Laura Lancaster’s research while affiliated with University of California, Santa Cruz and other places

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Publications (41)


Implication of nucleotides near the 3' end of 16S rRNA in guarding the translational reading frame
  • Article

March 2024

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6 Reads

Nucleic Acids Research

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Laura Lancaster

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[...]

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Harry F Noller

Loss of the translational reading frame leads to misincorporation and premature termination, which can have lethal consequences. Based on structural evidence that A1503 of 16S rRNA intercalates between specific mRNA bases, we tested the possibility that it plays a role in maintenance of the reading frame by constructing ribosomes with an abasic nucleotide at position 1503. This was done by specific cleavage of 16S rRNA at position 1493 using the colicin E3 endonuclease and replacing the resulting 3'-terminal 49mer fragment with a synthetic oligonucleotide containing the abasic site using a novel splinted RNA ligation method. Ribosomes reconstituted from the abasic 1503 16S rRNA were highly active in protein synthesis but showed elevated levels of spontaneous frameshifting into the -1 reading frame. We then asked whether the residual frameshifting persisting in control ribosomes containing an intact A1503 is due to the absence of the N6-dimethyladenosine modifications at positions 1518 and 1519. Indeed, this frameshifting was rescued by site-specific methylation in vitro by the ksgA methylase. These findings thus implicate two different sites near the 3' end of 16S rRNA in maintenance of the translational reading frame, providing yet another example of a functional role for ribosomal RNA in protein synthesis.


The role of GTP hydrolysis by EF-G in ribosomal translocation
  • Article
  • Full-text available

October 2022

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45 Reads

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12 Citations

Proceedings of the National Academy of Sciences

Translocation of transfer RNA (tRNA) and messenger RNA (mRNA) through the ribosome is catalyzed by the GTPase elongation factor G (EF-G) in bacteria. Although guanosine-5'-triphosphate (GTP) hydrolysis accelerates translocation and is required for dissociation of EF-G, its fundamental role remains unclear. Here, we used ensemble Förster resonance energy transfer (FRET) to monitor how inhibition of GTP hydrolysis impacts the structural dynamics of the ribosome. We used FRET pairs S12-S19 and S11-S13, which unambiguously report on rotation of the 30S head domain, and the S6-L9 pair, which measures intersubunit rotation. Our results show that, in addition to slowing reverse intersubunit rotation, as shown previously, blocking GTP hydrolysis slows forward head rotation. Surprisingly, blocking GTP hydrolysis completely abolishes reverse head rotation. We find that the S13-L33 FRET pair, which has been used in previous studies to monitor head rotation, appears to report almost exclusively on intersubunit rotation. Furthermore, we find that the signal from quenching of 3′-terminal pyrene–labeled mRNA, which is used extensively to follow mRNA translocation, correlates most closely with reverse intersubunit rotation. To account for our finding that blocking GTP hydrolysis abolishes a rotational event that occurs after the movements of mRNA and tRNAs are essentially complete, we propose that the primary role of GTP hydrolysis is to create an irreversible step in a mechanism that prevents release of EF-G until both the tRNAs and mRNA have moved by one full codon, ensuring productive translocation and maintenance of the translational reading frame.

