The Function of the Lipoxygenase ZmLOX10 in Maize Interactions with Insects and Pathogens

Christensen, Shawn A.

2009 December 1900

Lipoxygenase (LOX)-derived oxylipins are known to play critical roles in defense against herbivores and pathogens. The objective of this study was to determine the biochemical, molecular and physiological roles of a specific maize lipoxygenase gene, ZmLOX10, with special emphasis on LOX10-derived oxylipins in plant-insect and plant-pathogen interactions. To achieve this goal, independent mutant alleles were generated and genetically advanced to create near-isogenic mutant and wild-type lines suitable for functional analysis. Here we provide genetic evidence that LOX10 is the sole LOX isoform in maize required for the biosynthesis of green leafy volatiles (GLV) in leaves and show that LOX10- mediated GLVs play a significant role in direct and indirect defense responses to insects through their regulation of jasmonic acid and volatile organic compound production. Contrary to the defensive role of LOX10 in plant-insect interactions, tests for susceptibility to fungal pathogens suggest that LOX10-mediated GLVs may contribute to the development of disease symptoms to the economically important maize pathogens, Aspergillus flavus and Colletotrichum graminicola. Specifically, LOX10-derived GLVs may facilitate aflatoxin accumulation in response to A. flavus infection and may play a positive role in anthracnose leaf blight and stalk rot caused by C. graminicola. Collectively, our results suggest that metabolites derived from GLV-regulated pathways have a significant impact on molecular plant-herbivore and plant-pathogen interactions.

Jasmonates as a new class of signaling molecules in Bradyrhizobium-soybean symbiosis

Mabood, Fazli

January 2005

Jasmonic acid (JA) and its methyl ester, methyl jasmonate (MeJA), collectively termed as jasmonates, are naturally occurring in plants and are important signal molecules involved in induced disease resistance and stress responses of plants. Besides their role in-planta, they are also rhizosecreted by root cells. Germinating soybean seeds exude large quantities of jasmonic acid; however there is no knowledge regarding how jasmonates influence cells of the soybean symbiont, Bradyrhizobium japonicum, in the rhizosphere. We studied the role of jasmonates in the soybean-Bradyrhizobium symbiosis. Bradyrhizobium japonicum cultures were induced with jasmonates and the resulting Nod factors were isolated and purified. Our results showed that JA and MeJA strongly induced the production of Nod factors by the tested B. japonicum strains. When added together, genistein and jasmonates resulted in greater LCO production than either one alone. Jasmonic acid is produced from linoleic and linolenic acids via the octadecanoid pathway; we studied the effect of these two fatty acids on B. japonicum nod gene induction. Interestingly both linoleic and linolenic acids induced the nod genes and caused LCO production by B. japonicum cultures. Since jasmonates induced the nod genes and also caused LCO production in B. japonicum, I conducted experiments in the greenhouse and field to determine whether incubation of B. japonicum with JA or MeJA prior to inoculation increases soybean nodulation variables and grain yield. Both genistein and McJA increased nodule number and nodule dry weight per plant. Due to enhanced nitrogen fixation, attributed to increased nodule number and weight, soybean dry matter accumulation and grain yield were increased. These results document the discovery of jasmonates and their precursors as new signal molecules in the Bradyrhizobium - soybean nitrogen fixing symbiosis.

Jasmonic acid

Soybean -- Roots.

Root-tubercles.

Rhizobium japonicum.

Mycorrhizas.

Plant cellular signal transduction.

Diferenciação de laticíferos articulados em plantas de Tabernaemontana catharinensis (Apocynaceae)

Canaveze, Yve.

