strand peptide, and that the Sm-core structure is not affected by filament formation. Hfq proteins might thus co-exist in two forms in vivo, either as isolated, soluble hexamers or as self-assembled hexamers through amyloid-reminiscent interactions, modulating Hfq cellular functions.
... Hfq can simultaneously bind and alter secondary structures of sRNAs and mRNA targets to promote the sRNA-mRNA base-pairing. Hfq may also serve as a platform to increase the local concentrations of sRNAs and their mRNA targets (Valentin-Hansen et al. 2004;Aiba 2007;Brennan and Link 2007). The structures of individual sRNAs play an important role in competition among sRNAs for binding to Hfq and in the recognition of cognate sRNA-mRNA pairs by Hfq (Santiago-Frangos and Woodson 2018; Roca et al. 2022). ...
Small non-coding RNAs are an important class of regulatory RNAs in bacteria, often regulating responses to changes in environmental conditions. OxyS is a 110 nucleotide, stable, trans-encoded small RNA found in Escherichia coli and is induced by an increased concentration of hydrogen peroxide. OxyS has an important regulatory role in cell stress response, affecting the expression of multiple genes. In this work, we investigated the structure of OxyS and the interaction with fhlA mRNA using nuclear magnetic resonance spectroscopy, small-angle X-ray scattering and unbiased molecular dynamics simulations. We determined the secondary structures of isolated stem-loops and confirmed their structural integrity in OxyS. Unexpectedly, stem-loop SL4 was identified in the region that was predicted to be unstructured. Three-dimensional models of OxyS demonstrate that OxyS adopts an extended structure with four solvent-exposed stem-loops, which are available for interaction with other RNAs and proteins. Furthermore, we provide evidence of base pairing between OxyS and fhlA mRNA.
... Sm and Lsm proteins are found in Eukarya and Archaea domains, respectively, while Hfq proteins exist in the Bacteria domain and one archaeon species, Methanocaldococcus jannaschii [2][3][4][5]. Sm and Lsm proteins differ at the amino acid sequence level from Hfq; however, they show striking similarities in their tertiary and quaternary structure levels [3,6,7]. This Sm protein superfamily has a bipartite sequence known as the Sm motif, which consists of two segments, the Sm1 and Sm2 motifs, separated by a region of variable amino acid sequence and length [7]. ...
The Sm protein superfamily includes Sm, like-Sm (Lsm), and Hfq proteins. Sm and Lsm proteins are found in the Eukarya and Archaea domains, respectively, while Hfq proteins exist in the Bacteria domain. Even though Sm and Hfq proteins have been extensively studied, archaeal Lsm proteins still require further exploration. In this work, different bioinformatics tools are used to understand the diversity and distribution of 168 Lsm proteins in 109 archaeal species to increase the global understanding of these proteins. All 109 archaeal species analyzed encode one to three Lsm proteins in their genome. Lsm proteins can be classified into two groups based on molecular weight. Regarding the gene environment of lsm genes, many of these genes are located adjacent to transcriptional regulators of the Lrp/AsnC and MarR families, RNA-binding proteins, and ribosomal protein L37e. Notably, only proteins from species of the class Halobacteria conserved the internal and external residues of the RNA-binding site identified in Pyrococcus abyssi, despite belonging to different taxonomic orders. In most species, the Lsm genes show associations with 11 genes: rpl7ae, rpl37e, fusA, flpA, purF, rrp4, rrp41, hel308, rpoD, rpoH, and rpoN. We propose that most archaeal Lsm proteins are related to the RNA metabolism, and the larger Lsm proteins could perform different functions and/or act through other mechanisms of action.
... It was first discovered as an essential host factor for Qβ phage RNA replication in Escherichia coli. It shares a high degree of structural similarity with the eukaryotic spliceosome Sm protein involved in RNA degradation (Franze de Fernandez et al., 1968;Valentin-Hansen et al., 2004;Sauer, 2013), and its monomeric secondary structure is relatively conserved in different bacteria, comprising a solid N-terminal Sm domain and a looser and more variable C-terminus (Schumacher et al., 2002), where, the Sm domain is the core region of Hfq for RNA binding, which is consisted of a Sm1 motif with β1-β3 strands and a Sm2 motif with β4-β5 strands (Beich-Frandsen et al., 2011;Vincent et al., 2012). Bacterial intracellular Hfq proteins all form cyclic hexameric structures, showing two asymmetric polar faces, namely the proximal and distal polar faces. ...
Bacillus thuringiensis (Bt) is one of the most widely used bio-insecticides at present. It can produce many virulence factors and insecticidal crystal proteins during growth and sporulation. Hfq, on the other hand, is a bacterial RNA chaperone that can regulate the function of different kinds of RNAs, thereby affecting various bacterial phenotypes. To further explore the physiological functions of Hfq in Bt, we took BMB171 as the starting strain, knocked out one, two, or three hfq genes in its genome in different combinations, and compared the phenotypic differences between the deletion mutant strains and the starting strain. We did observe significant changes in several phenotypes, including motility, biofilm formation, sporulation, and insecticidal activity against cotton bollworm, among others. Afterward, we found through transcriptome studies that when all hfq genes were deleted, 32.5% of the genes in Bt were differentially transcribed, with particular changes in the sporulation-related and virulence-related genes. The above data demonstrated that Hfq plays a pivotal role in Bt and can regulate its various physiological functions. Our study on the regulatory mechanism of Hfq in Bt, especially the mining of the regulatory network of its sporulation and insecticidal activity, could lay a theoretical foundation for the better utilization of Bt as an effective insecticide.
... Although Hfq does not degrade RNA, it can bind to small RNAs (sRNAs) and promote annealing between sRNAs and their target mRNAs, thereby regulating the stability and translation of these mRNAs 173,174 . In fact, Hfq is now recognized as a global regulator that controls cell fitness under various conditions 175,176 . Another RNA chaperone of similar functional relevance as Hfq in the Enterobacteriaceae, which was more recently recognized, is ProQ 177 . ...
RNA turnover plays critical roles in the regulation of gene expression and allows cells to respond rapidly to environmental changes. In bacteria, the mechanisms of RNA turnover have been extensively studied in the models Escherichia coli and Bacillus subtilis, but not much is known in other bacteria. Cyanobacteria are a diverse group of photosynthetic organisms that have great potential for the sustainable production of valuable products using CO 2 and solar energy. A better understanding of the regulation of RNA decay is important for both basic and applied studies of cyanobacteria. Genomic analysis shows that cyanobacteria have more than 10 ribonucleases and related proteins in common with E. coli and B. subtilis, and only a limited number of them have been experimentally investigated. In this review, we summarize the current knowledge about these RNA-turnover-related proteins in cyanobacteria. Although many of them are biochemically similar to their counterparts in E. coli and B. subtilis, they appear to have distinct cellular functions, suggesting a different mechanism of RNA turnover regulation in cyanobacteria. The identification of new players involved in the regulation of RNA turnover and the elucidation of their biological functions are among the future challenges in this field.
... In fact, base-pairing between sRNAs and their target mRNAs modifies the accessibility of RNases and/or ribosome binding sites, thereby influencing gene expression [20,21]. The action of sRNAs often depends on the RNA chaperone Hfq that can facilitate and stabilize the interactions between the sRNAs and their target mRNAs [20,22]. Hfq has pleiotropic effects, and it is decisive for many sRNA-mediated regulation pathways, as its deletion affects the stress response, virulence, and biofilms in several bacteria [23,24]. ...
Biofilms provide an ecological advantage against many environmental stressors, such as pH and temperature, making it the most common life‐cycle stage for many bacteria. These protective characteristics make eradication of bacterial biofilms challenging. This is especially true in the health sector where biofilm formation on hospital or patient equipment, such as respirators, or catheters, can quickly become a source of anti‐microbial resistant (AMR) strains. Biofilms are complex structures encased in a self‐produced polymeric matrix containing numerous components such as polysaccharides, proteins, signalling molecules, extracellular DNA, and extracellular RNA. Biofilm formation is tightly controlled by several regulators, including quorum sensing (QS), cyclic diguanylate (c‐di‐GMP) and small non‐coding RNAs (sRNAs). These three regulators in particular are fundamental in all stages of biofilm formation; in addition, their pathways overlap, and the significance of their role is strain‐dependent. Currently, ribonucleases are also of interest for their potential role as biofilm regulators, and their relationships with QS, c‐di‐GMP and sRNAs have been investigated. This review article will focus on these four biofilm regulators (ribonucleases, QS, c‐di‐GMP and sRNAs) and the relationships between them.
... There are RNA binding proteins (RBPs) as well. These regulatory RBPs bind to the ribosome binding site (RBS) to directly regulate the accessibility of ribosomes, or bind to the nearby sites to open/close the SD sequence or to open RNase binding site for rapid degradation [13,[15][16][17]. Therefore, translation efficiency is regulated by the sequence features embedded in 5' UTR of mRNAs and corresponding RBPs that bind to the sequences. ...
AU-rich elements in 5’ untranslated region (UTR) are known to increase translation efficiency by recruiting S1 protein that facilitates the assembly of ribosomes. However, AU-rich elements also serve a binding site for Hfq protein, RNase E, etc. To investigate their roles in translation, mRNAs containing either an AU-rich element, originated from sodB 5’-UTR or a non-AU-rich element were constructed. The non-AU-rich elements were designed to retain the thermodynamics of the AUrich element-containing mRNAs to reduce structural effect on translation. The AU-rich element increased mRNA translation and knock-down of S1 protein decreased the translation of AU-rich element-containing mRNAs, confirming the essential role of S1 protein in translation. When their mRNA levels were measured in hfq-deleted cells, those containing a non-AU-rich element and a high AU-content N-terminal coding sequence decreased, representing an auxiliary role of Hfq in translation, specifically in mRNA protection. Interestingly, despite of decreased mRNA level in hfq-deleted cells, protein production was increased, implying the involvement of unknown factors in translation. Consequently, these results suggest that actively translating ribosomes recruited by S1 protein at an AU-rich element stabilize mRNAs from degradation. In the absence of S1 protein, Hfq protein protects mRNAs from degradation. Moreover, AU-rich elements can be used for improved protein production.
... Hfq has also been shown to promote the RNA degradosome recruitment to sRNA:mRNA complexes, inducing their rapid degradation [20,[36][37][38]. This is consistent with the observation that in a Δhfq strain, sRNA-mediated degradation of mRNAs is decreased or even abolished [39][40][41] Notably, we recently demonstrated that Hfq binding to the target hdeD is critical to promote sRNA-dependent degradation by RNase E [42]. Studies investigating global Hfq binding sites indicated additional mRNAs bound to the protein [31,32]. ...
Many RNA-RNA interactions depend on molecular chaperones to form and remain stable in living cells. A prime example is the RNA chaperone Hfq, which is a critical effector involved in regulatory interactions between small RNAs (sRNAs) and cognate target mRNAs in Enterobacteriaceae. While there is a great deal of in vitro biochemical evidence supporting the model that Hfq enhances rates or affinities of sRNA:mRNA interactions, there is little corroborating in vivo evidence. Here we used in vivo tools including reporter genes, co-purification assays, and super-resolution microscopy to analyze the role of Hfq in RyhB-mediated regulation, and we found that Hfq is often unnecessary for efficient RyhB:mRNA complex formation in vivo. Remarkably, our data suggest that a primary function of Hfq is to promote RyhB-induced cleavage of mRNA targets by RNase E. Moreover, our work indicates that Hfq plays a more limited role in dictating regulatory outcomes following sRNAs RybB and DsrA complex formation with specific target mRNAs. Our investigation helps evaluate the roles played by Hfq in some RNA-mediated regulation.
... Hfq was first discovered to be an essential host factor required for the RNA synthesis of Escherichia coli phage Qβ (Franze de Fernandez et al., 1968), but was later found to be a common RNA chaperone protein in bacteria. Like the Sm and Lsm spliceosome proteins, which are mainly involved in RNA degradation in eukaryotes and archaea, Hfq also belongs to the Sm/Lsm family of RNA-binding proteins (Valentin-Hansen et al., 2004). The secondary structure of various Hfq protein monomers in different bacteria is highly conserved, with all containing a conserved Sm domain for RNA binding (Beich-Frandsen et al., 2011;Vincent et al., 2012;Mura et al., 2013;Santiago-Frangos and Woodson, 2018). ...
RNA chaperone protein Hfq is an important post-transcriptional regulator in bacteria, while c-di-GMP is a second messenger signaling molecule widely distributed in bacteria. Both factors have been found to play key roles in post-transcriptional regulation and signal transduction pathways, respectively. Intriguingly, the two factors show some common aspects in the regulation of certain physiological functions such as bacterial motility, biofilm formation, pathogenicity and so on. Therefore, there may be regulatory relationship between Hfq and c-di-GMP. For example, Hfq can directly regulate the activity of c-di-GMP metabolic enzymes or alter the c-di-GMP level through other systems, while c-di-GMP can indirectly enhance or inhibit the hfq gene expression through intermediate factors. In this article, after briefly introducing the Hfq and c-di-GMP regulatory systems, we will focus on the direct and indirect regulation reported between Hfq and c-di-GMP, aiming to compare and link the two regulatory systems to further study the complicated physiological and metabolic systems of bacteria, and to lay a solid foundation for drawing a more complete global regulatory network.
... Similar to eukaryotic miRNAs, bacterial sRNAs have multiple targets and regulate them in trans as well as cis acts by base-pairing in anti-sense orientation with complementary sequence of its target mRNAs [18]. Bacterial sRNA commonly required the smlike RNA-binding protein called Hfq, which interacts with both sRNA and mRNA and facilitates the interaction between anti-sense sRNA and their binding target mRNAs in post transcriptionally [19,20]. Hfq also can serve alone as translational repressor of mRNA [21,22]. ...