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FIGURE 3. Domain IV mutations cause mRNA translocation defects. A fluorescence quenching assay (Studer et al. 2003) was used to measure mRNA translocation complex containing a 3 ′ -pyrene-labeled mRNA. (A,B) A pretranslocation complex was rapidly mixed with mutant forms of EF-G·GTP and quenching of fluorescence of the pyrene label was measured in a stopped-flow fluorimeter. Data were fit to double-exponential curves (Table 1). (C,D) Rates of mRNA quenching for EF-G mutants (C) S587P and (D) S588P were measured manually, due to their low translocation rates. Data could be fit to single-exponential curves.
FIGURE 4. In vitro translation of a full-length protein by domain IV mutant EF-Gs. A mRNA coding for ribosomal protein S2 was translated in vitro by 70S ribosomes in an E. coli system (Ali et al. 2006) using mutant forms of EF-G with S100 extract (A) containing or (B) lacking endogenous wild-type EF-G. (WT) Addition of wild-type EF-G; (No EF-G) wild-type EF-G not added; (S2) position of full-length protein S2; (23 kD) a translation product likely made from a 3'-truncated mRNA. All mutant EF-Gs except S587P and S588P are capable of catalyzing synthesis of full-length protein.
FIGURE 5. Domain IV mutations affect rates of intersubunit and 30S head rotation. (A,B) Reverse intersubunit rotation during translocation was measured by FRET using doubly labeled 70S ribosomes containing a Cy3 donor on 50S protein L9 and a Cy5 acceptor on 30S protein S6 in a stopped-flow fluorimeter (Ermolenko and Noller 2011). Data were fit to single-exponential curves. (C,D) Forward and reverse rotation of the head domain of the 30S subunit during translocation was measured by FRET using 70S ribosomes formed from doubly labeled 30S subunits containing an Alexa488 donor on protein S12 in the 30S body domain and an Alexa568 acceptor on protein S19 in the 30S domain (Guo and Noller 2012), in a stopped-flow fluorimeter. Data were fit to double-exponential curves corresponding to initial forward head rotation (downward curves) followed by reverse head rotation (upward curves). (WT) Wild-type EF-G.
FIGURE 8. Domain IV mutants stimulate frameshifting into the −1 reading frame. (A) Schematic showing (no RT) the S2 mRNA containing a slippery sequence at positions 381-388 showing the positions of +1 and −1 out-of-frame stop codons. (−1 RT) A mRNA designed to create read-through of the −1 frame UGA stop codon at position 417, which was replaced by a GGA sense codon. (+1 RT) A +1 read-through mRNA in which the out-of-frame +1 UGA stop codon at position 404 was replaced by a GGA sense codon. Frameshifting events can be assigned to the −1 or +1 reading frames according to whether a frameshift product of increased size appears when translating the −1 RT or +1 RT mRNA. (B) SDS gel showing results of translation through the +1 read-through (+1 RT), −1 read-through (−1 RT), and no-read-through (No RT) mRNAs. Products indicated are (S2), full-length S2 protein; (23 kD) 23 kD carboxy-terminal truncated EF-G product; (−1 RT) read-through product in the −1 frame; (−1 FS) frameshift product in the −1 frame; (−2 FS) product of 2 −1 frameshifting events. Appearance of the 16.6 kDa product with the −1 RT mRNA confirms that the 19.5 kDa band is indeed the product of −1 frameshifting.
FIGURE 9. Contacts between the tip of domain IV of EF-G and the RNA backbones of the codon-anticodon duplex. The crystal structure of a trapped chimeric hybrid-state translocation intermediate (Zhou et al. 2014) shows that (A) Gln507 and Tyr514 in loop I (red) form H-bonds with phosphate 37 in the anticodon loop; Gly 509 and Thr 508 are within Van der Waals contact distance of riboses 36 and 37. (B) His583 and Asp586 at the tip of loop II form H-bonds with the 2 ′ -OH of ribose 35 and phosphate 37 in the anticodon loop. (C) Gly510 in loop I makes the sole Van der Waals contact between domain IV and the mRNA backbone, at U20 of the GUA Val codon. (D) Schematic representations of domain IV interactions with the codon-anticodon duplex in the chimeric hybrid state complex (Zhou et al. 2014) and posttranslocation complex (Gao et al. 2009). Mutations at Gln507, His583, and Asp586 were found to confer severe frameshifting and translocation phenotypes (Tables 1, 2). In both crystal structures, all contacts with domain IV are with ribose and phosphate backbone moieties of the tRNA and mRNA. Contacts observed in the two structures are overlapping, but not identical; interactions with Thr508, Gly509, His583 are preserved between the two translocational states. Most of the contacts are with the backbone of the anticodon loop, centered around nucleotides that interact with the first and second codon positions. Note that both crystal structures were obtained from T. thermophilus, although we use E. coli numbering here; all residues are identical between the two species, except for Thr508, which is replaced by Ser508 in E. coli EF-G.