January 2016

Orientador: Silvia Rodrigues Machado / Resumo: Neste estudo buscamos avaliar diferentes aspectos da diferenciação de laticíferos. O crescimento intrusivo (capacidade de crescer penetrando a lamela média de células adjacentes) e a ação indutora dos laticíferos (capacidade de induzir uma célula vizinha a adquirir características de laticíferos) são mecanismos de crescimento interessantes que podem ocorrer nos laticíferos, mas que são mal compreendidos. O etileno e o ácido jasmônico são hormônios vegetais liberados durante a herbivoria e podem afetar a diferenciação de estruturas secretoras relacionadas à defesa, como laticíferos e ductos resiníferos. Utilizando métodos convencionais em microscopia eletrônica de transmissão, para caracterização da ultraestrutura celular, e imunocitoquímicos, para a detecção de componentes de parede celular, exploramos o desenvolvimento de laticíferos articulados anastomosados com crescimento intrusivo e a ação indutora dos laticíferos no embrião maduro e na planta de Tabernaemontana catharinensis A.DC. (Apocynaceae). Além disso, pulverizamos soluções de etileno 2%, ácido jasmônico 0,1% ou água deionizada em plantas (n = 33) de T. catharinensis cultivadas em condições controladas e avaliamos a influência destes reguladores vegetais sobre a diferenciação dos laticíferos nos tecidos primários e floema secundário. Ultraestruturalmente, verificamos que o processo de incorporação de células ao sistema laticífero é distinto no embrião e na planta. Entretanto, em ambos os casos, o protoplasto da cél... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: In this study, we evaluated different aspects of the laticifer differentiation. The intrusive growth (the capacity of grow penetrating the middle lamella that cements adjacent cells) and the inducing action of laticifers (the capacity of induced an adjacent cell to acquirer laticifer features) are exciting growth mechanisms that may occur in laticifers, but they are poorly understood. Ethylene and jasmonic acid are plant hormones released during the herbivory and may affect the differentiation of secretory structures related with plant defense, as laticifers and resin ducts. Using transmission electron microcopy conventional methods (for characterization of the cell ultrastructure), and immunocytochemistry (for detection of the cell wall compounds), we explored the development of the articulated anastomosing laticifers with intrusive growth and the induction action of laticifer in the mature embryo and plant of Tabernaemontana catharinensis A.DC. (Apocynaceae). Additionally, we sprayed solutions of the 2% ethephon, 0.1% jasmonic acid and deonized water in plants of T. catharinensis (n = 33) growing under controlled conditions and evaluated the influence of these plant regulators on laticifer differentiation in the primary tissues and secondary phloem. In the ultrastructure, we verified that the process of cell incorporation within the laticifer system is distinct in the embryo and plant. However, in both the cases the protoplast of the incorporated cells acquires similar feat... (Complete abstract click electronic access below) / Doutor

Ácido jasmônico

Apocynaceae

Imunocitoquimica.

Etileno.

Sistema laticífero

Ultraestrutura

Apocynaceae

Ethylene

Immunocitochemistry

Jasmonic acid

Laticifer system

Ultrastructure

Rust and drought effects on gene expression and phytohormone concentration in big bluestem

Frank, Erin

January 1900

Master of Science / Department of Plant Pathology / Karen A. Garrett / While plants are typically exposed to multiple stressors in the field, studies of genome-wide gene expression and phytohormone responses in wild plant species exposed to multiple stressors are rare. Our objectives were to determine the effects of drought and rust stress on gene expression in Andropogon gerardii, the dominant grass in tallgrass prairie, and associated levels of phytohormone production. In a factorial design, plants experiencing drought or non-drought conditions were either inoculated with the rust pathogen Puccinia andropogonis or not inoculated. Gene expression was evaluated with maize microarrays. Drought-stressed plants significantly decreased expression of genes associated with photosynthesis and the hypersensitive response, while expression of genes associated with chaperones and heat-shock proteins increased. No significant differences in gene expression in response to the rust treatment were detected using a mixed model analysis of variance and false discovery rate protection, probably because of the low infection rate. Phytohormone production increased when both stresses were present. The rust treatment significantly increased benzoic acid (BA) production in the presence of drought, while the drought treatment alone significantly increased salicylic acid (SA) production. Leaf tips usually had higher levels of all phytohormones in all treatments and the leaf section evaluated had a larger effect on phytohormone level than did the treatments applied.

