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ABSTRACT: In cucurbits phloem latex exudes from cut sieve tubes of the extrafascicular phloem (EFP) serving in defense against herbivores. We analyzed inducible defense mechanisms in the EFP of Cucurbita maxima after leaf damage. As an early systemic response, wounding elicited transient accumulation of jasmonates and a decrease in exudation probably due to partial sieve tube occlusion by callose. The energy status of the EFP was enhanced as indicated by increased levels of adenosine triphosphate, phosphate and intermediates of the citric acid cycle. Gas chromatography coupled to mass spectrometry also revealed that sucrose transport, gluconeogenesis/glycolysis and amino acid metabolism were up-regulated after wounding. Combining ProteoMinerTM technology for enrichment of low-abundance proteins with stable isotope-coded protein labeling (ICPL) we identified 51 wound-regulated phloem proteins. Two sucrose nonfermenting 1-related protein kinases and a 32 kDa 14-3-3 protein are candidate central regulators of stress metabolism in the EFP. Other proteins such as the silverleaf-whitefly-induced protein 1, mitogen-activated protein kinase 6 and heat shock protein 81 have known defensive functions. ICPL and western blot analyses indicated that cyclophilin 18 is a reliable marker for stress responses of the EFP. As a hint towards induction of redox-signaling we have observed delayed oxidation-triggered polymerization of the major phloem proteins 1 and 2 (PP1/PP2), which correlated with a decline in carbonylation of PP2. In sum, wounding triggered transient sieve tube occlusion, enhanced energy metabolism and accumulation of defense-related proteins in the pumpkin EFP. The systemic wound response was mediated by jasmonate and redox signaling.
Plant physiology 10/2012; · 6.53 Impact Factor
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ABSTRACT: The field of proteomics suffers from the immense complexity of even small proteomes and the enormous dynamic range of protein concentrations within a given sample. Most protein samples contain a few major proteins, which hamper in-depth proteomic analysis. In the human field, combinatorial hexapeptide ligand libraries (CPLL; such as ProteoMiner) have been used for reduction of the dynamic range of protein concentrations; however, this technique is not established in plant research. In this work, we present the application of CPLL to Arabidopsis (Arabidopsis thaliana) leaf proteins. One- and two-dimensional gel electrophoresis showed a decrease in high-abundance proteins and an enrichment of less abundant proteins in CPLL-treated samples. After optimization of the CPLL protocol, mass spectrometric analyses of leaf extracts led to the identification of 1,192 proteins in control samples and an additional 512 proteins after the application of CPLL. Upon leaf infection with virulent Pseudomonas syringae DC3000, CPLL beads were also used for investigating the bacterial infectome. In total, 312 bacterial proteins could be identified in infected Arabidopsis leaves. Furthermore, phloem exudates of pumpkin (Cucurbita maxima) were analyzed. CPLL prefractionation caused depletion of the major phloem proteins 1 and 2 and improved phloem proteomics, because 67 of 320 identified proteins were detectable only after CPLL treatment. In sum, our results demonstrate that CPLL beads are a time- and cost-effective tool for reducing major proteins, which often interfere with downstream analyses. The concomitant enrichment of less abundant proteins may facilitate a deeper insight into the plant proteome.
Plant physiology 05/2012; 159(3):902-14. · 6.53 Impact Factor
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ABSTRACT: Increasing evidences support the assumption that nitric oxide (NO) acts as a physiological mediator in plants. Understanding its pleiotropic effects requires a deep analysis of the molecular mechanisms underlying its mode of action. In the recent years, efforts have been made in the identification of plant proteins modified by NO at the post-translational level, notably by S-nitrosylation. This reversible process involves the formation of a covalent bond between NO and reactive cysteine residues. This research has now born fruits and numerous proteins regulated by S-nitrosylation have been identified and characterized. This review describes the basic principle of S-nitrosylation as well as the Biotin Switch Technique and its recent adaptations allowing the identification of S-nitrosylated proteins in physiological contexts. The impact of S-nitrosylation on the structure/function of selected proteins is further discussed.
Plant Science 11/2011; 181(5):527-33. · 2.94 Impact Factor
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ABSTRACT: Nitric oxide (NO) production is associated with many physiological situations in plants, and NO is a key signaling molecule throughout the lifespan of a plant. The complexity of the underlying signaling events are just starting to be unraveled. The basis for nitric oxide signaling, the production of the signaling molecule itself, is far from understood in plants. While in animals, three homologous NO synthases (NOS) isoforms have been identified, yet in higher plants no corresponding enzymes are known so far. More than half a dozen NO productive reactions have been observed in plants but only few of them have been thoroughly investigated. It remains to be elucidated how these parts act together to form the sophisticated NO signaling network observed in plants.