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Mutations in Domain IV of Elongation Factor EF-G Confer -1 Frameshifting

October 2020

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53 Reads

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15 Citations

RNA

A recent crystal structure of a ribosome complex undergoing partial translocation in the absence of elongation factor EF-G showed disruption of codon-anticodon pairing and slippage of the reading frame by -1, directly implicating EF-G in preservation of the translational reading frame. Among mutations identified in a random screen for dominant-lethal mutations of EF-G were a cluster of 6 that map to the tip of domain IV, which has been shown to contact the codon-anticodon duplex in trapped translocation intermediates. In vitro synthesis of a full-length protein using these mutant EF-Gs revealed dramatically increased -1 frameshifting, providing new evidence for a role for domain IV of EF-G in maintaining the reading frame. These mutations also caused decreased rates of mRNA translocation and rotational movement of the head and body domains of the 30S ribosomal subunit during translocation. Our results are in general agreement with recent findings from Rodnina and co-workers based on in vitro translation of an oligopeptide using EF-Gs containing mutations at two positions in domain IV, who found an inverse correlation between the degree of frameshifting and rates of translocation. Four of our six mutations are substitutions at positions that interact with the translocating tRNA, in each case contacting the RNA backbone of the anticodon loop. We suggest that EF-G helps to preserve the translational reading frame by preventing uncoupled movement of the tRNA through these contacts; a further possibility is that these interactions may stabilize a conformation of the anticodon that favors base-pairing with its codon.


The structural basis for inhibition of ribosomal translocation by viomycin

April 2020

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27 Reads

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25 Citations

Proceedings of the National Academy of Sciences

Viomycin, an antibiotic that has been used to fight tuberculosis infections, is believed to block the translocation step of protein synthesis by inhibiting ribosomal subunit dissociation and trapping the ribosome in an intermediate state of intersubunit rotation. The mechanism by which viomycin stabilizes this state remains unexplained. To address this, we have determined cryo-EM and X-ray crystal structures of Escherichia coli 70S ribosome complexes trapped in a rotated state by viomycin. The 3.8-Å resolution cryo-EM structure reveals a ribosome trapped in the hybrid state with 8.6° intersubunit rotation and 5.3° rotation of the 30S subunit head domain, bearing a single P/E state transfer RNA (tRNA). We identify five different binding sites for viomycin, four of which have not been previously described. To resolve the details of their binding interactions, we solved the 3.1-Å crystal structure of a viomycin-bound ribosome complex, revealing that all five viomycins bind to ribosomal RNA. One of these (Vio1) corresponds to the single viomycin that was previously identified in a complex with a nonrotated classical-state ribosome. Three of the newly observed binding sites (Vio3, Vio4, and Vio5) are clustered at intersubunit bridges, consistent with the ability of viomycin to inhibit subunit dissociation. We propose that one or more of these same three viomycins induce intersubunit rotation by selectively binding the rotated state of the ribosome at dynamic elements of 16S and 23S rRNA, thus, blocking conformational changes associated with molecular movements that are required for translocation.


On-demand single molecule analysis platform. a A nanopore-optofluidic chip combines liquid-core (blue) and solid-core (gray) optical waveguides; particles are introduced into the liquid-core waveguide by applying a voltage across reservoirs 1 and 2, where reservoir 2 is placed over a nanopore; fluorescence is excited via an intersecting solid-core waveguide and collected by the liquid-core waveguide. The chip is connected to an electronic circuit for implementing feedback control over the number of particles entering the channel through the nanopore b SEM image of a typical square well milled on the microchannel to remove the thick oxide layer for further nanopore drilling. c SEM image of a drilled nanopore. d Experimental demonstration of voltage-gated delivery of a single 70 S ribosome into the microfluidic channel; top: nanopore current (inset: zoomed in translocation), bottom: voltage applied across the nanopore
Gated delivery of single bioparticles with reconfigurable settings. a–c Current trace of voltage-gated delivery of single λ-DNA, Zika NS-1 protein, and NaCMC molecule respectively, into the microfluidic channel. d Example of delivery of user-defined particle number (here: two and three) into fluidic channel (top: current through pore (inset: zoomed in translocations); center: signals in detection circuit of digitized identification of particle translocation; bottom: voltage across pore turned off after the desired number of particles has been detected
Automated delivery of successive 70S ribosomes. a Automatic re-application of voltage across the pore after user-defined time delays (here: 10, 20, 50, and 100 ms) during which the pore is closed. Note that the vertical axis limit for INP has been chosen for best visibility of the molecular signatures. The saturation limit of the setup is 200 nA. b Demonstration of automated delivery of 48 ribosomes (~513/min) into the microfluidic channel where the voltage is re-applied 100 ms after each translocation; top: nanopore current, center: translocation detection pulses, bottom: voltage applied across pore; c zoomed-in view of panel b revealing translocation events and how pore is switched off for 100 ms after a translocation has been detected
Voltage-gated selection of specific particles from a mixture. a Scatter plot of differential current vs. dwell time of translocation events when only λ-DNAs (blue) and only ribosomes (red) are drawn through the same nanopore. b Demonstration of selective voltage gating of λ-DNAs from a mixture of ribosome and λ-DNA; top: current through nanopore, center: specific translocation detection pulses, bottom: voltage applied across pore; c zoomed-in view of panel b, revealing how specific targets are voltage-gated while others are not gated. d Scatter plot of differential current vs. dwell time of each translocation event of panel b, where magenta points show voltage-gated translocations, and black points show the translocations which are not gated, with thresholds shown by dotted lines
Fluorescence detection of λ-DNA molecules on demand. a top: Current through pore and electrical detection of a single λ-DNA entering fluidic channel (dashed box: zoomed-in view of translocation event); center: voltage across the pore preventing further translocations after event has been detected; bottom: Concurrently recorded fluorescence signal showing optical detection after characteristic transport time. b Introduction and detection of two λ-DNA molecules; the ambiguity of the double-peak electrical signal is removed by the optical detection after both DNA molecules have separated in the channel
On demand delivery and analysis of single molecules on a programmable nanopore-optofluidic device