Andropogon gerardii

Puccinia andropogonis

Gene expression

Salicylic acid

Jasmonic acid

Drought

Agriculture, Plant Pathology (0480)

Jasmonates as a new class of signaling molecules in Bradyrhizobium-soybean symbiosis

Mabood, Fazli

January 2005

No description available.

Soybean -- Roots.

Mycorrhizas.

Jasmonic acid

Plant cellular signal transduction.

Root-tubercles.

Rhizobium japonicum.

Desenvolvimento de micorriza arbuscular em tomateiro (Lycopersicon esculentum cv micro-tom) insensível ao ácido jasmônico (jai1-1) e superprodutor de etileno (epinastic) / Development of arbuscular mycorrhizal in tomato (Lycopersicon esculentum cv Micro-Tom) insensitive to jasmonic acid (jai1-1) and ethylene over producer (epinastic)

Corrêa, Joze Aparecida Marciano

04 February 2011

Micorrizas arbusculares (MAs) são simbioses mutualistas formadas entre fungos do solo e a maioria das plantas terrestres, principalmente angiospermas. Esta simbiose pode trazer uma série de benefícios para o hospedeiro vegetal, como uma maior absorção de fosfato, um aumento na tolerância ao estresse abiótico e biótico, e resistência a agentes patogênicos, resultando numa melhor adaptação ao meio. É possível que hormônios vegetais estejam envolvidos em eventos de sinalização entre fungos micorrízicos arbusculares e plantas hospedeiras, durante os processos de colonização das raízes e de desenvolvimento dos arbúsculos. Recentes estudos têm demonstrado que durante o estabelecimento da simbiose, ocorre uma reprogramação da expressão de um grande número de genes, e que essas alterações na expressão gênica podem estar associadas a alterações dos níveis de hormônios nas plantas. O objetivo deste trabalho foi avaliar o desenvolvimento de MAs em mutantes de tomateiro cv Micro-Tom (MT) insensível ao ácido jasmônico (jai1-1), superprodutor de etileno (epi) e duplo mutante epijai1 inoculados com Glomus clarum em condições de baixa concentração de fósforo no substrato, e a expressão de genes relacionadas à biossíntese do ácido jasmônico (AJ) (OPR3 e AOC) e do etileno (ET) (ACO4 e ACS2). O mutante jai1-1 não apresentou colonização intrarradicular e o acúmulo de transcritos tanto para a via de biossíntese do AJ como do ET foi relativamente menor do que o controle MT o que sugere a importância do AJ para o desenvolvimento da simbiose.O mutante epi e o duplo mutante apresentaram colonização intraradicular reduzida em relação ao controle MT. O acúmulo de transcritos dos genes da via do ET (ACO4 e ACS2) e do AJ (OPR3 e AOC) foi maior no mutante epi. A insensibilidade ao AJ presente no duplo mutante não impediu o acúmulo de transcritos para as vias de biossíntese do AJ e do ET, o que sugere uma relação sinérgica entre os hormônios vegetais no estabelecimento da simbiose. / Arbuscular mycorrhizal (AM) symbioses are formed between mutualistic soil fungi and most land plants, particularly angiosperms. This symbiosis can bring many benefits to the host plant, such as increased absorption of phosphate, an increase in tolerance to abiotic and biotic stress, and resistance to pathogens, resulting in better adaptation to the environment. Its possible that plant hormones are involved in signaling events between mycorrhizal fungi and host plants during the processes of colonization of roots and development of arbuscules. Recent studies have shown that during the establishment of symbiosis, there is a reprogramming of the expression of a large number of genes, and that these changes in gene expression may be associated with altered levels of hormones in plants. The aim of this study was to evaluate the development of MA in mutants of tomato cv Micro-Tom (MT) insensitive to jasmonic acid (jai1-1), ethylene overproducer (epi) and double mutant epijai1 inoculated with Glomus clarum under low phosphorus concentration in substrate, and the expression of genes related to biosynthesis of jasmonic acid (JA) (and OPR3 AOC) and ethylene (ET) (ACO4 and ACS2). Jai1-1 mutant showed no intraradical colonization and the accumulation of transcripts for both the biosynthesis of JA and ET was less than the control MT suggesting the importance of JA for the development of epi and double mutant symbiosis. The mutant epi and the double mutant showed reduced intraradical colonization when compared to the control MT. The transcript accumulation of the ET (ACO4 and ACS2) and JA (OPR3 and AOC) genes was higher in the mutant epi. The insensitivity to the JA in this double mutant did not prevent the accumulation of transcripts for the biosynthetic pathways of JA and ET, suggesting a synergistic relationship between plant hormones for the establishment of symbiosis.