Pseudomonas aeruginosa, is a gram-negative bacterium causes opportunistic or nosocomial infections in immunocompromised individuals. In recent years, a steady increase in human corneal infections of P. aeruginosa has been reported with increased multi-drug resistance (MDR) or extensively drug resistance (XDR). Several non-coding sRNAs, has been identified to regulate various physiological processes in P. aeruginosa, including biofilm formation, quorum sensing. However, the regulatory mechanism of sRNAs in MDR/XDR pathways of P. aeruginosa keratitis strains is not yet studied. In this study, we identified bacterial sRNAs in publicly available P. aeruginosa keratitis genomes and investigated their regulatory role in MDR/XDR pathways using bioinformatic analysis. Totally, 46 P. aeruginosa keratitis strains from different geographical regions were included. Of 46, Eight (30%) out of Twenty-seven and Nine (52%) out of Nineteen P. aeruginosa strains from India and Australia were identified as not-MDR. Whereas, 10 (38%) Indian and 9 (47%) Australian strains were identified as MDR. Eight Indian strains were identified as XDR. Out of 46 strains, 23 (50%) carried ExoU, 21(45%) carried ExoS and two (5%) strains carried both ExoU and ExoS, exotoxins for their virulence. The sRNA, SPA0021 was identified in 18 MDR/XDR and 6 not-MDR strains along with UCBPP-PA14. Interestingly, majority of the imipenem resistant P. aeruginosa keratitis strains from the present study was found to be carried SPA0023 sRNA (18 out of 30 strains). The outer membrane porin protein OprD, identified as binding target of SPA0023. Negative regulation or inactivation of OprD, reported in increased imipenem resistance in P. aeruginosa. Mutation analysis revealed that SPA0023 carrying P. aeruginosa keratitis strains contains a lesser number of amino acid changes in OprD protein than other strains. These findings indicate, imipenem resistance in SPA0023 carried strains might arose from the negative regulation or inhibition of OprD by SPA0023. However, functional studies are warranted with large number of P. aeruginosa keratitis strains to confirm the negative regulation of OprD by SPA0023 and imipenem resistance.
... Occasionally, pairing results in coupled degradation of sRNA and target mRNA (6). Since trans-encoded sR-NAs are only partially complementary to their target mR-NAs, most of them require the RNA chaperone Hfq for hybrid formation and consequently for their regulatory function (7,8) and can modulate expression of multiple targets (1,2). ...
Tight control of cell division is essential for survival of most organisms. For prokaryotes, the regulatory mechanisms involved in the control of cell division are mostly unknown. We show that the small non-coding sRNA StsR has an important role in controlling cell division and growth in the alpha-proteobacterium Rhodobacter sphaeroides. StsR is strongly induced by stress conditions and in stationary phase by the alternative sigma factors RpoHI/HII, thereby providing a regulatory link between cell division and environmental cues. Compared to the wild type, a mutant lacking StsR enters stationary phase later and more rapidly resumes growth after stationary phase. A target of StsR is UpsM, the most abundant sRNA in the exponential phase. It is derived from partial transcriptional termination within the 5′ untranslated region of the mRNA of the division and cell wall (dcw) gene cluster. StsR binds to UpsM as well as to the 5′ UTR of the dcw mRNA and the sRNA-sRNA and sRNA-mRNA interactions lead to a conformational change that triggers cleavage by the ribonuclease RNase E, affecting the level of dcw mRNAs and limiting growth. These findings provide interesting new insights into the role of sRNA-mediated regulation of cell division during the adaptation to environmental changes.
... A large number of sRNAs were found in an analysis of H. pylori primary transcriptome study (Rieder et al., 2012). Reports show that bacterial Sm-like protein Hfq is necessary for effective function of sRNA (Valentin-Hansen et al., 2004). However, Hfq, an RNA molecular chaperone, is absent in H. pylori. ...
Gastric cancer is a common malignant tumor of the digestive system. Its occurrence and development are the result of a combination of genetic, environmental, and microbial factors. Helicobacter pylori infection is a chronic infection that is closely related to the occurrence of gastric tumorigenesis. Non-coding RNA has been demonstrated to play a very important role in the organism, exerting a prominent role in the carcinogenesis, proliferation, apoptosis, invasion, metastasis, and chemoresistance of tumor progression. H. pylori infection affects the expression of non-coding RNA at multiple levels such as genetic polymorphisms and signaling pathways, thereby promoting or inhibiting tumor progression or chemoresistance. This paper mainly introduces the relationship between H. pylori -infected gastric cancer and non-coding RNA, providing a new perspective for gastric cancer treatment.
... Hfq is a global regulator response to microgravity and is conserved in a wide range of microorganism species, regardless of prokaryotes and eukaryotes. The nature of Hfq is an RNAbinding protein which acts as a chaperone to interact with some RNA molecules, like mRNA, miRNA and siRNA (Valentin-Hansen et al., 2004;Wilson et al., 2007). When microgravity or other environmental stresses exist, the cell growth rate decreases, which in turn increases the intracellular level of Hfq. ...
Regardless of bacteria or eukaryotic microorganism hosts, improving their ability to express heterologous proteins is always a goal worthy of elaborate study. In addition to traditional methods including intracellular synthesis process regulation and extracellular environment optimization, some special or extreme conditions can also be employed to create an enhancing effect on heterologous protein production. In this review, we summarize some extreme environmental factors used for the improvement of heterologous protein expression, including low temperature, hypoxia, microgravity and high osmolality. The applications of these strategies are elaborated with examples of well-documented studies. We also demonstrated the confirmed or hypothetical mechanisms of environment stress affecting the host behaviors. In addition, multi-omics techniques driving the stress-responsive research for construction of efficient microbial cell factories are also prospected at the end.
... Hence, we considered the possibility that the stability of zapB mRNA might be controlled by a sRNA, either destabilizing the transcript in LB or stabilizing the transcript in the presence of DOC. Because most bacterial small regulatory RNAs require the Hfq chaperone for interaction with the target and for stability of the sRNA itself (Valentin-Hansen et al., 2004;McCullen et al., 2010;Soper et al., 2011), we analyzed the stability of zapB mRNA in an Hfq − strain using Northern blotting (Figure 4). In the Hfq − background, the stability of the zapB transcript with and without DOC was similar to the stability of zapB mRNA in the wild type strain grown in LB, suggesting that stabilization of zapB mRNA in the presence of DOC requires the Hfq RNA chaperone (Figures 4A,B). ...
Genes annotated as ygfE and yiiU in the genome of Salmonella enterica serovar Typhimurium encode proteins homologous to Escherichia coli cell division factors ZapA and ZapB, respectively. ZapA ⁻ and ZapB ⁻ mutants of S. enterica are bile-sensitive. The amount of zapB mRNA increases in the presence of a sublethal concentration of sodium deoxycholate (DOC) while zapA mRNA remains unaffected. Increased zapB mRNA level in the presence of DOC is not caused by upregulation of zapB transcription but by increased stability of zapB mRNA. This increase is suppressed by an hfq mutation, suggesting the involvement of a small regulatory RNA. We provide evidence that such sRNA is MicA. The ZapB protein is degraded in the presence of DOC, and degradation appears to involve the Lon protease. We propose that increased stability of zapB mRNA in the presence of DOC may counter degradation of bile-damaged ZapB, thereby providing sufficient level of functional ZapB protein to permit Z-ring assembly in the presence of bile.
... Overview of hfq, motility and chemotaxis hfq hfq. Hfq has emerged as an important post-transcriptional factor that facilitates the pairing of small RNAs with their target mRNAs; its role in bacteria has been recently reviewed [80][81][82] . To highlight its importance, in some organisms it can impact expression of up to 20% of all genes 83 85 ; they have also been shown to play a role in pathogenicity 9,91-93 and biofilm formation 13,94 . ...
As interest in space exploration rises, there is a growing need to quantify the impact of microgravity on the growth, survival, and adaptation of microorganisms, including those responsible for astronaut illness. Motility is a key microbial behavior that plays important roles in nutrient assimilation, tissue localization and invasion, pathogenicity, biofilm formation, and ultimately survival. Very few studies have specifically looked at the effects of microgravity on the phenotypes of microbial motility. However, genomic and transcriptomic studies give a broad general picture of overall gene expression that can be used to predict motility phenotypes based upon selected genes, such as those responsible for flagellar synthesis and function and/or taxis. In this review, we focus on specific strains of Gram-negative bacteria that have been the most studied in this context. We begin with a discussion of Earth-based microgravity simulation systems and how they may affect the genes and phenotypes of interest. We then summarize results from both Earth- and space-based systems showing effects of microgravity on motility-related genes and phenotypes.
... For example, Hfq protein is associated with stress resistance in E. coli [38] and it showed to be crucial for cell survival under nutrient limitation [54]. Hfq protein is also known as a global regulator and is involved in posttranscriptional regulation by facilitating the interaction between small regulatory RNAs (sRNAs) and mRNAs [55,56], and regulations of RNA stability [57,58]. Hfq protein also controls the activity of several proteins involved in mRNA turnover by directly or indirectly interacting with RNase E [59], polynucleotide phosphorylase, and poly(A) polymerase [60][61][62][63]. ...
Escherichia coli is a widely used platform for metabolic engineering due to its fast growth and well-established engineering techniques. However, there has been a demand for faster-growing E. coli for higher production of desired substances. Here, to increase the growth of E. coli cells, we optimized the expression level of Hfq protein, which plays an essential role in stress responses. Six variants of the hfq gene with a different ribosome binding site sequence and thereby a different expression level were constructed. When the Hfq expression level was optimized in DH5α, its growth rate was increased by 12.1% and its cell density was also increased by 4.5%. RNA-seq and network analyses revealed the upregulation of stress response genes and metabolic genes, which increases the tolerance against pH changes. When the same strategy was applied to five other E. coli strains (BL21 (DE3), JM109, TOP10, W3110, and MG1655), all their growth rates were increased by 18–94% but not all their densities were increased (− 12 − + 32%). In conclusion, the Hfq expression optimization can increase cell growth rate and probably their cell densities as well. Since the hfq gene is highly conserved across bacterial species, the same strategy could be applied to other bacterial species to construct faster-growing strains.
... It should be emphasized that a careful accounting of SgrS mutations' effects on SgrS lifetimes was necessary to reach this conclusion. Microscopic mechanisms for Hfq's role in sRNA-mRNA annealing are still a subject of active research 60,65,66 , and may be investigated in the future using our analysis platform. ...
Base-pairing interactions mediate many intermolecular target recognition events. Even a single base-pair mismatch can cause a substantial difference in activity but how such changes influence the target search kinetics in vivo is unknown. Here, we use high-throughput sequencing and quantitative super-resolution imaging to probe the mutants of bacterial small RNA, SgrS, and their regulation of ptsG mRNA target. Mutations that disrupt binding of a chaperone protein, Hfq, and are distal to the mRNA annealing region still decrease the rate of target association, k on , and increase the dissociation rate, k off , showing that Hfq directly facilitates sRNA–mRNA annealing in vivo. Single base-pair mismatches in the annealing region reduce k on by 24–31% and increase k off by 14–25%, extending the time it takes to find and destroy the target by about a third. The effects of disrupting contiguous base-pairing are much more modest than that expected from thermodynamics, suggesting that Hfq buffers base-pair disruptions.
... Hfq-Hfq is an RNA chaperone that facilitates the interaction between sRNAs and their targets (Gottesman, 2004;Valentin-Hansen et al., 2004;Majdalani et al., 2005;Brennan and Link, 2007;Waters and Storz, 2009). The Hfq of B. burgdorferi was difficult to identify because it has limited homology with the Hfq from E. coli and other bacteria, but it is able to heterologously complement an hfq mutant of E. coli (Lybecker et al., 2010). ...
Borrelia (Borreliella) burgdorferi, along with closely related species, is the etiologic agent of Lyme disease. The spirochete subsists in an enzootic cycle that encompasses acquisition from a vertebrate host to a tick vector and transmission from a tick vector to a vertebrate host. To adapt to its environment and persist in each phase of its enzootic cycle, B. burgdorferi wields three systems to regulate the expression of genes: the RpoN-RpoS alternative sigma (σ) factor cascade, the Hk1/Rrp1 two-component system and its product c-di-GMP, and the stringent response mediated by RelBbu and DksA. These regulatory systems respond to enzootic phase-specific signals and are controlled or fine- tuned by transcription factors, including BosR and BadR, as well as small RNAs, including DsrABb and Bb6S RNA. In addition, several other DNA-binding and RNA-binding proteins have been identified, although their functions have not all been defined. Global changes in gene expression revealed by high-throughput transcriptomic studies have elucidated various regulons, albeit technical obstacles have mostly limited this experimental approach to cultivated spirochetes. Regardless, we know that the spirochete, which carries a relatively small genome, regulates the expression of a considerable number of genes required for the transitions between the tick vector and the vertebrate host as well as the adaptation to each.
... Hfq is an RNA chaperone that facilitates the interaction between sRNAs and their targets (Gottesman, 2004;Valentin-Hansen et al., 2004;Majdalani et al., 2005;Brennan and Link, 2007;Waters and Storz, 2009). The Hfq of B. burgdorferi was difficult to identify because it has limited homology with the Hfq from E. coli and other bacteria, but it is able to heterologously complement an hfq mutant of E. coli (Lybecker et al., 2010). ...
... As the simplest (+)-RNA virus, Qβ phage can play a major role in providing the catalytic enzymatic basis for RNA-dependent RNA replication in synthetic systems. Many important results related to Qβ replicase, including the kinetics [105][106][107][108], structure [109][110][111], related host proteins [112][113][114][115] and mechanism of template recognition and initiation [116][117][118][119], have established Qβ phage as the pioneering model for applications of RNA replication and laid a solid foundation for exploring and employing the RNA replication process. Compared to replicases from other viruses, Qβ replicase has advantages in terms of purification efficiency, activity preservation in cell-free extracts, RNA amplification rate and template specificity [120], which makes Qβ replicase the prime choice for RNA replication in different scenarios. ...