August 2019

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167 Reads

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23 Citations

Nanopore-based single nanoparticle detection has recently emerged as a vibrant research field with numerous high-impact applications. Here, we introduce a programmable optofluidic chip for nanopore-based particle analysis: feedback-controlled selective delivery of a desired number of biomolecules and integration of optical detection techniques on nanopore-selected particles. We demonstrate the feedback-controlled introduction of individual biomolecules, including 70S ribosomes, DNAs and proteins into a fluidic channel where the voltage across the nanopore is turned off after a user-defined number of single molecular insertions. Delivery rates of hundreds/min with programmable off-times of the pore are demonstrated using individual 70S ribosomes. We then use real-time analysis of the translocation signal for selective voltage gating of specific particles from a mixture, enabling selection of DNAs from a DNA-ribosome mixture. Furthermore, we report optical detection of nanopore-selected DNA molecules. These capabilities point the way towards a powerful research tool for high-throughput single-molecule analysis on a chip.


Co-temporal Force and Fluorescence Measurements Reveal a Ribosomal Gear Shift Mechanism of Translation Regulation by Structured mRNAs

August 2019

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96 Reads

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60 Citations

Molecular Cell

The movement of ribosomes on mRNA is often interrupted by secondary structures that present mechanical barriers and play a central role in translation regulation. We investigate how ribosomes couple their internal conformational changes with the activity of translocation factor EF-G to unwind mRNA secondary structures using high-resolution optical tweezers with single-molecule fluorescence capability. We find that hairpin opening occurs during EF-G-catalyzed translocation and is driven by the forward rotation of the small subunit head. Modulating the magnitude of the hairpin barrier by force shows that ribosomes respond to strong barriers by shifting their operation to an alternative 7-fold-slower kinetic pathway prior to translocation. Shifting into a slow gear results from an allosteric switch in the ribosome that may allow it to exploit thermal fluctuations to overcome mechanical barriers. Finally, we observe that ribosomes occasionally open the hairpin in two successive sub-codon steps, revealing a previously unobserved translocation intermediate.


Spontaneous ribosomal translocation of mRNA and tRNAs into a chimeric hybrid state

April 2019

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37 Reads

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53 Citations

Proceedings of the National Academy of Sciences

The elongation factor G (EF-G)–catalyzed translocation of mRNA and tRNA through the ribosome is essential for vacating the ribosomal A site for the next incoming aminoacyl-tRNA, while precisely maintaining the translational reading frame. Here, the 3.2-Å crystal structure of a ribosome translocation intermediate complex containing mRNA and two tRNAs, formed in the absence of EF-G or GTP, provides insight into the respective roles of EF-G and the ribosome in translocation. Unexpectedly, the head domain of the 30S subunit is rotated by 21°, creating a ribosomal conformation closely resembling the two-tRNA chimeric hybrid state that was previously observed only in the presence of bound EF-G. The two tRNAs have moved spontaneously from their A/A and P/P binding states into ap/P and pe/E states, in which their anticodon loops are bound between the 30S body domain and its rotated head domain, while their acceptor ends have moved fully into the 50S P and E sites, respectively. Remarkably, the A-site tRNA translocates fully into the classical P-site position. Although the mRNA also undergoes movement, codon–anticodon interaction is disrupted in the absence of EF-G, resulting in slippage of the translational reading frame. We conclude that, although movement of both tRNAs and mRNA (along with rotation of the 30S head domain) can occur in the absence of EF-G and GTP, EF-G is essential for enforcing coupled movement of the tRNAs and their mRNA codons to maintain the reading frame.