Ethylene

Fungos micorrízicos

Hormônios vegetais

Jasmonic acid

Micorriza

Micro-Tom

Mutação genética

Mutant

Mycorrhizal fungi

Plant hormones.

Reguladores de crescimento

Tomate.

Desenvolvimento de micorriza arbuscular em tomateiro (Lycopersicon esculentum cv micro-tom) insensível ao ácido jasmônico (jai1-1) e superprodutor de etileno (epinastic) / Development of arbuscular mycorrhizal in tomato (Lycopersicon esculentum cv Micro-Tom) insensitive to jasmonic acid (jai1-1) and ethylene over producer (epinastic)

Joze Aparecida Marciano Corrêa

04 February 2011

Micorrizas arbusculares (MAs) são simbioses mutualistas formadas entre fungos do solo e a maioria das plantas terrestres, principalmente angiospermas. Esta simbiose pode trazer uma série de benefícios para o hospedeiro vegetal, como uma maior absorção de fosfato, um aumento na tolerância ao estresse abiótico e biótico, e resistência a agentes patogênicos, resultando numa melhor adaptação ao meio. É possível que hormônios vegetais estejam envolvidos em eventos de sinalização entre fungos micorrízicos arbusculares e plantas hospedeiras, durante os processos de colonização das raízes e de desenvolvimento dos arbúsculos. Recentes estudos têm demonstrado que durante o estabelecimento da simbiose, ocorre uma reprogramação da expressão de um grande número de genes, e que essas alterações na expressão gênica podem estar associadas a alterações dos níveis de hormônios nas plantas. O objetivo deste trabalho foi avaliar o desenvolvimento de MAs em mutantes de tomateiro cv Micro-Tom (MT) insensível ao ácido jasmônico (jai1-1), superprodutor de etileno (epi) e duplo mutante epijai1 inoculados com Glomus clarum em condições de baixa concentração de fósforo no substrato, e a expressão de genes relacionadas à biossíntese do ácido jasmônico (AJ) (OPR3 e AOC) e do etileno (ET) (ACO4 e ACS2). O mutante jai1-1 não apresentou colonização intrarradicular e o acúmulo de transcritos tanto para a via de biossíntese do AJ como do ET foi relativamente menor do que o controle MT o que sugere a importância do AJ para o desenvolvimento da simbiose.O mutante epi e o duplo mutante apresentaram colonização intraradicular reduzida em relação ao controle MT. O acúmulo de transcritos dos genes da via do ET (ACO4 e ACS2) e do AJ (OPR3 e AOC) foi maior no mutante epi. A insensibilidade ao AJ presente no duplo mutante não impediu o acúmulo de transcritos para as vias de biossíntese do AJ e do ET, o que sugere uma relação sinérgica entre os hormônios vegetais no estabelecimento da simbiose. / Arbuscular mycorrhizal (AM) symbioses are formed between mutualistic soil fungi and most land plants, particularly angiosperms. This symbiosis can bring many benefits to the host plant, such as increased absorption of phosphate, an increase in tolerance to abiotic and biotic stress, and resistance to pathogens, resulting in better adaptation to the environment. Its possible that plant hormones are involved in signaling events between mycorrhizal fungi and host plants during the processes of colonization of roots and development of arbuscules. Recent studies have shown that during the establishment of symbiosis, there is a reprogramming of the expression of a large number of genes, and that these changes in gene expression may be associated with altered levels of hormones in plants. The aim of this study was to evaluate the development of MA in mutants of tomato cv Micro-Tom (MT) insensitive to jasmonic acid (jai1-1), ethylene overproducer (epi) and double mutant epijai1 inoculated with Glomus clarum under low phosphorus concentration in substrate, and the expression of genes related to biosynthesis of jasmonic acid (JA) (and OPR3 AOC) and ethylene (ET) (ACO4 and ACS2). Jai1-1 mutant showed no intraradical colonization and the accumulation of transcripts for both the biosynthesis of JA and ET was less than the control MT suggesting the importance of JA for the development of epi and double mutant symbiosis. The mutant epi and the double mutant showed reduced intraradical colonization when compared to the control MT. The transcript accumulation of the ET (ACO4 and ACS2) and JA (OPR3 and AOC) genes was higher in the mutant epi. The insensitivity to the JA in this double mutant did not prevent the accumulation of transcripts for the biosynthetic pathways of JA and ET, suggesting a synergistic relationship between plant hormones for the establishment of symbiosis.

