Project description:As sessile organism, plants evolved a highly complicated signaling system to cope with unfavorable and fluctuating environmental conditions. Rapid and transient Reactive Oxygen Species (ROS) burst is a common response to both biotic and abiotic stresses. Plants exposed with O3 could trigger extracellular similar ROS production through cell wall peroxidases and NPADPH oxidases, resulting in changes in the gene expression and cell death. Whereas ROS induced cell death is not simply due to its toxicity, rather due to interplay with several other signaling pathways, such as salicylic acid (SA), jasmonic acid (JA) and ethylene signaling pathways. Furthermore, the three hormones have both synergistic and antagonistic interactions, where the suppression of JA signaling by SA is the mostly studied. In addition, ethylene promotes cell death while JA has a protective role upon O3 exposure. The role of SA is more complicated; depending on the genetic background it can have either cell death promoting or protecting roles. Hence, a clean system to deliver apoplastic ROS is required to study the role of ROS apart from con-current activation of other signaling pathways. Arabidopsis thaliana offer a convenient system to study apoplastic ROS signaling due to the availability of hormone signaling or biosynthesis mutants including the JA receptor mutant coi1-16 (CORONATINE INSENSITIVE1), the essential ethylene signaling mutant ein2 (ETHYLENE INSENSITIVE2), the SA biosynthesis mutant sid2 (SALICYLIC ACID INDUCTION DEFICIENT2 also known as ISOCHORISMATE SYNTHASE1), and essential regulators in SA/JA/ethylene-induced defense response triple mutant tga2 tga5 tga6 (Clade II TGA transcription factors). Here we used a combination of transcriptome analysis, cell death assays and mutant analysis to systematically quantified the contribution of hormone signaling in relation to apoplastic ROS signaling, identified transcription factors (TFs) involved in ROS regulation and dissected the components involved in defense hormones associated cell death. Transcriptome profiling of ozone response using two arabidopsis triple mutants coi1-16 ein2 sid2 and tga2 tga5 tga6 related to Jasmonic acid, salicylic acid and ethylene signaling to identify hormone-independant apoplastic ROS signaling

Project description:As sessile organism, plants evolved a highly complicated signaling system to cope with unfavorable and fluctuating environmental conditions. Rapid and transient Reactive Oxygen Species (ROS) burst is a common response to both biotic and abiotic stresses. Plants exposed with O3 could trigger extracellular similar ROS production through cell wall peroxidases and NPADPH oxidases, resulting in changes in the gene expression and cell death. Whereas ROS induced cell death is not simply due to its toxicity, rather due to interplay with several other signaling pathways, such as salicylic acid (SA), jasmonic acid (JA) and ethylene signaling pathways. Furthermore, the three hormones have both synergistic and antagonistic interactions, where the suppression of JA signaling by SA is the mostly studied. In addition, ethylene promotes cell death while JA has a protective role upon O3 exposure. The role of SA is more complicated; depending on the genetic background it can have either cell death promoting or protecting roles. Hence, a clean system to deliver apoplastic ROS is required to study the role of ROS apart from con-current activation of other signaling pathways. Arabidopsis thaliana offer a convenient system to study apoplastic ROS signaling due to the availability of hormone signaling or biosynthesis mutants including the JA receptor mutant coi1-16 (CORONATINE INSENSITIVE1), the essential ethylene signaling mutant ein2 (ETHYLENE INSENSITIVE2), the SA biosynthesis mutant sid2 (SALICYLIC ACID INDUCTION DEFICIENT2 also known as ISOCHORISMATE SYNTHASE1), and essential regulators in SA/JA/ethylene-induced defense response triple mutant tga2 tga5 tga6 (Clade II TGA transcription factors). Here we used a combination of transcriptome analysis, cell death assays and mutant analysis to systematically quantified the contribution of hormone signaling in relation to apoplastic ROS signaling, identified transcription factors (TFs) involved in ROS regulation and dissected the components involved in defense hormones associated cell death.