The ribosome moves: RNA mechanics and translocation

December 2017

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138 Reads

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88 Citations

Nature Structural & Molecular Biology

During protein synthesis, mRNA and tRNAs must be moved rapidly through the ribosome while maintaining the translational reading frame. This process is coupled to large- and small-scale conformational rearrangements in the ribosome, mainly in its rRNA. The free energy from peptide-bond formation and GTP hydrolysis is probably used to impose directionality on those movements. We propose that the free energy is coupled to two pawls, namely tRNA and EF-G, which enable two ratchet mechanisms to act separately and sequentially on the two ribosomal subunits.


Ribosome structural dynamics in translocation: yet another functional role for ribosomal RNA

October 2017

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121 Reads

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55 Citations

Quarterly Reviews of Biophysics

Ribosomes are remarkable ribonucleoprotein complexes that are responsible for protein synthesis in all forms of life. They polymerize polypeptide chains programmed by nucleotide sequences in messenger RNA in a mechanism mediated by transfer RNA. One of the most challenging problems in the ribosome field is to understand the mechanism of coupled translocation of mRNA and tRNA during the elongation phase of protein synthesis. In recent years, the results of structural, biophysical and biochemical studies have provided extensive evidence that translocation is based on the structural dynamics of the ribosome itself. Detailed structural analysis has shown that ribosome dynamics, like aminoacyl-tRNA selection and catalysis of peptide bond formation, is made possible by the properties of ribosomal RNA.



Citations (28)


... Ada's presentation revealed that she and her colleagues had given up on the Hma LRS, possibly because of the space group instabilities that had given JBC REVIEWS: The PDB and the ribosome us so much trouble, and that they had decided to concentrate instead on the Tth SRS for which they had a 7 Å resolution map (31). Harry's talk dealt both with the results of some chemical probing experiments his group had done, and with the work they were doing with crystals of the 70S ribosome from Tth, for which they had a 7.8 Å resolution map (32). Thus, by the end of the 1999 meeting, it was clear to all that atomic resolution structures for ribosomes and ribosomal subunits were imminent. ...

Reference:

The PDB and the ribosome
Studies on the Structure and Function of Ribosomes by Combined Use of Chemical Probing and X-Ray Crystallography
  • Citing Chapter
  • April 2014

... Blocking GTP hydrolysis after the movement of mRNA and tRNA essentially and completely cancels the rotation of the structural head domains of the 30S ribosome. Meanwhile, GTP hydrolysis critically prevents the release of EF-G before the tRNA and mRNA have been moved by a complete codon and ensures productive translation and the maintenance of translated reading frames [60]. To elucidate how the nearly rigid EF-G corrects the inherent spontaneous dynamics of the ribosome in tRNA-mRNA translation, and how GTP hydrolysis and Pi release drive the dissociation of EF-G, time-resolved cryoelectron microscopy was used to visualize GTP-catalyzed translocation in the absence of an inhibitor [46]. ...

The role of GTP hydrolysis by EF-G in ribosomal translocation

Proceedings of the National Academy of Sciences

... To inhibit hydrolysis, we began by substituting GTP with the nonhydrolyzable analogs GDPNP and GDPCP and the slowly hydrolyzed GTP analog GTPγS. We also blocked GTP hydrolysis using EF-G carrying the GTPase-defective mutation H91L, identified previously in a screen for dominant-lethal mutations in EF-G (43). We tested the ribosome-dependent GTP hydrolysis activity of EF-G (H91L) and found that it was undetectable over background, even after several minutes at 37°(SI Appendix, Fig. S2). ...