Fungos micorrízicos

Hormônios vegetais

Micorriza

Mutação genética

Reguladores de crescimento

Tomate.

Ethylene

Jasmonic acid

Micro-Tom

Mutant

Mycorrhizal fungi

Plant hormones.

Genetics of Resistance to Ascochyta Blight in Lentil

2014 October 1900

The aim of this study was to gain insight into the nature of resistance genes and mechanisms of resistance present in different ascochyta blight (AB) resistant genotypes of lentil to efficiently select non-allelic AB resistance genes mediating different mechanisms of resistance for gene pyramiding. Recombinant inbred lines (RILs) from all possible crosses among AB resistant Lens culinaris genotypes CDC Robin, 964a-46, ILL 7537 and ILL 1704 were subjected to allelism tests. Efforts were also made to understand the genetics of resistance in the L. ervoides accession L-01-827A. LR-18, a RIL population from the cross CDC Robin × 964a-46 was subjected to quantitative trait loci (QTL) mapping using a comprehensive genetic linkage map previously developed from polymorphic SNPs, SSRs and phenotypic markers. Results of allelism tests suggested that genes conditioning resistance to ascochyta blight in all lentil genotypes were non-allelic. Two complementary recessive resistance genes in L-01-827A were detected. QTL analysis indicated that CDC Robin and 964a-46 were different at two AB resistance QTLs. Histological tests suggested that cell death inhibition in CDC Robin, and reduced colonization of epidermal cells in 964a-46 might be the mechanisms of resistance in these genotypes. Comparing the expression of key genes in the salicylic acid (SA) and jasmonic acid (JA) signaling pathways of CDC Robin and 964a-46 suggested that the SA pathway was strongly triggered in 964a-46. However, the JA pathway was triggered in both, but at a lower expression level in 964a-46 than in CDC Robin. RNA-seq analysis revealed a number of candidate defense genes differentially expressed among genotypes with hypothetical actions in different layers of the plant defense machinery. The expression levels of the six candidate defense genes measured by quantitative real-time PCR analysis was correlated with those of RNA-seq. In conclusion, 964a-46 and CDC Robin mediated resistance to ascochyta blight through different resistant mechanisms, making them ideal candidates for resistance gene pyramiding. Gene pyramiding can be accelerated using closely linked markers to CDC Robin and 964a-46 resistance genes identified through QTL analysis.

Role of VILAMBIT Genes Controlling Flowering Time and Jasmonic Acid Signaling in Arabidopsis