As the most abundant biological entities with incredible diversity, bacteriophages (also known as phages) have been recognized as an important source of molecular machines for the development of genetic-engineering tools. At the same time, phages are crucial for establishing and improving basic theories of molecular biology. Studies on phages provide rich sources of essential elements for synthetic circuit design as well as powerful support for the improvement of directed evolution platforms. Therefore, phages play a vital role in the development of new technologies and central scientific concepts. After the RNA world hypothesis was proposed and developed, novel biological functions of RNA continue to be discovered. RNA and its related elements are widely used in many fields such as metabolic engineering and medical diagnosis, and their versatility led to a major role of RNA in synthetic biology. Further development of RNA-based technologies will advance synthetic biological tools as well as provide verification of the RNA world hypothesis. Most synthetic biology efforts are based on reconstructing existing biological systems, understanding fundamental biological processes, and developing new technologies. RNA-based technologies derived from phages will offer abundant sources for synthetic biological components. Moreover, phages as well as RNA have high impact on biological evolution, which is pivotal for understanding the origin of life, building artificial life-forms, and precisely reprogramming biological systems. This review discusses phage-derived RNA-based technologies terms of phage components, the phage lifecycle, and interactions between phages and bacteria. The significance of RNA-based technology derived from phages for synthetic biology and for understanding the earliest stages of biological evolution will be highlighted.
... Trans-acting sRNAs and their target mRNAs typically exhibit short and discontinuous stretches of sequence complementarity, and thus their base-pairing interactions are inefficiently established without the assistance of proteins [7]. The bacterial Sm-like protein Hfq has been long regarded as a major node in post-transcriptional RNA networks, promoting sRNA stability and facilitating basepairing of trans-sRNAs with their targets [6,8]. Hfq substrates extend beyond sRNA transcripts to include other RNA species and even DNA [9]. ...
Function of bacterial small non-coding RNAs (sRNAs) and overall RNA metabolism is largely shaped by a vast diversity of RNA-protein interactions. However, in non-model bacteria with defined non-coding transcriptomes the sRNA interactome remains almost unexplored. We used affinity chromatography to capture proteins associated in vivo with MS2-tagged trans-sRNAs that regulate nutrient uptake (AbcR2 and NfeR1) and cell cycle (EcpR1) mRNAs by antisense-based translational inhibition in the nitrogen-fixing α-rhizobia Sinorhizobium meliloti. The three proteomes were rather distinct, with that of EcpR1 particularly enriched in cell cycle-related enzymes, whilst sharing several transcription/translation-related proteins recurrently identified associated with sRNAs. Strikingly, MetK, the synthetase of the major methyl donor S-adenosylmethionine, was reliably recovered as a binding partner of the three sRNAs, which reciprocally co-immunoprecipitated with a FLAG-tagged MetK variant. Induced (over) expression of the trans-sRNAs and MetK depletion did not influence canonical riboregulatory traits, `for example, protein titration or sRNA stability, respectively. An in vitro filter assay confirmed binding of AbcR2, NfeR1 and EcpR1 to MetK and further revealed interaction of the protein with other non-coding and coding transcripts but not with the 5S rRNA. These findings uncover a broad specificity for RNA binding as an unprecedented feature of this housekeeping prokaryotic enzyme.
... Its role in regulation usually involves inhibiting mRNA transcription and/or translation or inducing its rapid degradation in only a few cases to activate mRNA transcription [9,10]. Trans-encoded RNA, also known as small regulatory RNA (sRNA), are usually of short length, and form a circular homo-hexamer with an mRNA target with the help of a Lsm/ Sm family RNA binding protein Hfq [11,12], which may be due to the limited complementarity between sRNA and target mRNA to facilitate RNA-RNA interactions [13][14][15]. ...
Gene transcription in bacteria is mainly triggered by sigma factors (σ factors), such as rpoE. Bacterial ncRNAs are key players in reprogramming protein transcription when the environment changes. In our experiment, under the stress of ampicillin, the ncRNA transcriptomes of Salmonella enterica serovar Typhi wild-type strain (WT) and rpoE-deficient strain (ΔrpoE) were sequenced and analyzed, and four ncRNAs were selected to be verified by qRT-PCR. Of the ncRNA transcripts tested, 57 ncRNAs were found to have significantly different expressions (fold changes > 2) in ΔrpoE compared to WT, with 31 being upregulated and 26 being downregulated. The expression levels of the four ncRNAs verified preliminarily by subsequent qRT-PCR showed consistency with the sequencing data. Our study revealed the differences in ncRNA expression profiles between Salmonella enterica serovar Typhi WT and ΔrpoE under ampicillin stress. The four ncRNAs identified by qRT-PCR and their associated signaling pathways may be related to the envelope stress and antibiotic susceptibility of Salmonella enterica serovar Typhi.
... In some cases, a sRNA targeting multiple mRNAs can have both positive and negative regulation effects depending on the mRNA target [52,53]. The RNA chaperone Hfq is required for the activity of partially complementary sRNAs in proteobacterial species including Escherichia coli, Salmonella enterica, and Vibrio cholerae [54][55][56]. However, in Gram-positive bacteria such as Staphylococcus aureus ...
Many metabolic pathways in bacteria are modulated by metabolite-sensing riboswitches, which regulate gene expression at the level of transcription elongation or translation initiation. Riboswitches represent promising targets to modulate expression of genes and operons relevant for the biotechnological production of commercially relevant compounds. In Firmicutes, approximately 70% of all putative and validated riboswitches (are predicted to) act exclusively at the transcriptional level using a termination-antitermination mechanism. In a first attempt to interfere with purine-sensing riboswitches and deregulate purine metabolism in Bacillus subtilis, a set of synthetic small RNAs (sRNAs) targeting the purine-sensing aptamers were designed to impair ligand binding using rational design combined with in silico evolution. However, the designed sRNAs did not show any activity in vivo on the riboswitch controlling purine biosynthesis (pur operon riboswitch). The effect of the antisense RNA (asRNA) perfectly complementary to the aptamer of the pur operon riboswitch was also tested; The asRNA did not affect negatively expression of a riboswitch-regulated lacZ gene, yet similarly to the partially complementary sRNAs, the asRNA did not impair the downregulation exerted by the riboswitch in the presence of ligand. Finally, expression of the small RNAs in B. subtiliswas quantified, and the kinetic limitations for their hybridization with the aptamer and their competition with the ligand are discussed. A second metabolic engineering strategy based on editing the genome of B. subtilis with regard to transcriptional riboswitches was investigated. Removal of the riboswitches that control purine biosynthesis and riboflavin biosynthesis in B. subtilis led to auxotrophic strains. As an alternative, a rational approach was developed for engineering transcriptional riboswitches independently from the availability of their 3D structures. This approach consists in the identification and deletion of a key nucleotide sequence exclusively involved in transcription termination without affecting formation of other secondary and tertiary structures potentially involved in other roles. To demonstrate the efficacy of the approach, it was applied to derepress the purine and the riboflavin biosynthetic pathways in B. subtilis. Following the proof of concept using specialized reporter strains, the approach was implemented into a B. subtilis wild-type strain employing CRISPR-Cas genome editing. The CRISPRCas9 system displayed an efficiency of 61% in editing the genome, and the resulting purine and riboflavin production strains were characterized at the level of gene expression, metabolite synthesis, and growth. With a substantial enhancement observed at each level, the strategy established here represents a powerful tool for deregulating pathways modulated by transcriptional riboswitches. Finally, applying this strategy to derepress the purine pathway of an industrial riboflavin overproducing strain, with impaired growth, led to an increase in biomass by 53% and resulted in an enhanced total production of riboflavin in the culture.
... Prior to completion of the transcriptional start site map via high-throughput RNA sequencing (RNAseq) of Helicobacter pylori (16), the Epsilonproteobacteria were thought not to be capable of using small and antisense noncoding RNA as a regulatory mechanism, partly due to a lack of the RNA chaperone protein Hfq (17). Indeed, initial attempts using computational approaches to identify ncRNAs in Campylobacter failed to yield any potential candidates, with only 3 potential loci being identified in Helicobacter (18). ...
Small non-coding RNAs are involved in many important physiological functions in pathogenic microorganisms. Previous studies have identified the presence of non-coding RNAs in the major zoonotic pathogen Campylobacter jejuni , however, few have been functionally characterized to date. CjNC110 is a conserved ncRNA in C. jejuni, located downstream of the luxS gene which is responsible for the production of the quorum-sensing molecule autoinducer-2 (AI-2). In this study, we utilized strand specific high-throughput RNAseq to identify potential targets or interactive partners of CjNC110 in a sheep abortion clone of C. jejuni . This data was then utilized to focus further phenotypic evaluation of the role of CjNC110 in motility, autoagglutination, quorum sensing, hydrogen peroxide sensitivity and chicken colonization in C. jejuni . Inactivation of the CjNC110 ncRNA led to a statistically significant decrease in autoagglutination ability as well as increased motility and hydrogen peroxide sensitivity when compared to wild-type. Extracellular AI-2 detection was decreased in ΔCjNC110, however, intracellular AI-2 accumulation was significantly increased, suggesting a key role of CjNC110 in modulating the transport of AI-2. Notably, ΔCjNC110 also showed a decreased ability to colonize chickens. Complementation of CjNC110 restored all phenotypic changes back to wild-type levels. The collective results of the phenotypic and transcriptomic changes observed in our data provide valuable insights into the pathobiology of C. jejuni sheep abortion clone and strongly suggest that CjNC110 plays an important role in regulation of energy taxis, flagellar glycosylation, cellular communication via quorum sensing, oxidative stress tolerance and chicken colonization in this important zoonotic pathogen.
... Hfq is a pleiotropic post-transcriptional regulator found in approximately 50% of all sequenced bacteria (1)(2)(3). Hfq acts as an RNA chaperone and regulates gene expression by binding U-tracts and A-rich regions of small noncoding RNAs (sRNAs) and target mRNAs, respectively, to effect their annealing (4)(5)(6)(7)(8)(9). The resulting sRNA-mRNA complex typically inhibits translation of the target mRNA and ultimately leads to its degradation as well as that of the sRNA, although some mRNAs, including rpoS, which encodes the stress response sigma factor S , require Hfq for efficient translation (5,(10)(11). ...
Hfq regulates bacterial gene expression post-transcriptionally by binding small RNAs and their target mRNAs, facilitating sRNA-mRNA annealing, typically resulting in translation inhibition and RNA turnover. Hfq is also found in the nucleoid and binds double-stranded (ds) DNA with a slight preference for A-tracts. Here, we present the crystal structure of the Escherichia coli Hfq Core bound to a 30 bp DNA, containing three 6 bp A-tracts. Although previously postulated to bind to the 'distal' face, three statistically disordered double stranded DNA molecules bind across the proximal face of the Hfq hexamer as parallel, straight rods with B-DNA like conformational properties. One DNA duplex spans the diameter of the hexamer and passes over the uridine-binding proximal-face pore, whereas the remaining DNA duplexes interact with the rims and serve as bridges between adjacent hexamers. Binding is sequence-independent with residues N13, R16, R17 and Q41 interacting exclusively with the DNA backbone. Atomic force microscopy data support the sequence-independent nature of the Hfq-DNA interaction and a role for Hfq in DNA compaction and nucleoid architecture. Our structure and nucleic acid-binding studies also provide insight into the mechanism of sequence-independent binding of Hfq to dsRNA stems, a function that is critical for proper riboregulation.
... One of the other classic techniques used is copurification with proteins that are limited to a subclass of sRNAs and requiring highly specific antibodies. The Hfq is commonly used because it binds sRNAs [3,51,52] to ensure stability and enhanced interaction with the mRNA target. Therefore, antibodies directed against Hfq are beneficial for such experiments. ...
Proteins have long been considered to be the most prominent factors regulating so-called invasive genes involved in host-pathogen interactions. The possible role of small non-coding RNAs (sRNAs), either intracellular, secreted or packaged in outer membrane vesicles (OMVs), remained unclear until recently. The advent of high-throughput RNA-sequencing (RNA-seq) techniques has accelerated sRNA discovery. RNA-seq radically changed the paradigm on bacterial virulence and pathogenicity to the point that sRNAs are emerging as an important, distinct class of virulence factors in both gram-positive and gram-negative bacteria. The potential of OMVs, as protectors and carriers of these functional, gene regulatory sRNAs between cells, has also provided an additional layer of complexity to the dynamic host-pathogen relationship. Using a non-exhaustive approach and through examples, this review aims to discuss the involvement of sRNAs, either free or loaded in OMVs, in the mechanisms of virulence and pathogenicity during bacterial infection. We provide a brief overview of sRNA origin and importance, and describe the classical and more recent methods of identification that have enabled their discovery, with an emphasis on the theoretical lower limit of RNA sizes considered for RNA sequencing and bioinformatics analyses.
... Białko to jest plejotropowym, potranskrypcyjnym regulatorem, który działa jak białko opiekuńcze RNA, kontrolując stabilność mRNA, wpływając na różnorodne funkcje komórki, m.in. szybkość wzrostu, czas tworzenia biofilmu, wiązanie azotu czy przetrwanie w warunkach stresowych [91]. Do rozprzestrzenienia się S. flexnerii wymaga aktywności DksA, które bezpośrednio aktywuje transkrypcję Hfq. ...