Project description:Many genes involve in pathogenicity and virulence are induced only in plant or in the presence of host components. Plant apoplast is the primary site of infection for P. syringae, which obtain nutrients directly from apoplastic fluid of host plants. In this work we investigated the effect of apoplastic fluid on the transcriptomic profile of the bacterium, when grown at low temperature in minimal medium with or without apoplastic fluid extracted from healthy bean leaves.

Project description:The extracellular space within plant leaves is called the apoplast, and functions as a key battlefield between plants and pathogens. Previously, we have shown that apoplastic wash fluid purified from Arabidopsis leaves contains small RNAs (sRNAs). To investigate whether these RNAs are encapsulated inside extracellular vesicles (EVs), we treated EVs isolated from Arabidopsis leaves with the protease trypsin and RNase A, which should degrade RNAs located outside of EVs, but not those located inside. These analyses revealed that apoplastic RNAs are mostly located outside of EVs and are associated with proteins. Additional analyses of these extracellular RNAs (exRNAs) revealed that they are made up both sRNAs and long non-coding RNAs (lncRNAs), including circular RNAs (circRNAs). We also found that exRNAs are highly enriched in the post-transcriptional modification N6-methyladenine (m6A). Consistent with this, we identified a putative m6A-binding protein in apoplastic wash fluids, GLYCINE-RICH RNA BINDING PROTEIN 7 (GRP7), as wells as the small RNA-binding protein ARGONAUTE2 (AGO2). These two proteins co-immunoprecipitated with each other, and with lncRNAs, including circRNAs. Mutation of GRP7 or AGO2 caused changes in both the sRNA and lncRNA content of apoplastic wash fluid, suggesting that these proteins contribute to the secretion and/or stabilization of exRNAs.

Project description:The extracellular space within plant leaves is called the apoplast, and functions as a key battlefield between plants and pathogens. Previously, we have shown that apoplastic wash fluid purified from Arabidopsis leaves contains small RNAs (sRNAs). To investigate whether these RNAs are encapsulated inside extracellular vesicles (EVs), we treated EVs isolated from Arabidopsis leaves with the protease trypsin and RNase A, which should degrade RNAs located outside of EVs, but not those located inside. These analyses revealed that apoplastic RNAs are mostly located outside of EVs and are associated with proteins. Additional analyses of these extracellular RNAs (exRNAs) revealed that they are made up both sRNAs and long non-coding RNAs (lncRNAs), including circular RNAs (circRNAs). We also found that exRNAs are highly enriched in the post-transcriptional modification N6-methyladenine (m6A). Consistent with this, we identified a putative m6A-binding protein in apoplastic wash fluids, GLYCINE-RICH RNA BINDING PROTEIN 7 (GRP7), as wells as the small RNA-binding protein ARGONAUTE2 (AGO2). These two proteins co-immunoprecipitated with each other, and with lncRNAs, including circRNAs. Mutation of GRP7 or AGO2 caused changes in both the sRNA and lncRNA content of apoplastic wash fluid, suggesting that these proteins contribute to the secretion and/or stabilization of exRNAs.

Project description:In order to dissect the roles of sequence-specific transcription factors WRKY25, WRKY33 and WRKY75 in apoplastic ROS signaling, a transcriptome profiling of ozone response was done using two arabidopsis mutants: a double mutant wrky25 wrky33 and a single mutant wrky75. The single mutant lines used for transcriptomic analyses were obtained from NASC: wrky25 (SAIL_529_B11) and wrky33 (SALK_006603) were crossed to generate double mutant wrky25 wrky33. T-DNA insertion mutant wrky75-25 (N121525) was obtained from NASC.