Plant Science 10/2011; 181(4):401-4. · 2.94 Impact Factor
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ABSTRACT: Nitric oxide (NO) is now recognised as a crucial player in plant defence against pathogens. Considerable progress has been made in defining upstream and downstream signals of NO. Recently, MAP kinases, cyclic nucleotide phosphates, calcium and phosphatidic acid were demonstrated to be involved in pathogen-induced NO-production. However, the search for inducers of NO synthesis is difficult because of the still ambiguous enzymatic source of NO. Accumulation of NO triggers signal transduction by other second messengers. Here we depict NON-EXPRESSOR OF PATHOGENESIS-RELATED 1 and glyceraldehyde-3-phosphate dehydrogenase as central redox switches translating NO redox signalling into cellular responses. Although the exact position of NO in defence signal networks is unresolved at last some NO-related signal cascades are emerging.
Current opinion in plant biology 08/2011; 14(6):707-14. · 10.33 Impact Factor
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ABSTRACT: In recent years, nitric oxide (NO) has been recognized as a signalling molecule of plants, being involved in diverse processes like germination, root growth, stomatal closing, and responses to various stresses. A mechanism of how NO can regulate physiological processes is the modulation of cysteine residues of proteins (S-nitrosylation) by S-nitrosoglutathione (GSNO), a physiological NO donor. The concentration of GSNO and the level of S-nitrosylated proteins are regulated by GSNO reductase, which seems to play a major role in NO signalling. To investigate the importance of NO in plant defense response, we performed a proteomic analysis of Arabidopsis wildtype and GSNO-reductase knock-out plants infected with both the avirulent and virulent pathogen strains of Pseudomonas syringae. Using 2-D DIGE technology in combination with MS, we identified proteins, which are differentially accumulated during the infection process. We observed that both lines were more resistant to avirulent infections than to virulent infections mainly due to the accumulation of stress-, redox-, and defense-related proteins. Interestingly, after virulent infections, we also observed accumulation of defense-related proteins, but no or low accumulation of stress- and redox-related proteins, respectively. In summary, we present here the first detailed proteomic analysis of plant defense response.
Proteomics 03/2011; 11(9):1664-83. · 4.43 Impact Factor
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ABSTRACT: Model systems have played a crucial role for understanding biological processes at genetic, molecular and systems levels. Arabidopsis thaliana is one of the best studied model species for higher plants. Large genomic resources and mutant collections made Arabidopsis an excellent source for functional and comparative genomics. Rice and Brachypodium have a great potential to become model systems for grasses. Given the agronomic importance of grass crops, it is an attractive strategy to apply knowledge from Arabidopsis to grasses. Despite many efforts successful reports are sparse. Knowledge transfer should generally work best between orthologous genes that share functionality and a common ancestor. In higher plants, however, recent genome projects revealed an active and rapid evolution of genome structure, which challenges the concept of one-to-one orthologous mates between two species. In this study, we estimated on the example of protein families that are involved in redox related processes, the impact of gene expansions on the success rate for a knowledge transfer from Arabidopsis to the grass species rice, sorghum and Brachypodium. The sparse synteny between dicot and monocot plants due to frequent rearrangements, translocations and gene losses strongly impairs and reduces the number of orthologs detectable by positional conservation. To address the limitations of sparse synteny and expanded gene families, we applied for the detection of orthologs in this study orthoMCL, a sequence-based approach that allows to group closely related paralogs into one orthologous gene cluster. For a total of 49 out of 170 Arabidopsis genes we could identify conserved copy numbers between the dicot model and the grass annotations whereas approximately one third (34.7%, 59 genes) of the selected Arabidopsis genes lack an assignment to any of the grass genome annotations. The remaining 62 Arabidopsis genes represent groups that are considerably biased in their copy numbers between Arabidopsis and all or most of the three grass genomes.
Journal of plant physiology 01/2011; 168(1):3-8. · 2.50 Impact Factor
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ABSTRACT: Bacterial lipopolysaccharides (LPS) are triggers of defence responses in plants, and induce local as well as systemic acquired resistance. Arabidopsis thaliana plants pretreated with LPS show an increased resistance to the virulent bacterial plant pathogen Pseudomonas syringae pv. tomato DC3000. To investigate the mobilization and transport of LPS in Arabidopsis leaves, fluorescently labelled LPS (Alexa Fluor® 488 conjugate) from Salmonella minnesota was used. Leaves were pressure infiltrated with fluorescein-labelled LPS and fluorescence microscopy was used to follow the movement and localization of LPS as a function of time. The observation of leaves 1 h after supplementation with fluorescein-labelled LPS revealed a fluorescent signal in the intercellular space. Capillary zone electrophoresis was used for the detection and analysis of the labelled LPS in directly treated leaves and systemic leaves. In addition, gel electrophoresis was used to confirm LPS mobilization. The results indicated that LPS mobilization/translocation occurs through the xylem from local, treated leaves to systemic, untreated leaves. Consequently, care should be taken when ascribing the observed biochemical responses and induced resistance from LPS perception as being uniquely local or systemic, as these responses might overlap because of the mobility of LPS in the plant vascular system.