The aim of the existence of every organism is to survive and replicate its genetic material. The pathogen, after infection of the host, has to overcome the host’s defensive barrier. For this, bacterial pathogens use virulence-related factors, such as cell and tissue invasion, adhesion to the surface and toxin production. Numerous pathogenic microorganisms combine their virulence pathways with general mechanisms that allow their adaptation to changing environmental conditions. For this purpose, many bacteria use the global mechanisms of reaction to a stress condition, the stringent response. Here we discuss how the components of stringent response influence the virulence of pathogenic bacteria.
1. Introduction. 2. Metabolism of (p)ppGpp. 2.1. Regulatory targets of (p)ppGpp. 3. Virulence and adaptation to adverse environmental conditions. 4. The role of stringent response in the virulence of Gram-negative bacteria 4.1. Escherichia coli EHEC. 4.2. Escherichia coli UPEC. 4.3. Shigella flexneri. 4.4. Vibrio cholerae. 4.5. Salmonella enterica. 4.6. Pseudomonas aeruginosa. 4.7. Francisella tularensis. 4.8. Bordetella pertussis. 5. The role of stringent response in the virulence of Gram-positive bacteria. 5.1. Enterococcus faecalis. 5.2. Bacillus anthracis. 5.3. Staphylococcus aureus. 5.4. Streptococcus pyogenes. 5.5. Listeria monocytogenes. 6. The effect of the stringent response on the virulence of Mycobacterium tuberculosis. 7. Summary
... In E. coli, the Hfq ring contains sRNA-binding sites on the so-called proximal (side of the ring and inner rim of the central cavity containing α-helixes) and lateral (outer rim of the ring) faces, and an mRNA-binding region on the distal (surface opposite to the proximal side containing β-sheets) face of the ring (95-99). Hfq was shown to preferentially recognize a common sRNA structure: an A/U rich sequence followed by a Rho-independent terminator hairpin and a 3′ poly-U tail (100)(101)(102). Similarly, an Hfq-binding element called the (ARN) x motif (where A is adenine, R is a purine, and N is any nucleotide) is found in the leader sequences of many sRNA-regulated mRNAs. ...
Small non-coding RNAs (sRNAs) are key regulators of post-transcriptional gene expression in bacteria. Hundreds of sRNAs have been found using in silico genome analysis and experimentally based approaches in bacteria of the Burkholderia cepacia complex (Bcc). However, and despite the hundreds of sRNAs identified so far, the number of functionally characterized sRNAs from these bacteria remains very limited. In this mini-review, we describe the general characteristics of sRNAs and the main mechanisms involved in their action as regulators of post-transcriptional gene expression, as well as the work done so far in the identification and characterization of sRNAs from Bcc. The number of functionally characterized sRNAs from Bcc is expected to increase and to add new knowledge on the biology of these bacteria, leading to novel therapeutic approaches to tackle the infections caused by these opportunistic pathogens, particularly severe among cystic fibrosis patients.
Key points
•Hundreds of sRNAs have been identified in Burkholderia cepacia complex bacteria (Bcc).
•A few sRNAs have been functionally characterized in Bcc.
•Functionally characterized Bcc sRNAs play major roles in metabolism, biofilm formation, and virulence.
Hfq is a pleitropic actor, serving as stress response and virulence factor in the bacterial cell. It achieves this function mostly through its binding to small noncoding RNAs, conferring annealing with mRNAs. To execute these functions, Hfq assembles into a symmetric torus-shaped hexamer, called the Sm-core, with two concave structurally distinct surfaces and a convex rim. Extending outward from this core, Hfq presents a C-terminal region, described as intrinsically disordered in solution. Many as-pects of the role and the structure of this elongated C-terminal remain unclear. For instance, this region in its truncated form can promote amyloid-like filament assembly. Here, we show that a minimal 11-residue motif found at the end of the Hfq sequence assembles into filaments with amyloid characteristics, based on x-ray diffraction, infrared spectroscopy, circular dichroism and solid-state Nuclear Magnetic Resonance. Furthermore, our data suggest that the full-length Hfq in its filamentous state contains a similar molecular fingerprint than that of the short β-strand peptide, and that the Sm-core structure is not affected by filament formation. Hfq proteins might thus co-exist in two forms in vivo, either as isolated, soluble hexamers or as self-assembled hex-amers through amyloid-reminiscent interactions. This property may help modulating Hfq cellular functions.
Posttranscriptional processes in Bacteria include the association of small regulatory RNAs (sRNA) with a target mRNA. The sRNA/mRNA annealing process is often mediated by an RNA chaperone called Hfq. The functional role of bacterial and eukaryotic Lsm proteins is partially understood, whereas knowledge about archaeal Lsm proteins is scarce. Here, we used the genetically tractable archaeal hyperthermophile Pyrococcus furiosus to identify the protein interaction partners of the archaeal Sm-like proteins (PfuSmAP1) using mass spectrometry and performed a transcriptome-wide binding site analysis of PfuSmAP1. Most of the protein interaction partners we found are part of the RNA homoeostasis network in Archaea including ribosomal proteins, the exosome, RNA-modifying enzymes, but also RNA polymerase subunits, and transcription factors. We show that PfuSmAP1 preferentially binds messenger RNAs and antisense RNAs recognizing a gapped poly(U) sequence with high affinity. Furthermore, we found that SmAP1 co-transcriptionally associates with target RNAs. Our study reveals that in contrast to bacterial Hfq, PfuSmAP1 does not affect the transcriptional activity or the pausing behaviour of archaeal RNA polymerases. We propose that PfuSmAP1 recruits antisense RNAs to target mRNAs and thereby executes its putative regulatory function on the posttranscriptional level.
Small RNAs (sRNAs), a subset of non-coding RNAs, act posttranscriptionally to salvage bacteria from stress, thereby modulating multiple aspects of bacterial growth, physiology, and virulence. Conventional genetic screens do not efficiently detect sRNAs, rendering most sRNAs in E. coli uncharacterized. Characterizing sRNA regulons and their mechanism(s) of action is necessary for understanding the regulatory networks controlling growth, physiology, and virulence. Utilizing the sRNAMap database and the deposited expression datasets on the NCBI Gene Expression Omnibus (GEO), we chose a pool of uncharacterized E. coli sRNAs that are differentially expressed under distinct stress conditions. These sRNAs were then cloned into medium copy-number plasmids. Simultaneously, IntaRNA was used to computationally predict potential targets for these sRNAs. To validate posttranscriptional regulation of these sRNA targets, we constructed target lacZ translational fusions using lambda-Red recombineering. We confirmed posttranscriptional regulation by measuring changes in the β-galactosidase activity of these fusions upon ectopic expression of the sRNAs. Successful completion of this project will help elucidate the individual targetomes of these novel sRNAs. Ultimately, this will aid our understanding of the physiological condition(s) that trigger the expression of these sRNAs.
The principal transcriptome analysis is the determination of differentially expressed genes across experimental conditions. For this, the next-generation sequencing of RNA (RNA-seq) has several advantages over other techniques, such as the capability of detecting all the transcripts in one assay over RT-qPCR, such as its higher accuracy and broader dynamic range over microarrays or the ability to detect novel transcripts, including non-coding RNA molecules, at nucleotide-level resolution over both techniques. Despite these advantages, many microbiology laboratories have not yet applied RNA-seq analyses to their investigations. The high cost of the equipment for next-generation sequencing is no longer an issue since this intermediate part of the analysis can be provided by commercial or central services. Here, we detail a protocol for the first part of the analysis, the RNA extraction and an introductory protocol to the bioinformatics analysis of the sequencing data to generate the differential expression results.
The necrotrophic plant pathogenic bacterium Dickeya solani emerged in the potato agrosystem in Europe. All isolated strains of D. solani contain several large polyketide synthase/non-ribosomal peptide synthetase (PKS/NRPS) gene clusters. Analogy with genes described in other bacteria suggests that the clusters ooc and zms are involved in the production of secondary metabolites of the oocydin and zeamine families, respectively. A third cluster named sol was recently shown to produce an antifungal molecule. In this study, we constructed mutants impaired in each of the three secondary metabolite clusters sol, ooc, and zms to compare first the phenotype of the D. solani wild-type strain D s0432-1 with its associated mutants. We demonstrated the antimicrobial functions of these three PKS/NRPS clusters against bacteria, yeasts or fungi. The cluster sol, conserved in several other Dickeya species, produces a secondary metabolite inhibiting yeasts. Phenotyping and comparative genomics of different D. solani wild-type isolates revealed that the small regulatory RNA ArcZ plays a major role in the control of the clusters sol and zms. A single-point mutation, conserved in some Dickeya wild-type strains, including the D. solani type strain IPO 2222, impairs the ArcZ function by affecting its processing into an active form.
Enteropathogenic Escherichia coli (EPEC) is a diarrheagenic bacterium that predominantly infects infants in developing countries. EPEC forms attaching and effacing (A/E) lesions on the apical surface of the small intestine, leading to diarrhea. The locus of enterocyte effacement (LEE) is both necessary and sufficient for A/E lesion morphogenesis by EPEC. Gene expression from this virulence determinant is controlled by an elaborate regulatory web that extends beyond protein-based transcriptional regulators and includes small regulatory RNA (sRNA) that exert their effects posttranscriptionally. To date, only 4 Hfq-dependent sRNAs—MgrR, RyhB, McaS, and Spot42—have been identified that affect the LEE of EPEC by diverse mechanisms and elicit varying regulatory outcomes. In this study, we demonstrate that the paralogous Hfq-dependent sRNAs OmrA and OmrB globally silence the LEE to diminish the ability of EPEC to form A/E lesions. Interestingly, OmrA and OmrB do not appear to directly target a LEE-encoded gene; rather, they repress transcription from the LEE1 promoter indirectly, by means of an as-yet-unidentified transcriptional factor that binds within 200 base pairs upstream of the transcription start site to reduce the expression of the LEE master regulator Ler, which, in turn, leads to reduced morphogenesis of A/E lesions. Additionally, OmrA and OmrB also repress motility in EPEC by targeting the 5′ UTR of the flagellar master regulator, flhD.
There is increasing evidence that prokaryotes maintain chromosome structure, which in turn impacts gene expression. We recently characterized densely occupied, multi-kilobase regions in the E. coli genome that are transcriptionally silent, similar to eukaryotic heterochromatin. These extended protein occupancy domains (EPODs) span genomic regions containing genes encoding metabolic pathways as well as parasitic elements such as prophages. Here, we investigate the contributions of nucleoid-associated proteins (NAPs) to the structuring of these domains, by examining the impacts of deleting NAPs on EPODs genome-wide in E. coli and B. subtilis. We identify key NAPs contributing to the silencing of specific EPODs, whose deletion opens a chromosomal region for RNA polymerase binding at genes contained within that region. We show that changes in E. coli EPODs facilitate an extra layer of transcriptional regulation, which prepares cells for exposure to exotic carbon sources. Furthermore, we distinguish novel xenogeneic silencing roles for the NAPs Fis and Hfq, with the presence of at least one being essential for cell viability in the presence of domesticated prophages. Our findings reveal previously unrecognized mechanisms through which genomic architecture primes bacteria for changing metabolic environments and silences harmful genomic elements.
While most bacterial species taken up by macrophages are degraded through processing of the bacteria-containing vacuole through the endosomal-lysosomal degradation pathway, intravacuolar pathogens have evolved to evade degradation through the endosomal-lysosomal pathway. All intra-vacuolar pathogens possess specialized secretion systems (T3SS-T7SS) that inject effector proteins into the host cell cytosol to modulate myriad of host cell processes and remodel their vacuoles into proliferative niches. Although intravacuolar pathogens utilize similar secretion systems to interfere with their vacuole biogenesis, each pathogen has evolved a unique toolbox of protein effectors injected into the host cell to interact with, and modulate, distinct host cell targets. Thus, intravacuolar pathogens have evolved clear idiosyncrasies in their interference with their vacuole biogenesis to generate a unique intravacuolar niche suitable for their own proliferation. While there has been a quantum leap in our knowledge of modulation of phagosome biogenesis by intravacuolar pathogens, the detailed biochemical and cellular processes affected remain to be deciphered. Here we discuss how the intravacuolar bacterial pathogens Salmonella, Chlamydia, Mycobacteria, Legionella, Brucella, Coxiella , and Anaplasma utilize their unique set of effectors injected into the host cell to interfere with endocytic, exocytic, and ER-to-Golgi vesicle traffic. However, Coxiella is the main exception for a bacterial pathogen that proliferates within the hydrolytic lysosomal compartment, but its T4SS is essential for adaptation and proliferation within the lysosomal-like vacuole.
In bacteria transcription is coupled to translation, and while it is broadly accepted that transcription–translation complexes (TTCs) are formed in growing bacterial cells, the exact spatial organization of these macromolecular assemblies is not known with certainty. Recent studies indicated the formation of orderly cytosolic superstructures in growing E. coli cells. The bacterial nucleic acid (NA)-binding protein Hfq has been shown to function at the interface of RNA synthesis–degradation machinery; multiple, independent studies link Hfq to orderly cytosolic assemblies. In this work, using fast cell lysis/2D-PAGE and in vitro reconstitution analyses we studied the Hfq modifications and small protein-associated molecules (SPAM). We demonstrate that native Hfq carries stable modifications and simulate 2D patterns of native Hfq–SPAM complexes in reconstitution experiments with purified Hfq and synthetic NA probes. We also demonstrate that genetically engineered Hfq lacking the conserved arginine residues positioned near the rim of the disc formed by the subunits’ N-terminal domains binds DNA with a reduced affinity in comparison with wild-type Hfq. These results are consistent with the proposed Hfq-mediated DNA remodeling and point to the involvement of this patch of conserved arginines in interactions with DNA.