Project description:Background and aims The endophytic diazotrophic strain CBAmC of Nitrospirillum amazonense has been reported as a plant growth promoter of sugarcane variety RB867515 when grown under field conditions. The present work aimed to assess the influence of apoplast fluid from RB867515 on the transcriptomic and proteomic profiles of CBAmC cultured in vitro. Methods RNA-Seq in Ion Proton™ and ESI-LC-MS/MS peptide analysis were used to evaluate the transcriptomic and proteomic profiles, respectively, of CBAmC exposed for 2 h to the sugarcane apoplast fluid. Results The bacterial transcriptomic and proteomic profiles were well correlated. The overall response of CBAmC to the apoplast fluid included overexpression of defense systems against reactive oxygen species (ROS) and osmotic stress, RND efflux pumps for toxic compounds, Sec and Tat secretory systems, and assimilative metabolism of iron. In contrast, active transporters of organic compounds, chemotaxis system and flagellum structure were underexpressed. Conclusions The bacterial metabolic pathways / functions activated in response to the sugarcane apoplast fluid are most likely related to its adaptation to the peculiar characteristics of the fluid. The activation of some of those functions could be determinant for its adaptation to the sugarcane apoplastic niche, and perhaps be involved in the previously observed effect of promoting plant growth. SUBMITTER_CITATION: Terra, L.A., de Soares, C.P., Meneses, C.H.S.G. et al. Plant Soil (2019). Transcriptome and proteome profiles of the diazotroph Nitrospirillum amazonense strain CBAmC in response to the sugarcane apoplast fluid.

Project description:In order to dissect the roles of sequence-specific transcription factors WRKY25, WRKY33 and WRKY75 in apoplastic ROS signaling, a transcriptome profiling of ozone response was done using two arabidopsis mutants: a double mutant wrky25 wrky33 and a single mutant wrky75. The single mutant lines used for transcriptomic analyses were obtained from NASC: wrky25 (SAIL_529_B11) and wrky33 (SALK_006603) were crossed to generate double mutant wrky25 wrky33. T-DNA insertion mutant wrky75-25 (N121525) was obtained from NASC. Three biological replicates, five plants per replicate, treated with 350 ppb ozone for 2 hours, were used for RNA-seq analysis. For each genotype, also non-ozone-treated samples were collected. For the Col-0 control line, an additional fourth replicate with/without ozone was done.

Project description:Plant apoplast is the first hub of plant-pathogen communication. Indeed, during interaction, pathogen effectors are recognized by plant defensive proteins and cell receptors and several signal transduction pathways are activated. Within this first contact, a defence response is triggered by the plant involving several extra and intracellular proteins. In grapevine, little is known about the communication between cells and apoplast in the context of plant-pathogen interactions, also apoplast dynamics, particularly considering the role of apoplastic proteins in response to pathogens still remains a blackbox. In this study we focused on 6 hours after Plasmopara viticola inoculation to evaluated grapevine proteome modulation both in the apoplastic fluid (APF) and total leaf tissue. Plasmopara viticola secretome was also assessed enabling a deeper understanding of plant and pathogen communication. Our results showed that oomycete recognition, plant cell wall modifications, ROS signalling and disruption of oomycete structures are triggered in Regent after P. viticola inoculation. Also, our results highlight a strict relation between the apoplastic pathways modulated and the proteins identified in ‘Regent’ total leaf proteome. On the other hand, P. viticola proteins related to growth/morphogenesis and virulence mechanisms were the most predominant. This pioneer study highlights the early dynamics of extra and intracellular communication between grapevine and defence activation leading to the successful establishment of an incompatible interaction

Project description:The study of different cellular compartments also allows a broader conception of cell dynamics. Plant apoplast is the cellular compartment external to the plasma membrane including the cell wall. Despite our knowledge on apoplast involvement on several processes from cell growth to biotic and abiotic stress response, its dynamics is yet still poorly studied due to the need for adaptation of the extraction process according to the plant system and consequently, the difficulty to perform a comprehensive profiling of proteins, metabolites and lipids within a single experiment. Moreover, when looking at woody plants as grapevine, more challenges are raised leading to only few studies published so far focusing on apoplast characterization. Being grapevine one of the most important fruit crops worldwide, a wider characterization of this compartment may unveil the importance of grapevine’s secretome. Here, we describe an optimized vacuum-infiltration-centrifugation method for the simultaneous extraction of apoplastic proteins and metabolites from the grapevine leaf on a single experiment, compatible with high-throughput mass spectrometry analysis.