Kumar, Sushil

January 2015

The transition to flowering is an important decision for plants since seed-setting and the survival of the progeny depend on the environmental conditions prevalent during this transition. Therefore, to ensure maximum reproductive success, plants have evolved several regulatory mechanisms to enable them flower at the most appropriate time. Environmental parameters such as light, temperature and nutrient availability as well as endogenous factors such as age and hormonal status of the plant profoundly affect floral transition (Boss et al., 2004; Srikanth and Schmid, 2011). Studies in Arabidopsis and other model plant species have identified several distinct genetic pathways that integrate the information from the endogenous and environmental cues to regulate flowering (Boss et al., 2004; Srikanth and Schmid, 2011). Many components and gene regulatory networks identified in Arabidopsis are conserved in other commercially important species including rice, maize, sorghum, potato and tomato. Therefore, it is important to understand the basic mechanisms that modulate the flowering response in model plants such as Arabidopsis thaliana, the knowledge from which can be used to develop better adapted and high-yielding varieties of crop plants in the wake of challenges like global warming and increasing food demand. In the present study, we have studied the function of VLB1 and VLB2, genes that code for plant-specific Zn-finger transcription factors. Previous studies from our laboratory (Pratibha Choudhary, Ph.D thesis, 2011) and by other research groups have reported that VLBs redundantly promote flowering in A. thaliana (Yasui et al., 2012; Celesnik et al., 2013). However, the underlying mechanism of this regulation is not well understood. Our data suggests that VLBs redundantly promote the transition to flowering specifically in the photoperiod pathway, the major floral induction pathway in A. thaliana. CO, which is the 93 key regulatory gene in this pathway, is regulated by various factors at the transcriptional as well as post-transcriptional level (Suarez-Lopez et al., 2001; Yanovsky and Kay, 2002; Srikanth and Schmid, 2011). Using genetics, we show that VLBs and CO function together to promote flowering in the photoperiod pathway. Further, our BiFC results reveal that VLBs and CO interact physically. Nevertheless, the physical interaction between VLBs and CO needs to be further validated by in vitro and in vivo by co-immunoprecipitation experiments. We hypothesize that the interaction between VLBs and CO is important to regulate FT expression and hence, flowering. However, whether VLBs interact with CO and promote the CO-stability, or facilitates its recruitment to the FT promoter region, still needs to be determined. Apart from its role in flowering, VLBs have been recently shown to regulate biotic and abiotic responses in Arabidopsis (Nakai et al., 2013a; Nakai et al., 2013b). Also, even though it has been demonstrated that VLBs code for transcription factors, no direct targets of VLBs have been reported till date. We performed a whole genome trancriptome-profiling and found that several important classes of genes including WRKY, RLPs, NBS-LRR and JAZs were affected suggesting that, in addition to their role in floral transition, VLBs have important functions in other plant processes as well. In fact, vlb1vlb2 mutant showed an early senescence phenotype and many senescence-associated genes (SAGs) were up-regulated in our microarray experiments, which was further validated by qRT-PCR analysis. By comparing the differentially-regulated genes and PatMatch analysis, we have identified 82 putative direct targets of VLBs in the Arabidopsis genome which need to be validated by chromatin immunoprecipitation (ChIP) assay and functional studies. 94 Results of global transcriptome analysis revealed that the expression of several JA-signaling and response genes was significantly down-regulated. JA is an important phytohormone involved in plant defense and other developmental processes such as stamen development, root growth and senescence (Wasternack, 2007). Results from the JA-induced expression analysis and root inhibition assay confirmed that JA-signaling and response are indeed compromised in the vlb1vlb2 double mutant. Moreover, in vitro DNA-binding assay showed that MYC2, the key transcriptional regulator of JA-responsive gene expression, is a direct transcriptional target of VLB2. A recent study reported that loss-of-function of VLB genes impairs plant defense while their overexpression confers biotic stress tolerance in Arabidopsis (Nakai et al., 2013a; Nakai et al., 2013b). Compromised JA signaling in the vlb1vlb2 double mutant might partly explain this reduced tolerance to pathogens. However, whether VLBs are associated with the MYC2 promoter in planta needs to be tested by performing ChIP and other in vivo assays. In conclusion, our study shows that VLBs have important regulatory roles in diverse processes including control of flowering time, senescence and JA signaling in Arabidopsis. The validation and functional characterization of the direct targets of VLBs will shed more light on the role of VLBs. Since VLBs are conserved in vascular plants, it will be interesting to see if the function of VLBs is also conserved across species and what might be its ancestral function in evolution.