Every organism faces the challenge of organizing immense amounts of genetic information into a small physical space that is the cell. In eukaryotes, this process is facilitated by histones that wrap DNA into small units. While it has been historically assumed that bacteria do not have an organized genome, increasing evidence implicates a robust structure that enables bacteria to quickly cope with a variety of environmental pressures. The organization and regulation of DNA is incredibly important to engineer bacteria for biotechnological purposes and to understand bacteria that cause disease. However, while bacteria impact almost every aspect of human life, we do not fully understand their genomes. In this thesis I investigated genome organization with a specific focus in bacteria. To improve our understanding of bacterial genomes, I helped design a high-throughput tool, in-vivo protein occupancy display at high-resolution (IPOD-HR), that allows resolution of how proteins bind across the whole length of a bacterial chromosome. By applying this tool to a number of different bacteria, we discovered conserved areas of the genome that are densely bound by proteins but are transcriptionally silent – similarly to heterochromatin in eukaryotes. I show that these regions, termed extended protein occupancy domains (EPODs), have functional roles in bacteria that enable them to use new carbon sources for energy and provide an immune defense against viruses in Escherichia coli (E. coli). I show that EPODs are occupied by nucleoid associated proteins (NAPs). By performing deletions of single NAPs, I identified the key NAPs that bind to specific regulons. In E. coli, I find that EPODs silence a number of metabolic pathways and toxic prophages. I induced changes of particular EPODs by exposing cells to exotic carbon sources and find that EPODs mediate a transcriptional memory affect, where upon a second exposure to an exotic carbon source mounts a faster growth rate and de-repression of genes required for metabolism. In addition, I show one essential role of the formation of EPODs by NAPs in E. coli is to silence harmful genetic elements that have integrated into the genome, such as mobile elements and prophages, that can be potentially toxic to the cell. I define novel prophage silencers, Hfq and Fis that are required for silencing specific prophages. In collaboration with the Jakob Lab, I employed biochemistry, genetics, and bioinformatics and discovered that Hfq binds with a poly-anion, polyphosphate (polyP), to DNA to silence prophages. Biochemical results suggest a model in which polyphosphate acts as an Hfq chaperone in order to permit appropriate silencing at EPODs. These results provided the first evidence that polyP might act in DNA damage control by either directly or indirectly suppressing the expression of genetic mobile elements and prophages, and a mechanism by which bacterial heterochromatin enables regulation during times of stress. Ultimately, my work defines the importance of genome organization in bacteria and provides a scaffold for further investigation into mechanisms underlying the establishment heterochromatin-like domains in bacteria.
The Sm, like-Sm, and Hfq proteins belonging to the Sm superfamily of proteins are represented in all domains of life. These proteins are involved in several RNA metabolism pathways. The functions of bacterial Hfq and eukaryotic Sm proteins have been described, but knowledge about the in vivo functions of archaeal Sm proteins remains limited. This study aims to improve the understanding of Lsm proteins and their role using the haloarchaeon Haloferax mediterranei as a model microorganism. The Haloferax mediterranei genome contains one lsm gene that overlaps with the rpl37e gene. To determine the expression of lsm and rpl37e genes and the co-transcription of both, reverse transcription-polymerase chain reaction (RT-PCR) analyses were performed under different standard and stress conditions. The results suggest that the expression of lsm and rpl37e is constitutive. Co-transcription occurs at sub-optimal salt concentrations and temperatures, depending on the growth phase. The halophilic Lsm protein contains two Sm motifs, Sm1 and Sm2, and the sequence encoding the Sm2 motif also constitutes the promoter of the rpl37e gene. To investigate their biological functions, the lsm deletion mutant and the Sm1 motif deletion mutant, where the Sm2 motif remained intact, were generated and characterised. Comparison of the lsm deletion mutant, Sm1 deletion mutant, and the parental strain HM26 under standard and stress growth conditions revealed growth differences. Finally, swarming assays in complex and defined media showed greater swarming capacity in the deletion mutants.
Intrinsic and acquired defenses against bacteriophages, including Restriction/Modification, CRISPR/Cas, and Toxin/Anti-toxin systems have been intensely studied, with profound scientific impacts. However, adaptive defenses against phage infection analogous to adaptive resistance to antimicrobials have yet to be described. To identify such mechanisms, we applied an RNAseq-based, comparative transcriptomics approach in different Pseudomonas aeruginosa strains after independent infection by a set of divergent virulent bacteriophages. A common host-mediated adaptive stress response to phages was identified that includes the Pseudomonas Quinolone Signal, through which infected cells inform their neighbors of infection, and what may be a resistance mechanism that functions by reducing infection vigor. With host transcriptional machinery left intact, we also observe phage-mediated differential expression caused by phage-specific stresses and molecular mechanisms. These responses suggest the presence of a conserved Bacterial Adaptive Phage Response mechanism as a novel type of host defense mechanism, and which may explain transient forms of phage persistence.
Ro60 ribonucleoproteins (RNPs), composed of the ring-shaped Ro 60-kDa (Ro60) protein and noncoding RNAs called Y RNAs, are present in all three domains of life. Ro60 was first described as an autoantigen in patients with rheumatic disease, and Ro60 orthologs have been identified in 3% to 5% of bacterial genomes, spanning the majority of phyla. Their functions have been characterized primarily in Deinococcus radiodurans, the first sequenced bacterium with a recognizable ortholog. In D. radiodurans, the Ro60 ortholog enhances the ability of 3′-to-5′ exoribonucleases to degrade structured RNA during several forms of environmental stress. Y RNAs are regulators that inhibit or allow the interactions of Ro60 with other proteins and RNAs. Studies of Ro60 RNPs in other bacteria hint at additional functions, since the most conserved Y RNA contains a domain that is a close tRNA mimic and Ro60 RNPs are often encoded adjacent to components of RNA repair systems.
Expected final online publication date for the Annual Review of Microbiology, Volume 74 is September 8, 2020. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.
Francisella tularensis est l'agent étiologique responsable de la tularémie, une zoonose endémo-épidémique dans l'hémisphère Nord, capable d'infecter un grand nombre d'espèces animales (mammifères, oiseaux, insectes,...) et potentiellement hautement pathogène pour l'homme. Cette pathologie encore mal connue a des manifestations très polymorphes, pouvant aller de formes bénignes jusqu'à des formes pulmonaires mortelles. Lors de l'infection de mammifères, Francisella se multiplie principalement à l'intérieur des cellules macrophagiques. Cependant, au cours de sa dissémination systémique, elle est capable d'infecter de nombreux autres types cellulaires, y compris non phagocytaires (épithéliales, hépatocytes,...). Pour cela, Francisella a développé des mécanismes lui permettant d'échapper à la lyse dans le phagosome et de se multiplier dans le cytoplasme des cellules infectées où elle obtient certains éléments essentiels à sa croissance. Dans une première partie, nous nous sommes intéressés à l'adaptation métabolique de Francisella au cours de son cycle intracellulaire et notamment au rôle d'une enzyme clé de la Glycolyse/Gluconéogenèse, la fructose-1,6-biphosphate aldolase (FBA). Au-delà de son rôle ménager dans le métabolisme, nous démontrons que FBA est importante pour la multiplication bactérienne dans les macrophages en présence de substrats gluconéogèniques. De plus, nous mettons en évidence un rôle direct de cette enzyme métabolique dans la régulation de la transcription des gènes katG et rpoA, codant respectivement pour la catalase et une sous-unité de l'ARN polymérase. Nous proposons un modèle dans lequel FBA participe au contrôle de l'homéostasie redox de l'hôte et à la réponse immunitaire inflammatoire. Dans une seconde partie, nous nous sommes intéressés au système de sécrétion de type VI (SST6) de Francisella. De nombreuses bactéries à Gram négatif utilisent le SST6 pour transloquer des protéines effectrices dans des cellules eucaryotes ou procaryotes. Francisella possède un SST6 non-canonique codé sur l'îlot de pathogénicité FPI qui est essentiel pour la sortie du phagosome et permet à la bactérie de se multiplier dans le cytosol de la cellule hôte. En utilisant une approche phosphoprotéomique globale chez la sous-espèce novicida, nous avons identifié un site de phosphorylation unique sur la tyrosine 139 de IglB, un composant clé de la gaine contractile du SST6. Nous démontrons ici que le statut de phosphorylation de IglB joue un rôle important dans l'assemblage d'un SST6 fonctionnel. Nous proposons que cette modification post-traductionnelle du composant majeur de la gaine puisse constituer un mécanisme de régulation permettant de moduler la dynamique d'assemblage/désassemblage du T6SS.
Several authentic or potential global regulators have recently been shown to act at the post-trancriptional level. This is the case for Hfq (HF-1), which is involved in the regulation of an increasing number of genes in Escherichia coli, and CsrA (RsmA) responsible for controlling the expression of genes for extracellular enzymes and secondary metabolism in Gram-negative bacteria. The cold-shock proteins of the CspA family are able to destabilise mRNA secondary structures at low temperature and, therefore, also seem to act post-transcriptionally. These findings illustrate a more general aspect of post-transcriptional control which, in the past, was generally restricted to regulators acting at a single target. The expression of several global transcriptional regulators, such as the stationary phase and heat-shock sigma factors and H-NS, have also recently been shown to be themselves under post-transcriptional control. These examples underline the importance of this type of control in bacterial gene regulation.
Eukaryotic Sm and Sm-like proteins associate with RNA to form the core domain of ribonucleoprotein particles involved in pre-mRNA splicing and other processes. Recently, putative Sm proteins of unknown function have been identified in Archaea. We show by immunoprecipitation experiments that the two Sm proteins present in Archaeoglobus fulgidus (AF-Sm1 and AF-Sm2) associate with RNase P RNA in vivo, suggesting a role in tRNA processing. The AF-Sm1 protein also interacts specifically with oligouridylate in vitro. We have solved the crystal structures of this protein and a complex with RNA. AF-Sm1 forms a seven-membered ring, with the RNA interacting inside the central cavity on one face of the doughnut-shaped complex. The bases are bound via stacking and specific hydrogen bonding contacts in pockets lined by residues highly conserved in archaeal and eukaryotic Sm proteins, while the phosphates remain solvent accessible. A comparison with the structures of human Sm protein dimers reveals closely related monomer folds and intersubunit contacts, indicating that the architecture of the Sm core domain and RNA binding have been conserved during evolution.
DsrA is an 85-nucleotide, untranslated RNA that has multiple regulatory activities at 30°C. These activities include the translational
regulation of RpoS and H-NS, global transcriptional regulators in Escherichia coli. Hfq is an E. coli protein necessary for the in vitro and in vivo replication of the RNA phage Qβ. Hfq also plays a role in the degradation
of numerous RNA transcripts. Here we show that an hfq mutant strain is defective for DsrA-mediated regulation of bothrpoS and hns. The defect in rpoSexpression can be partially overcome by overexpression of DsrA. Hfq does not regulate the transcription of DsrA, and DsrA
does not alter the accumulation of Hfq. However, in an hfq mutant, chromosome-expressed DsrA was unstable (half-life of 1 min) and truncated at the 3′ end. When expressed from a multicopy
plasmid, DsrA was stable in both wild-type and hfq mutant strains, but it had only partial activity in the hfq mutant strain. Purified Hfq binds DsrA in vitro. These results suggest that Hfq acts as a protein cofactor for the regulatory
activities of DsrA by either altering the structure of DsrA or forming an active RNA-protein complex.
We have studied the interaction of the host factor (HF) required for bacteriophage Qbeta RNA replication and of ribosomal protein S1, a subunit of Qbeta replicase, with Qbeta and R17 RNA. Both proteins bind to both Qbeta and R17 RNA; HF has a higher affinity than S1 for these phages RNAs. HF binds to a single site in R17 RNA located in the replicase cistron, and to two sites of Qbeta RNA, one of which is located approximately 60 nucleotides from the 6' end of Qbeta RNA. The three HF binding sites all have portions rich in adenylate residues; all are bound by HF when contained in oligonucleotides which are predicted to exist only in single-stranded form. S1 selects a single site in Qbeta RNA, also near the 6' end, but binds to a large number of sites in R17 RNA. These results suggest that HF and possibly S1, through their interaction with the 3'-terminal region of Qbeta RNA, are directly involved in the recognition of the 6' end of Qbeta RNA by Qbeta replicase. Under conditions where specific protein-R1M RNA complexes are formed, we have also tested host factor and S1 for cistron-specific interference with ribosome binding to R17 RNA. Although S1 and HF lower the efficiency of initiation complex formation as described previously, we detect no discrimination against any particular cistron. We therefore conclude that translational interference exhibited by the two proteins probably reflects simply their high affinity for RNA and certain defined polynucleotides.
The amiB-mutL-miaA-hfq-hflX-hflK-hflC superoperon of Escherichia coli contains genes that are important for diverse cellular functions, including DNA mismatch repair (mutL), tRNA modification (miaA), pleiotropic regulation (hfq), and proteolysis (hflX-hflK-hflC). We show that this superoperon contains three E simga(32)-dependent heat shock promoters, P(mutL)HS,P(miaA)HS, and P1(hfq)HS, in addition to four E sigma(70)-dependent promoters, P(mutL), P(miaA), P2(hfq), and P3(hfq). Transcripts from P(mutL)HS and P(miaA)HS were most prominent in vivo during extreme heat shock (50 degrees C), whereas P1(hfq)HS transcripts were detectable under nonshock conditions and increased significantly after heat shock at 50 degrees C. The P(mutL)HS, P(miaA)HS, and P1(hfq)HS transcripts were not detected in an rpoH null mutant. All three promoters were transcribed by E sigma (32) in vitro at 37 degrees C and contain -35 and -10 regions that resemble the E sigma(32) consensus. In experiments to assess the possible physiological relevance of the P(mutL)HS and P(miaA)HS promoters, we found that E. coli prototrophic strain MG 1655 increased in cell mass and remained nearly 100% viable for several hours at 50 degrees C in enriched media. In these cells, a significant fraction of mutL and hfq-hflA region transcripts were from P(mutL)HS and P1(hfq)HS, respectively, and the amounts of the miaA, hfq, hflX, hflK, and hflC transcripts increased in comparison with those in nonstressed cells. The cellular amounts of MutL and the hfq gene product (HF-I protein) were maintained during heat shock at 44 or 50 degrees C. Consistent with their expression patterns, miaA and hfq were essential for growth and viability, respectively, at temperatures of 45 degrees C and above. Together, these results suggest that there is a class of E sigma(32) promoters that functions mainly at high temperatures to ensure E. coli function and survival.