Molecular Plant Pathology 11/2010; 11(6):747-55. · 3.90 Impact Factor
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ABSTRACT: The role of reactive oxygen and nitrogen species in local and systemic defense reactions is well documented. NPR1 and TGA1 are key redox-controlled regulators of systemic acquired resistance in plants. NPR1 monomers interact with the reduced form of TGA1, which targets the activation sequence-1 (as-1) element of the promoter region of defense proteins. Here, we report the effect of the physiological nitric oxide donor S-nitrosoglutathione on the NPR1/TGA1 regulation system in Arabidopsis thaliana. Using the biotin switch method, we demonstrate that both NPR1 and TGA1 are S-nitrosylated after treatment with S-nitrosoglutathione. Mass spectrometry analyses revealed that the Cys residues 260 and 266 of TGA1 are S-nitrosylated and S-glutathionylated even at GSNO concentrations in the low micromolar range. Furthermore, we showed that S-nitrosoglutathione protects TGA1 from oxygen-mediated modifications and enhances the DNA binding activity of TGA1 to the as-1 element in the presence of NPR1. In addition, we observed that the translocation of NPR1 into the nucleus is promoted by nitric oxide. Taken together, our results suggest that nitric oxide is a redox regulator of the NPR1/TGA1 system and that they underline the importance of nitric oxide in the plant defense response.
The Plant Cell 08/2010; 22(8):2894-907. · 8.99 Impact Factor
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ABSTRACT: Over the past 20 years, nitric oxide (NO) research has generated a lot of interest in various aspects of plant biology. It is now clear that NO plays a role in a wide range of physiological processes in plants. However, in spite of the significant progress that has been made in understanding NO biosynthesis and signaling in planta, several crucial questions remain unanswered. Here we highlight several challenges in NO plant research by summarizing the latest knowledge of NO synthesis and by focusing on the potential NO source(s) and players involved. Our goal is also to provide an overview of how our understanding of NO signaling has been enhanced by the identification of array of genes and proteins regulated by NO.
Physiologia Plantarum 10/2009; 138(4):372-83. · 3.11 Impact Factor
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ABSTRACT: During the last two decades nitric oxide (NO) has emerged as a new chemical messenger in plant biology, which is involved in many different physiological processes, such as plant defense, transpiration and gas exchange, seed germination, and root development. Protein S-nitrosylation, the post-translational modification of thiol residues, has been suggested to be the most important mechanism for transduction of the bioactivity of NO. The characterization of protein S-nitrosylation as well as the physiological relevance of this type of modification is essential information, which is necessary to understand the function of NO in plants. In this review we focus on the formation of nitrosothiols and describe the chemistry of NO and thiol groups. Furthermore, different methods for detection of S-nitrosothiols are highlighted and the function of S-nitrosylation in plants is discussed.
Journal of proteomics 08/2009; 73(1):1-9. · 5.07 Impact Factor
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ABSTRACT: Nitric oxide (NO) plays a pivotal role in cellular signaling in many different organisms as the result of the modification of protein activities/functions by protein S-nitrosylation. This NO-dependent posttranslational modification is based on the attachment of NO to the sulfur moiety of cysteine residues. However, the instability of S-nitrosothiols makes it difficult to analyze this type of protein modification in vitro as well as in vivo. Jeffrey and colleagues developed a method--named the biotin switch method--that allows the detection and purification of S-nitrosylated proteins. The principle behind this technology is the substitution of the NO group by a biotin linker in a three-step procedure. First, the all free thiol groups are blocked with a thiol-reactive agent, followed by selective reduction of the S-nitrosylated cysteine residues using ascorbate. In the final step, the reduced thiol groups are labeled with a biotin linker, so that the previously S-nitrosylated cysteine residues are finally biotinylated. Afterwards, the biotinylated proteins can be detected with anti-biotin antibodies or can be purified by affinity chromatography on neutravidin agarose. In this chapter, we give a detailed description of the biotin switch method, which can be used for proteomics approach to identify candidates for protein S-nitrosylation as well as to analyse S-nitrosylation of selected proteins.
Methods in molecular biology (Clifton, N.J.) 02/2009; 476:210-22.
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ABSTRACT: The bacterial quorum sensing signals N-acyl-L-homoserine lactones (AHL) enable bacterial cells to regulate gene expression depending on population density, which eventually leads to invasion of hosts. Only little is known about the molecular ways of plants reacting to these bacterial signals. Recently, we showed that the contact of Arabidopsis thaliana roots with N-hexanoyl-DL-homoserine-lactone (HHL) resulted in distinct transcriptional changes in roots and shoots, respectively. In addition, we provided evidence that Arabidopsis takes up bacterial AHLs, which are obviously transported throughout the plant. In sum, the bacterial quorum sensing signal AHL seems to influence plant growth, and may contribute to reprogram plants encountering bacterial pathogens or rhizosphere bacteria. However, as pointed out here, the response of plants to bacterial AHLs may depend on plant species and chemical structure of AHLs.
Plant signaling & behavior 02/2009; 4(1):50-1.