Mutations in Domain IV of Elongation Factor EF-G Confer -1 Frameshifting

RNA

... AMPs mainly exert their activity against bacteria using two modes, either by acting directly on the membranes (membrane-targeting AMPs) and leading to destabilization of membrane integrity, or by targeting mechanisms that inhibit the synthesis of nucleic acids, functional proteins, or essential enzymes (non-membrane-targeting AMPs) (Figure 3) [160]. The aforementioned three modes of action in the cellular membrane were considered for a long time the main mode of action of the AMPs, but several studies have shown that besides membrane-target action, many AMPs also target essential cell components and cellular functions leading to bacterial death [166,167]. These AMPs invade the cells without disturbing the membrane and then affect critical cellular processes, inhibiting protein and nucleic acid synthesis [168][169][170], translation in the ribosome [167,171], bacteria cell wall synthesis [172], and chaperone proteins [173]. ...

The structural basis for inhibition of ribosomal translocation by viomycin
  • Citing Article
  • April 2020

Proceedings of the National Academy of Sciences

... The strong intrinsic helicase activity of the ribosome complex (Takyar et al. 2005), coupled with associated DEAD-box helicases like initiation factor eIF4A, helps overcome intervening RNA structures and RNA-protein complexes (Sweeney et al. 2021;Ryan and Schröder 2022). Stable hairpins can resist the unwinding process by helicases (Bleichert and Baserga 2007;Yang et al. 2007), which correlates with reduced translation efficiency (Chen et al. 2013a;Desai et al. 2019). This study extends the correlation between translation inhibition and stable structural features in an mRNA to include protein binding events. ...

Co-temporal Force and Fluorescence Measurements Reveal a Ribosomal Gear Shift Mechanism of Translation Regulation by Structured mRNAs
  • Citing Article
  • August 2019

Molecular Cell

... Kühn et al. produced another method of particle aggregation in a microfluidic setting [64][65][66][67]. Two counter-propagating beams are fed into a liquid-core channel from integrated waveguides. ...

On demand delivery and analysis of single molecules on a programmable nanopore-optofluidic device

... advances in the study of ribosome structure have begun to reveal the remarkable conformational flexibility of ribosomes. Major conformational changes are recognized to be associated with each phase of translational expansion [28,29]. Emerging peptides appear as carriers during synthesis and are prone to misfolding and aggregation, thus lacking the information needed to complete the folding until the end of translation. ...

Spontaneous ribosomal translocation of mRNA and tRNAs into a chimeric hybrid state
  • Citing Article
  • April 2019

Proceedings of the National Academy of Sciences

... One might expect that a translating ribosome could displace or even strip a transcribing RdRP. Ribosomes are molecular machines that utilize four GTP molecules for each translocation step, moving three nucleotides at a time (Noller et al. 2017). In contrast, transcription is a Brownian ratchet mechanism, where translocation is bidirectional and nucleotide addition provides directionality (Noe Gonzalez, Blears, and Svejstrup 2021;Turowski et al. 2020). ...

The ribosome moves: RNA mechanics and translocation
  • Citing Article
  • December 2017

Nature Structural & Molecular Biology

... This serves as a check point for the enzyme, as this transition occurs only rarely for the incorrect nucleotide and catalysis can occur only in the closed form ( 2 ). More complex nanomachines such as the ribosome go through a series of large-scale rearrangements that involve the sliding of the mRNA upon completion of the peptide synthesis step ( 3 ). Using cryogenic electron microscopy, it is now possible to generate experimentally the different structures adopted by a given nanomachine in the presence of different substrates. ...

Ribosome structural dynamics in translocation: yet another functional role for ribosomal RNA
  • Citing Article
  • October 2017

Quarterly Reviews of Biophysics

... In 67 addition, nascent polypeptides can also affect elongation rates through interactions with the ribosome 68 exit tunnel or by modulating kinetics of peptide bond formation (Collart and Weiss, 2020; Gutierrez et 69 al., 2013). Furthermore, strong RNA structures in the coding sequence of an mRNA are thought to slow 70 down ribosome translocation as well (Wen et al., 2008). Regulatory proteins can also slow down 71 elongation, including the signal recognition particle (SRP) that binds to and pauses ribosomes 72 translating transmembrane and secreted proteins (Halic et al., 2004), and Argonaute proteins 73 complexed with miRNAs (Sako et al., 2023). ...

Following translation by single ribosomes one codon at a time
  • Citing Article
  • March 2008