The hfq-encoded RNA-binding protein HF-I has long been known as a host factor for phage Qbeta RNA replication and has recently been shown to be essential for translation of rpoS, which encodes the sigmaS subunit of RNA polymerase. Here we demonstrate that an hfq null mutant does not synthesize glycogen, is starvation and multiple stress sensitive, and exhibits strongly reduced expression of representative sigmaS-regulated genes. These phenotypes are consistent with strongly reduced sigmaS levels in the hfq mutant. However, the analysis of global protein synthesis patterns on two-dimensional O'Farrell gels indicates that approximately 40% of the more than 30 proteins whose syntheses are altered in the hfq null mutant are not affected by an rpoS mutation. We conclude that HF-I is a global regulator involved in the regulation of expression of sigmaS and sigmaS-independent genes.
The MutS, MutL, and MutH proteins play major roles in several DNA repair pathways. We previously reported that the cellular amounts of MutS and MutH decreased by as much as 10-fold in stationary-phase cultures. Consequently, we tested whether the amounts of MutS, MutL, and MutH were regulated by two global regulators, RpoS (sigma38) and Hfq (HF-I [putative RNA chaperone]), which are involved in stationary-phase transition. We report here that mutations in hfq and rpoS reversed the stationary-phase down-regulation of the amounts of MutS and MutH. hfq regulation of the amount of MutS in stationary-phase cultures was mediated by RpoS-dependent and -independent mechanisms, whereas hfq regulation of the amount of MutH was mediated only through RpoS. Consistent with this interpretation, the amount of MutS but not MutH was regulated by Hfq, but not RpoS, in exponentially growing cells. The amount of MutL remained unchanged in rpoS, hfq-1, and rpoS+, hfq+ strains in exponentially growing and stationary-phase cultures and served as a control. The beta-galactosidase activities of single-copy mutS-lacZ operon and gene fusions suggested that hfq regulates mutS posttranscriptionally in exponentially growing cultures. RNase T2 protection assays revealed increased amounts of mutS transcript that are attributed to increased mutS transcript stability in hfq-1 mutants. Lack of Hfq also increased the amounts and stabilities of transcripts initiated from P(miaA) and P1hfqHS, two of the promoters for hfq, suggesting autoregulation, but did not change the half-life of bulk mRNA. These results suggest that the amounts of MutS and MutH may be adjusted in cells subjected to different stress conditions by an RpoS-dependent mechanism. In addition, Hfq directly or indirectly regulates several genes, including mutS, hfq, and miaA, by an RpoS-independent mechanism that destabilizes transcripts.
The OxyS regulatory RNA integrates the adaptive response to hydrogen peroxide with other cellular stress responses and protects against DNA damage. Among the OxyS targets is the rpoS-encoded sigma(s) subunit of RNA polymerase. Sigma(s) is a central regulator of genes induced by osmotic stress, starvation and entry into stationary phase. We examined the mechanism whereby OxyS represses rpoS expression and found that the OxyS RNA inhibits translation of the rpoS message. This repression is dependent on the hfq-encoded RNA-binding protein (also denoted host factor I, HF-I). Co-immunoprecipitation and gel mobility shift experiments revealed that the OxyS RNA binds Hfq, suggesting that OxyS represses rpoS translation by altering Hfq activity.
The genome DNA of Escherichia coli is associated with about 10 DNA-binding structural proteins, altogether forming the nucleoid. The nucleoid proteins play some functional roles, besides their structural roles, in the global regulation of such essential DNA functions as replication, recombination, and transcription. Using a quantitative Western blot method, we have performed for the first time a systematic determination of the intracellular concentrations of 12 species of the nucleoid protein in E. coli W3110, including CbpA (curved DNA-binding protein A), CbpB (curved DNA-binding protein B, also known as Rob [right origin binding protein]), DnaA (DNA-binding protein A), Dps (DNA-binding protein from starved cells), Fis (factor for inversion stimulation), Hfq (host factor for phage Q(beta)), H-NS (histone-like nucleoid structuring protein), HU (heat-unstable nucleoid protein), IciA (inhibitor of chromosome initiation A), IHF (integration host factor), Lrp (leucine-responsive regulatory protein), and StpA (suppressor of td mutant phenotype A). Intracellular protein levels reach a maximum at the growing phase for nine proteins, CbpB (Rob), DnaA, Fis, Hfq, H-NS, HU, IciA, Lrp, and StpA, which may play regulatory roles in DNA replication and/or transcription of the growth-related genes. In descending order, the level of accumulation, calculated in monomers, in growing E. coli cells is Fis, Hfq, HU, StpA, H-NS, IHF*, CbpB (Rob), Dps*, Lrp, DnaA, IciA, and CbpA* (stars represent the stationary-phase proteins). The order of abundance, in descending order, in the early stationary phase is Dps*, IHF*, HU, Hfq, H-NS, StpA, CbpB (Rob), DnaA, Lrp, IciA, CbpA, and Fis, while that in the late stationary phase is Dps*, IHF*, Hfq, HU, CbpA*, StpA, H-NS, CbpB (Rob), DnaA, Lrp, IciA, and Fis. Thus, the major protein components of the nucleoid change from Fis and HU in the growing phase to Dps in the stationary phase. The curved DNA-binding protein, CbpA, appears only in the late stationary phase. These changes in the composition of nucleoid-associated proteins in the stationary phase are accompanied by compaction of the genome DNA and silencing of the genome functions.
The genome of Escherichia coli is composed of a single molecule of circular DNA with the length of about 47,000 kilobase pairs, which is associated with about 10 major DNA-binding proteins, altogether forming the nucleoid. We expressed and purified 12 species of the DNA-binding protein, i.e. CbpA (curved DNA-binding protein A), CbpB or Rob (curved DNA-binding protein B or right arm of the replication origin binding protein), DnaA (DNA-binding protein A), Dps (DNA-binding protein from starved cells), Fis (factor for inversion stimulation), Hfq (host factor for phage Q(beta)), H-NS (histone-like nucleoid structuring protein), HU (heat-unstable nucleoid protein), IciA (inhibitor of chromosome initiation A), IHF (integration host factor), Lrp (leucine-responsive regulatory protein), and StpA (suppressor of td(-) phenotype A). The sequence specificity of DNA binding was determined for all the purified nucleoid proteins using gel-mobility shift assays. Five proteins (CbpB, DnaA, Fis, IHF, and Lrp) were found to bind to specific DNA sequences, while the remaining seven proteins (CbpA, Dps, Hfq, H-NS, HU, IciA, and StpA) showed apparently sequence-nonspecific DNA binding activities. Four proteins, CbpA, Hfq, H-NS, and IciA, showed the binding preference for the curved DNA. From the apparent dissociation constant (K(d)) determined using the sequence-specific or nonspecific DNA probes, the order of DNA binding affinity were determined to be: HU > IHF > Lrp > CbpB(Rob) > Fis > H-NS > StpA > CbpA > IciA > Hfq/Dps, ranging from 25 nM (HU binding to the non-curved DNA) to 250 nM (Hfq binding to the non-curved DNA), under the assay conditions employed.
Current evidence suggests that the length of poly(A) tails of bacterial mRNAs result from a competition between poly(A) polymerase and exoribonucleases that attack the 3' ends of RNAs. Here, we show that host factor Hfq is also involved in poly(A) tail metabolism. Inactivation of the hfq gene reduces the length of poly(A) tails synthesized at the 3' end of the rpsO mRNA by poly(A) polymerase I in vivo. In vitro, Hfq stimulates synthesis of long tails by poly(A) polymerase I. The strong binding of Hfq to oligoadenylated RNA probably explains why it stimulates elongation of primers that already harbor tails of 20-35 A. Polyadenylation becomes processive in the presence of Hfq. The similar properties of Hfq and the PABPII poly(A) binding protein, which stimulates poly(A) tail elongation in mammals, indicates that similar mechanisms control poly(A) tail synthesis in prokaryotes and eukaryotes.
The adaptation of mRNA stability to environmental changes is a means of cells to adjust the level of gene expression. The Escherichia coli ompA mRNA has served as one of the paradigms for regulated mRNA decay in prokaryotes. The stability of the transcript is known to be correlated inversely with the bacterial growth rate. Thus, the regulation of ompA mRNA stability meets the physiological needs to adjust the level of ompA expression to the rate of cell division. Recently, host factor I (Hfq/HF1) was shown to be involved in the regulation of ompA mRNA stability under slow growth conditions. Here, we present the first direct demonstration that 30S ribosomes bound to the ompA 5'-UTR protect the transcript from RNase E cleavage in vitro. However, the 30S protection was found to be abrogated in the presence of Hfq. Toeprinting and in vitro translation assays revealed that translation of ompA is repressed in the presence of Hfq. These in vitro studies are corroborated by in vivo expression studies demonstrating that the reduced synthesis rate of OmpA effected by Hfq results in functional inactivation of the ompA mRNA. The data are discussed in terms of a model wherein Hfq regulates the stability of ompA mRNA by competing with 30S ribosomes for binding to the ompA 5'-UTR.
Background:
The genome DNA of Escherichia coli is folded into the nucleosome-like structure, often called a nucleoid, by the binding of several DNA-binding proteins. We previously determined the specificity and affinity of DNA-binding for 12 species of the E. coli DNA-binding protein, and their intracellular concentrations at various growth phases. The intracellular localization of these proteins in E. coli could be predicted from these data, but no attempt has been made thus far to directly observe the intracellular distribution of the DNA-binding proteins.
Results:
The intracellular localization in Escherichia coli of 10 species of the nucleoid-associated protein, three components of the transcripton apparatus, and three components of the translation machinery was investigated by indirect immuno-fluorescence microscopy. The DNA-binding proteins could be classified into two groups. The group-I proteins, including the major nucleoid-structural proteins, H-NS, HU, IHF, StpA and Dps, are distributed uniformly within the entire nucleoid. In contrast, the group-II proteins, which are presumed to possess regulatory activities of DNA functions accumulate at specific loci within the nucleoid, forming 2 (SeqA), 3-4 (CbpA and CbpB) and 6-10 (Fis and IciA) immuno-stained dots. Each immuno-stained dot may represent either the association of a hundred to one thousand molecules of each DNA-binding protein at a specific locus of the genome DNA or the assembly of protein-associated DNA segments from different domains of the folded genome. Both the RNA polymerase core enzyme and the sigma70 subunit are mainly associated with the nucleoid, but the anti-sigma70 factor (Rsd) appears to be accumulated at the boundary between the nucleoid and the cytosol in the stationary-phase cells. Here we show that the majority of Hfq is present in cytoplasm together with ribosomal proteins L7/L12 and RMF.
Conclusion:
The DNA-binding proteins of E. coli could be classified into two groups. One group proteins was distributed uniformly within the nucleoid, but the other group of proteins showed an irregular distribution, forming immuno-stained spots or clumps.
Within the yeast commitment complex, SmB, SmD1, and SmD3 make direct contact with the pre-mRNA substrate, close to the 5' splice site. Only these three Sm proteins have long and highly charged C-terminal tails, in metazoa as well as in yeast. We replaced these proteins with tail-truncated versions. Genetic assays demonstrate that the tails contribute to similar and overlapping functions, and cross-linking assays show that the tails make direct contact with the pre-mRNA in a largely sequence-independent manner. Other biochemical assays indicate that they function at least in part to stabilize the U1 snRNP-pre-mRNA interaction. We speculate that this role may be general, and may have even evolved to aid weak intermolecular nucleic acid interactions of only a few base pairs.
A burgeoning list of small RNAs with a variety of regulatory functions has been identified in both prokaryotic and eukaryotic cells. However, it remains difficult to identify small RNAs by sequence inspection. We used the high conservation of small RNAs among closely related bacterial species, as well as analysis of transcripts detected by high-density oligonucleotide probe arrays, to predict the presence of novel small RNA genes in the intergenic regions of the Escherichia coli genome. The existence of 23 distinct new RNA species was confirmed by Northern analysis. Of these, six are predicted to encode short ORFs, whereas 17 are likely to be novel functional small RNAs. We discovered that many of these small RNAs interact with the RNA-binding protein Hfq, pointing to a global role of the Hfq protein in facilitating small RNA function. The approaches used here should allow identification of small RNAs in other organisms.
The 102 aa Hfq protein of Escherichia coli (Hfq(Ec)) was first described as a host factor required for phage Qbeta replication. More recently, Hfq was shown to affect the stability of several E. coli mRNAs, including ompA mRNA, where it interferes with ribosome binding, which in turn results in rapid degradation of the transcript. In contrast, Hfq is also required for efficient translation of the E. coli and Salmonella typhimurium rpoS gene, encoding the stationary sigma factor. In this study, the authors have isolated and characterized the Hfq homologue of Pseudomonas aeruginosa (Hfq(Pa)), which consists of only 82 aa. The 68 N-terminal amino acids of Hfq(Pa) show 92% identity with Hfq(Ec). Hfq(Pa) was shown to functionally replace Hfq(Ec) in terms of its requirement for phage Qbeta replication and for rpoS expression. In addition, Hfq(Pa) exerted the same negative effect on E. coli ompA mRNA expression. As judged by proteome analysis, the expression of either the plasmid-borne hfq(Pa) or the hfq(Ec) gene in an E. coli Hfq(-) RpoS(-) strain revealed no gross difference in the protein profile. Both Hfq(Ec) and Hfq(Pa) affected the synthesis of approximately 26 RpoS-independent E. coli gene products. These studies showed that the functional domain of Hfq resides within its N-terminal domain. The observation that a C-terminally truncated Hfq(Ec) lacking the last 27 aa [Hfq(Ec(75))] can also functionally replace the full-length E. coli protein lends further support to this notion.