Arabidopsis thaliana - Plant Protein

Jasmonic Acid Signaling

CO MRNA

ViLAMBIT Genes

Arabidopsis

VLB1

VLB2

JA-signaling

VILAMBITs

Microbiology and Cell Biology

Characterization of a MAPK module involved in Arabidopsis response to wounding / Caractérisation d'un module MAPK impliqué dans la réponse à la blessure chez Arabidopsis thaliana

Sözen, Cécile

29 November 2017

Les plantes ne pouvant pas se déplacer sont continuellement soumises aux stress environnementaux. La blessure, l’un des stress les plus fréquents auxquels la plante est soumise, peut causer d’important dégâts et faciliter l’entrée de pathogène dans les tissus de la plante. Pour répondre efficacement à la blessure, la plante a développé des mécanismes lui permettant de guérir ses tissus endommagés et d’empêcher l’infection pathogène. Les stress environnementaux sont perçus grâce à la présence de récepteurs spécifiques activant des voies de signalisation qui, à terme, conduisent à la mise en place de réponses de défense. Les modules de MAPK, composés de 3 kinases (MAP3K, MAP2K et MAPK) activées en cascades, représentent d’importantes voies de signalisation impliquées en réponse à divers stress biotiques et abiotiques. Grâce aux approches de tests de phosphorylation in vitro très maîtrisées dans le groupe « Stress signaling », j’ai pu identifier un module MAPK impliquant la MAP2K MKK3 et les MAPKs du groupe C (MPK1, 2, 7 et 14) activé par la blessure. Les MAP3Ks du sous-clade III (MAP3K13 à 20) sont transcriptionnellement induites par divers stress ce qui semble être un mécanisme assez conservé. Certains membres du sous-clade III sont induits par la blessure et parmi eux la MAP3K14 semble avoir un rôle majeur en amont du module MKK3/MPK1-2-7-14. Enfin, j’ai pu montrer que l’acide jasmonique (JA), une phytohormone importante produite en réponse à la blessure, tient un rôle important en amont du module. Ce-dernier est également activé en réponse à l’insecte herbivore Spodoptera littoralis et au champignon nécrotrophe Botrytis cinerea. Dans le contexte de blessure par l’insecte herbivore, MKK3 semble réguler la production de deux phytohormones, le JA et l’Acide Salicylique (SA). / Plants are sessile organisms. They have to cope continuously with environmental stresses. Injury, one of the most frequent stress conditions that plants must face may cause harsh damages to the plant tissues and facilitate the entry of pathogens. Therefore, plants have evolved mechanisms to respond efficiently to wounding by healing damaged tissues and preventing further pathogen infection. Wounding is a complex stress which is perceived by specific receptors which activate signaling pathways leading to those responses. Mitogen-Activated Protein Kinases modules are composed of 3 kinases (MAP3K, MAP2K and MAPK) activated in cascade and represent important signaling pathways involved in response to various biotic and abiotic stresses as well as in developmental processes. During my Ph.D I identified a MAPK module activated 30 minutes after wounding and involving the MAP2K MKK3 acting upstream of C-group MAPKs MPK1-2-7-14. In the past, the laboratory has shown that this module is dependent on the transcriptional regulation of sub-clade III MAP3Ks (MAP3K13 to 20). Some were found induced by wounding and among them MAP3K14 seems to have an important role upstream MKK3/C-group MAPKs. Finally I was able to show that Jasmonic Acid (JA), a major phytohormone produced upon wounding and involved in the mediation of defense responses, was shown to have an important role upstream the MKK3/C-group MAPKs module. The module is also activated by the herbivore Spodoptera littoralis and the necrotrophic fungus Botrytis cinerea. Upon insect feeding, MKK3 negatively regulates JA and SA levels. My work helped to better understand stress signaling events occurring upon wounding.

Blessure

MAPK

Signalisation

Acide jasmonique (JA)

Acide salicylique (SA)

Wounding

MAPK

Stress signaling

Jasmonic acid (JA)

Salicylic acid (SA)