In prokaryotes, Hfq regulates translation by modulating the structure of numerous RNA molecules by binding preferentially to A/U-rich sequences. To elucidate the mechanisms of target recognition and translation regulation by Hfq, we determined the crystal structures of the Staphylococcus aureus Hfq and an Hfq-RNA complex to 1.55 and 2.71 A resolution, respectively. The structures reveal that Hfq possesses the Sm-fold previously observed only in eukaryotes and archaea. However, unlike these heptameric Sm proteins, Hfq forms a homo-hexameric ring. The Hfq-RNA structure reveals that the single-stranded hepta-oligoribonucleotide binds in a circular conformation around a central basic cleft, whereby Tyr42 residues from adjacent subunits stack with six of the bases, and Gln8, outside the Sm motif, provides key protein-base contacts. Such binding suggests a mechanism for Hfq function.
Hfq, a bacterial RNA‐binding protein, was recently shown to contain the Sm1 motif, a characteristic of Sm and LSm proteins
that function in RNA processing events in archaea and eukaryotes. In this report, comparative structural modeling was used
to predict a three‐dimensional structure of the Hfq core sequence. The predicted structure aligns with most major features
of the Methanobacterium thermoautotrophicum LSm protein structure. Conserved residues in Hfq are positioned at the same structural locations responsible for subunit
assembly and RNA interaction in Sm proteins. A highly conserved portion of Hfq assumes a structural fold similar to the Sm2
motif of Sm proteins. The evolution of the Hfq protein was explored by conducting a BLAST search of microbial genomes followed
by phylogenetic analysis. Approximately half of the 140 complete or nearly complete genomes examined contain at least one
gene coding for Hfq. The presence or absence of Hfq closely followed major bacterial clades. It is absent from high‐level
clades and present in the ancient Thermotogales‐Aquificales clade and all proteobacteria except for those that have undergone
major reduction in genome size. Residues at three positions in Hfq form signatures for the beta/gamma proteobacteria, alpha
proteobacteria and low GC Gram‐positive bacteria groups.
The bacterial Hfq protein modulates the stability or the translation of mRNAs and has recently been shown to interact with small regulatory RNAs in E. coli. Here we show that Hfq belongs to the large family of Sm and Sm-like proteins: it contains a conserved sequence motif, known as the Sm1 motif, forms a doughnut-shaped structure, and has RNA binding specificity very similar to the Sm proteins. Moreover, we provide evidence that Hfq strongly cooperates in intermolecular base pairing between the antisense regulator Spot 42 RNA and its target RNA. We speculate that Sm proteins in general cooperate in bimolecular RNA-RNA interaction and that protein-mediated complex formation permits small RNAs to interact with a broad range of target RNAs.
Hfq (HF1) is a polyfunctional translational regulator of numerous bacterial mRNAs. Its physico-chemical properties, possible mechanisms regulating bacterial translation, and the effect of Hfq on transcription of several mRNAs are considered. A similarity of Hfq and eukaryotic mRNA splicing proteins is discussed. Data are reviewed on the roles of Hfq in poly(A) metabolism and formation of the bacterial nucleoid and on the Hfq interaction with untranslated regulatory RNAs.
In prokaryotes, Hfq regulates translation by modulating the structure of numerous RNA molecules by binding preferentially to A/U-rich sequences. To elucidate the mechanisms of target recognition and translation regulation by Hfq, we determined the crystal structures of the Staphylococcus aureus Hfq and an Hfq–RNA complex to 1.55 and 2.71 Å resolution, respectively. The structures reveal that Hfq possesses the Sm-fold previously observed only in eukaryotes and archaea. However, unlike these heptameric Sm proteins, Hfq forms a homo-hexameric ring. The Hfq–RNA structure reveals that the single-stranded hepta-oligoribonucleotide binds in a circular conformation around a central basic cleft, whereby Tyr42 residues from adjacent subunits stack with six of the bases, and Gln8, outside the Sm motif, provides key protein–base contacts. Such binding suggests a mechanism for Hfq function.
Summary The Host Factor required for in vitro coliphage Qß RNA replication, a heat-stable RNA binding protein present in uninfectedEscherichia coli, has been detected by both immunological and functional tests inAcinetobacter calcoaceticus, Klebsiella pneumoniae, Pseudomonas aeruginosa andPseudomonas putida. It was not detectable by these criteria inBacillus stearothermophilus, Bacillus subtilis, Caulobacter crescentus, Micrococcus lysodeikticus, Rhodopseudomonas capsulata orSaccharomyces cerevisiae. InEscherichia coli the Host Factor protein has been shown to be associated with ribosomes. It is demostrated here that this association is specific for the 30S ribosomal subunit.
Ring-shaped structures containing seven Sm or Sm-like proteins are stable components of several small nuclear ribonucleoprotein particles that function in pre-mRNA splicing. Recent reports describe a role for a distinct complex of seven Sm-like proteins in a very different process: mRNA degradation.
The σS (RpoS) subunit of RNA polymerase is the master regulator of the general stress response in Escherichia coli and related bacteria. While rapidly growing cells contain very little σS, exposure to many different stress conditions results in rapid and strong σS induction. Consequently, transcription of numerous σS-dependent genes is activated, many of which encode gene products with stress-protective functions. Multiple signal integration in the control of the cellular σS level is achieved by rpoS transcriptional and translational control as well as by regulated σS proteolysis, with various stress conditions differentially affecting these levels of σS control. Thus, a reduced growth rate results in increased rpoS transcription whereas high osmolarity, low temperature, acidic pH, and some late-log-phase signals stimulate the translation of already present rpoS mRNA. In addition, carbon starvation, high osmolarity, acidic pH, and high temperature result in stabilization of σS, which, under nonstress conditions, is degraded with a half-life of one to several minutes. Important cis-regulatory determinants as well as trans-acting regulatory factors involved at all levels of σS regulation have been identified. rpoS translation is controlled by several proteins (Hfq and HU) and small regulatory RNAs that probably affect the secondary structure of rpoS mRNA. For σS proteolysis, the response regulator RssB is essential. RssB is a specific direct σS recognition factor, whose affinity for σS is modulated by phosphorylation of its receiver domain. RssB delivers σS to the ClpXP protease, where σS is unfolded and completely degraded. This review summarizes our current knowledge about the molecular functions and interactions of these components and tries to establish a framework for further research on the mode of multiple signal input into this complex regulatory system.
Thesis (A.M.)--Indiana University, 1975. Vita.
A factor fraction essential for the in vitro synthesis of RNA bacteriophage Qbeta-RNA has been isolated from both infected and uninfected E. coli. This indicates that the contribution of the last bacterium to the replication of Qbeta-RNA is more extensive than was earlier thought.
The affinity of Escherichia coli host factor protein for a variety of ribonucleic acids (RNAs) is compared in an equilibrium competition assay with (pA)15 or (pA)27 as the common probe. Of the homopolymers tested, only polyriboadenylate [poly(rA)] binds the protein with a high affinity. At low ionic strength (0.1 M NaCl), the binding to Q beta RNA is much stronger than to the oligoadenylates, but the situation is reversed upon fragmentation of the RNA with ribonuclease T1. Increasing the ionic strength results in a drastic reduction of the affinity of host factor for Q beta RNA over a relatively narrow salt range (0.1--0.3 M NaCl). Over the same range, added salt greatly reduces the tendency of host factor hexamers to aggregate. The tight binding of host factor to Q beta RNA is proposed to result from the binding of an aggregate, which can interact with several low affinity sites on the RNA simultaneously.
The interaction of Escherichia coli host factor 1 with oligoadenylate [oligo(A)] was studied by fluorescence and filter retention techniques. The intrinsic fluorescence of the host factor is quenched by up to 60% by the addition of oligo(A). Fluorescence titrations at high protein concentrations (6 microM) give a saturation point of 14 A residues per host factor hexamer regardless of chain length or ionic strength. Nitrocellulose filter retention experiments at much lower concentrations (1 nM) indicate equimolar complexes form between (pA)l (12 less than l less than 27) and host factor hexamers. The smallest number of contiguous A residues which allows the formation of all favorable protein--RNA contacts is 16 at both low and high salt concentrations. At 0.1 M NaCl, the molar association constants are in the range of 10(10)--10(11) M-1 (15 less than l less than 27) and decrease only slightly with ionic strength, indicating a large nonionic component in the interaction. Cyclized (pA)l was shown to have a higher affinity for host factor than its linear counterparts when l is 18 or greater but a lower relative affinity when l is 15. This suggests that the binding site on the hexamer has a circular spatial orientation.
The region immediately downstream from the miaA tRNA modification gene at 94.8 min contains the hfq gene and the hflA region, which are important in the bacteriophage Q beta and lambda life cycles. The roles of these genes in bacteria remain largely unknown. We report here the characterization of two chromosomal hfq insertion mutations. An omega (omega) cassette insertion near the end of hfq resulted in phenotypes only slightly different from the parent, although transcript mapping demonstrated that the insertion was completely polar on hflX expression. In contrast, an equally polar omega cassette insertion near the beginning of hfq caused pronounced pleiotropic phenotypes, including decreased growth rates and yields, decreased negative supercoiling of plasmids in stationary phase, increased cell size, osmosensitivity, increased oxidation of carbon sources, increased sensitivity to ultraviolet light, and suppression of bgl activation by hns mutations. hfq::omega mutant phenotypes were distinct from those caused by omega insertions early in the miaA tRNA modification gene. On the other hand, both hfq insertions interfered with lambda phage plaque formation, probably by means of polarity at the hflA region. Together, these results show that hfq function plays a fundamental role in Escherichia coli physiology and that hfq and the hflA-region are in the amiB-mutL-miaA-hfq-hflX superoperon.
The host factor (HF-I) for phage Q beta RNA replication is a small protein of 102 amino acid residues encoded by the hfq gene at 94.8 min on the Escherichia coli chromosome. The synthesis rate of HF-I at the exponential-growth phase is higher than at the stationary phase, and it increases concomitantly with the increase in cell growth rate. The intracellular level of HF-I is about 30,000 to 60,000 molecules per cell, the majority being associated with ribosomes as one of the salt wash proteins. Taken together, we suggest that HF-I is one of the growth-related proteins.
The rpoS-encoded sigma(S) subunit of RNA polymerase in Escherichia coli is a global regulatory factor involved in several stress responses. Mainly because of increased rpoS translation and stabilization of sigma(S), which in nonstressed cells is a highly unstable protein, the cellular sigma(S) content increases during entry into stationary phase and in response to hyperosmolarity. Here, we identify the hfq-encoded RNA-binding protein HF-I, which has been known previously only as a host factor for the replication of phage Qbeta RNA, as an essential factor for rpoS translation. An hfq null mutant exhibits strongly reduced sigma(S) levels under all conditions tested and is deficient for growth phase-related and osmotic induction of sigma(S). Using a combination of gene fusion analysis and pulse-chase experiments, we demonstrate that the hfq mutant is specifically impaired in rpoS translation. We also present evidence that the H-NS protein, which has been shown to affect rpoS translation, acts in the same regulatory pathway as HF-I at a position upstream of HF-I or in conjunction with HF-I. In addition, we show that expression and heat induction of the heat shock sigma factor sigma(32) (encoded by rpoH) is not dependent on HF-I, although rpoH and rpoS are both subject to translational regulation probably mediated by changes in mRNA secondary structure. HF-I is the first factor known to be specifically involved in rpoS translation, and this role is the first cellular function to be identified for this abundant ribosome-associated RNA-binding protein in E. coli.
The RpoS transcription factor (also called sigma Sor sigma 38) is required for the expression of a number of stationary-phase and osmotically inducible genes in Escherichia coli. RpoS is also a virulence factor for several pathogenic bacteria, including Salmonella typhimurium. The activity of RpoS is regulated in response to several different signals, at the transcriptional and translational levels as well as by proteolysis. Here we report that host factor I (HF-I), the product of the hfq gene, is required for efficient expression of rpoS in S. typhimurium. HF-I is a small, heat-stable, site-specific RNA-binding protein originally characterized for its role in replication of the RNA bacteriophage Q beta of E. coli. Its role in the uninfected bacterial cell has previously been unknown. Assays of Beta-galactosidase in strains with rpoS-lac fusions, Western blot (immunoblot) analysis, and pulse-labeling and immunoprecipitation of both fusion proteins and native RpoS show that an S. typhimurium hfq mutant has a four- to sevenfold reduction in expression of rpoS that is attributable primarily to a defect in translation. These results add a new level of complexity to the regulation of RpoS activity.
RNA-protein interactions between bacteriophage Qbeta plus strand RNA and the components of the Qbeta replicase system were studied by deletion analysis. Internal, 5'-terminal and 3'-terminal deletions were assayed for template activity with replicase in vitro. Of the two internal binding sites previously described for replicase, we found that the S-site (map position 1247 to 1346) could be deleted without any significant effect on template activity, whereas deletion of the M-site (map position 2545 to 2867) resulted in a strong inactivation and a high salt sensitivity of the residual activity. Binding complexes of the deletion mutant RNAs with the different proteins involved in Qbeta RNA replication were analysed by electron microscopy. The formation of looped complex structures, previously reported and explained as simultaneous interactions with replicase at the S and the M-site, was abolished by deleting the S-site but, surprisingly, not by deleting the M-site. The same types of complexes observed with replicase were also formed with purified protein S1 (the alpha subunit of replicase), suggesting that these internal interactions with Qbeta RNA are mediated by the S1 protein. The Qbeta host factor, a protein required for the template activity of the Qbeta plus strand, was reported earlier to form similar complexes by binding to the S and M-sites (or adjacent sites) and in addition to the 3'-end, resulting in double-looped structures. The patterns of looped complexes observed with the deletion mutant RNAs suggest that the binding of host factor might not involve the S and M-sites themselves but adjacent downstream sites. An additional internal host factor interaction near map position 2300 was detected with several mutant RNAs. Qbeta RNA molecules with 3'-truncations formed 3'-terminal loops with similar efficiency as wild-type RNA, indicating that recognition of the 3'-end by host factor is not dependent on a specific 3'-terminal base sequence.
We found that plasmids isolated by alkaline-lysis method occasionally showed abnormal mobility on agarose gel electrophoresis. This abnormality was not detected after phenol extraction of plasmids, indicating that it was caused by proteinous factor(s). A 15-kDa protein was found in the plasmid preparations on SDS-PAGE. The sequence of eighteen N-terminal amino acid residues of the 15-kDa protein was identical with the host factor I (HF-I) encoded by the hfq gene at 95 min on the Escherichia coli chromosome map, which is known to be required for bacteriophage Qbeta replication. The HF-I protein was purified and in vitro DNA binding experiment was carried out. HF-I bound to both supercoiled DNA and linear DNA and the binding of HF-I seemed to be sequence-nonspecific.
The selective degradation of messenger RNAs enables cells to regulate the levels of particular mRNAs in response to changes in the environment. Ribonuclease (RNase) E, a single-strand-specific endonuclease that is found in a multi-enzyme complex known as the 'degradosome', initiates the degradation of many mRNAs in Escherichia coli. Its relative lack of sequence specificity and the presence of many potential cleavage sites in mRNA substrates cannot explain why mRNA decay frequently proceeds in a net 5'-to-3' direction. I have prepared covalently closed circular derivatives of natural substrates, the rpsT mRNA encoding ribosomal protein S20 and the 9S precursor to 5S ribosomal RNA, and find that these derivatives are considerably more resistant to cleavage in vitro by RNase E than are linear molecules. Moreover, antisense oligo-deoxynucleotides complementary to the 5' end of linear substrates significantly reduce the latter's susceptibility to attack by RNase E. Finally, natural substrates with terminal 5'-triphosphate groups are poorly cleaved by RNase E in vitro, whereas 5' monophosphorylated substrates are strongly preferred. These results show that RNase E has inherent vectorial properties, with its activity depending on the 5' end of its substrates; this can account for the direction of mRNA decay in E. coli, the phenomenon of 'all or none' mRNA decay, and the stabilization provided by 5' stem-loop structures.
The stability of the ompA mRNA depends on the bacterial growth rate. The 5' untranslated region is the stability determinant of this transcript and the target of the endoribonuclease, RNase E, the key player of mRNA degradation. An RNA-binding protein with affinity for the 5' untranslated region ompA was purified and identified as Hfq, a host factor initially recognized for its function in phage Qbeta replication. The ompA RNA-binding activity parallels the amount of Hfq, which is elevated in bacteria cultured at slow growth rate, a condition leading to facilitated degradation of the ompA mRNA. In hfq mutant cells with a deficient Hfq gene product, the RNA-binding activity is missing, and analysis of the ompA mRNA showed that the growth-rate dependence of degradation is lost. Furthermore, the half-life of the ompA mRNA is prolonged in the mutant cells, irrespective of growth rate. Hfq has no affinity for the lpp transcript whose degradation, like that of bulk mRNA, is not affected by bacterial growth rate. Compatible with our results, we found that the intracellular concentration of RNase E and its associated degradosome components is independent of bacterial growth rate. Thus our results suggest a regulatory role for Hfq that specifically facilitates the ompA mRNA degradation in a growth rate-dependent manner.
Bacterial cells contain several small RNAs (sRNAs) that are not translated. These stable, abundant RNAs act by multiple mechanisms, such as RNA-RNA basepairing, RNA-protein interactions and intrinsic RNA activity, and regulate diverse cellular functions, including RNA processing, mRNA stability, translation, protein stability and secretion.
We describe the isolation and molecular characterization of seven distinct proteins present in human [U4/U6.U5] tri-snRNPs. These proteins exhibit clear homology to the Sm proteins and are thus denoted LSm (like Sm) proteins. Purified LSm proteins form a heteromer that is stable even in the absence of RNA and exhibits a doughnut shape under the electron microscope, with striking similarity to the Sm core RNP structure. The purified LSm heteromer binds specifically to U6 snRNA, requiring the 3'-terminal U-tract for complex formation. The 3'-end of U6 snRNA was also co-precipitated with LSm proteins after digestion of isolated tri-snRNPs with RNaseT(1). Importantly, the LSm proteins did not bind to the U-rich Sm sites of intact U1, U2, U4 or U5 snRNAs, indicating that they can only interact with a 3'-terminal U-tract. Finally, we show that the LSm proteins facilitate the formation of U4/U6 RNA duplices in vitro, suggesting that the LSm proteins may play a role in U4/U6 snRNP formation.
Ring-shaped structures containing seven Sm or Sm-like proteins are stable components of several small nuclear ribonucleoprotein particles that function in pre-mRNA splicing. Recent reports describe a role for a distinct complex of seven Sm-like proteins in a very different process: mRNA degradation.
Significant advances have been made in elucidating the biogenesis pathway and three-dimensional structure of the UsnRNPs, the building blocks of the spliceosome. U2 and U4/U6*U5 tri-snRNPs functionally associate with the pre-mRNA at an earlier stage of spliceosome assembly than previously thought, and additional evidence supporting UsnRNA-mediated catalysis of pre-mRNA splicing has been presented.
The bacterial Hfq protein modulates the stability or the translation of mRNAs and has recently been shown to interact with small regulatory RNAs in E. coli. Here we show that Hfq belongs to the large family of Sm and Sm-like proteins: it contains a conserved sequence motif, known as the Sm1 motif, forms a doughnut-shaped structure, and has RNA binding specificity very similar to the Sm proteins. Moreover, we provide evidence that Hfq strongly cooperates in intermolecular base pairing between the antisense regulator Spot 42 RNA and its target RNA. We speculate that Sm proteins in general cooperate in bimolecular RNA-RNA interaction and that protein-mediated complex formation permits small RNAs to interact with a broad range of target RNAs.
The Escherichia coli host factor I, Hfq, binds to many small regulatory RNAs and is required for OxyS RNA repression of fhlA and rpoS mRNA translation. Here we report that Hfq is a bacterial homolog of the Sm and Sm-like proteins integral to RNA processing and mRNA degradation complexes in eukaryotic cells. Hfq exhibits the hallmark features of Sm and Sm-like proteins: the Sm1 sequence motif, a multisubunit ring structure (in this case a homomeric hexamer), and preferential binding to polyU. We also show that Hfq increases the OxyS RNA interaction with its target messages and propose that the enhancement of RNA-RNA pairing may be a general function of Hfq, Sm, and Sm-like proteins.
In this issue of Molecular Cell, Zhang et al. and Møller et al. independently report studies of the E. coli Hfq protein, revealing significant sequence similarities with human Sm proteins. Their findings suggest that Hfq, and the Sm and Sm-like (Lsm) proteins, may function in stabilizing interactions between RNA molecules.
A small RNA, RyhB, was found as part of a genomewide search for novel small RNAs in Escherichia coli. The RyhB 90-nt RNA down-regulates a set of iron-storage and iron-using proteins when iron is limiting; it is itself negatively regulated by the ferric uptake repressor protein, Fur (Ferric uptake regulator). RyhB RNA levels are inversely correlated with mRNA levels for the sdhCDAB operon, encoding succinate dehydrogenase, as well as five other genes previously shown to be positively regulated by Fur by an unknown mechanism. These include two other genes encoding enzymes in the tricarboxylic acid cycle, acnA and fumA, two ferritin genes, ftnA and bfr, and a gene for superoxide dismutase, sodB. Fur positive regulation of all these genes is fully reversed in an ryhB mutant. Our results explain the previously observed inability of fur mutants to grow on succinate. RyhB requires the RNA-binding protein, Hfq, for activity. Sequences within RyhB are complementary to regions within each of the target genes, suggesting that RyhB acts as an antisense RNA. In sdhCDAB, the complementary region is at the end of the first gene of the sdhCDAB operon; full-length sdhCDAB message disappears and a truncated message, equivalent in size to the region upstream of the complementarity, is detected when RyhB is expressed. RyhB provides a mechanism for the cell to down-regulate iron-storage proteins and nonessential iron-containing proteins when iron is limiting, thus modulating intracellular iron usage to supplement mechanisms for iron uptake directly regulated by Fur.
Bacterial small, untranslated RNAs are important regulators that often act to transmit environmental signals when cells encounter suboptimal or stressful growth conditions. These RNAs help modulate changes in cellular metabolism to optimize utilization of available nutrients and improve the probability for survival.
In recent years, systematic searches of both prokaryote and eukaryote genomes have identified a staggering number of small RNAs, the biological functions of which remain unknown. Small RNA-based regulators are well known from bacterial plasmids. They act on target RNAs by sequence complementarity; that is, they are antisense RNAs. Recent findings suggest that many of the novel orphan RNAs encoded by bacterial and eukaryotic chromosomes might also belong to a ubiquitous, heterogeneous class of antisense regulators of gene expression.
Proteins of largely unknown function related to the Sm proteins present in the core domain of eukaryotic small nuclear ribonucleoprotein particles have recently been detected in Archaea. In contrast to eukaryotes, Archaea contain maximally two distinct Sm-related proteins belonging to different subfamilies, we refer to as Sm1 and Sm2. Here we report the crystal structures of the Sm1- and Sm2-type proteins from the hyperthermophilic euryarchaeon Archaeoglobus fulgidus (AF-Sm1 and AF-Sm2) at a resolution of 2.5 and 1.95 A, respectively. While the AF-Sm1 protein forms a heptameric ring structure similar to that found in other archaeal Sm1-type proteins, the AF-Sm2 protein unexpectedly forms a homo-hexamer in the crystals, and, as is evident from the mass spectrometric analysis, also in solution. Both proteins have essentially the same monomer fold and inter-subunit beta-sheet hydrogen bonding giving rise to a similar overall architecture of the doughnut-shaped six and seven-membered rings. In addition, a conserved uracil-binding pocket identified previously in an AF-Sm1/RNA complex, suggests a common RNA-binding mode for the AF-Sm1 and AF-Sm2 proteins, in line with solution studies showing preferential binding to U-rich oligonucleotides for both proteins. Clear differences are however seen in the charge distribution within the two structures. The rough faces of the rings, i.e. the faces not containing the base binding pockets, have opposite charges in the two structures, being predominantly positive in AF-Sm1 and negative in AF-Sm2. Differences in the ionic interactions between subunits provide an explanation for the distinctly different oligomerisation behaviour of the AF-Sm1 and AF-Sm2 proteins and of Sm1- and Sm2-type proteins in general, as well as the stability of their complexes. Implications for the functions of archaeal Sm proteins are being discussed.
The physiological role of Escherichia coli Spot 42 RNA has remained obscure, even though the 109-nucleotide RNA was discovered almost three decades ago. Structural features of Spot 42 RNA and previous work suggested to us that the RNA might be a regulator of discoordinate gene expression of the galactose operon, a control that is only understood at the phenomenological level. The effects of controlled expression of Spot 42 RNA or deleting the gene (spf) encoding the RNA supported this hypothesis. Down-regulation of galK expression, the third gene in the gal operon, was only observed in the presence of Spot 42 RNA and required growth conditions that caused derepression of the spf gene. Subsequent biochemical studies showed that Spot 42 RNA specifically bound at the galK Shine-Dalgarno region of the galETKM mRNA, thereby blocking ribosome binding. We conclude that Spot 42 RNA is an antisense RNA that acts to differentially regulate genes that are expressed from the same transcription unit. Our results reveal an interesting mechanism by which the expression of a promoter distal gene in an operon can be modulated and underline the importance of antisense control in bacterial gene regulation.
The sigma(S) (RpoS) subunit of RNA polymerase is the master regulator of the general stress response in Escherichia coli and related bacteria. While rapidly growing cells contain very little sigma(S), exposure to many different stress conditions results in rapid and strong sigma(S) induction. Consequently, transcription of numerous sigma(S)-dependent genes is activated, many of which encode gene products with stress-protective functions. Multiple signal integration in the control of the cellular sigma(S) level is achieved by rpoS transcriptional and translational control as well as by regulated sigma(S) proteolysis, with various stress conditions differentially affecting these levels of sigma(S) control. Thus, a reduced growth rate results in increased rpoS transcription whereas high osmolarity, low temperature, acidic pH, and some late-log-phase signals stimulate the translation of already present rpoS mRNA. In addition, carbon starvation, high osmolarity, acidic pH, and high temperature result in stabilization of sigma(S), which, under nonstress conditions, is degraded with a half-life of one to several minutes. Important cis-regulatory determinants as well as trans-acting regulatory factors involved at all levels of sigma(S) regulation have been identified. rpoS translation is controlled by several proteins (Hfq and HU) and small regulatory RNAs that probably affect the secondary structure of rpoS mRNA. For sigma(S) proteolysis, the response regulator RssB is essential. RssB is a specific direct sigma(S) recognition factor, whose affinity for sigma(S) is modulated by phosphorylation of its receiver domain. RssB delivers sigma(S) to the ClpXP protease, where sigma(S) is unfolded and completely degraded. This review summarizes our current knowledge about the molecular functions and interactions of these components and tries to establish a framework for further research on the mode of multiple signal input into this complex regulatory system.