Transformação genética de tomate Micro-Tom e de laranja doce com os genes chitinase type III (PR-8) e constitutive disease resistance protein (CDR-1) de Citrus sinensis / Genetic transformation of Micro-Tom tomato and sweet orange with chitinase type III (PR-8) and constitutive disease resistance protein (CDR-1) genes from Citrus sinensis

Nathalia Felipe Ansante

04 December 2015

Atualmente, o HLB é considerado a principal doença que acomete as plantas cítricas. Diante desse fator, pesquisas por cultivares resistentes a esta doença são necessárias. A transformação genética via Agrobacterium, juntamente com o uso de plantas modelos, tem sido uma alternativa para verificação do funcionamento dos genes em resposta a patógenos, isto porque as plantas modelos possuem como característica ciclo de vida curto e alto poder de regeneração. Assim sendo, objetivou-se com o presente trabalho, a transformação genética via Agrobacterium tumefaciens, de tomate Micro-Tom (Solanum lycopersicum L.) e de laranja doce, com os genes que codificam as proteínas PR-8 e CDR-1, isolados a partir de Citrus simensis. Os cotilédones provenientes de sementes germinadas in vitro de tomate Micro-Tom foram utilizados como fonte de explante para os experimentos de transformação genética com os genes PR-8 e CDR-1. Esses explantes foram subcultivados até o aparecimento de brotos regenerantes e posteriormente plantas transgênicas, as quais foram aclimatizadas e levadas a casa-de-vegetação. A transgenia foi confirmada por PCR e o número de inserções do gene por Southern blot. As plantas foram cultivadas até a obtenção da geração T1. Simultaneamente, foram realizados experimentos de transformação genética em segmentos de epicótilo, provenientes de sementes de laranja ‘Hamlin’ germinadas in vitro, com o gene CDR-1, a fim de se obter plantas transgênicas e sua caracterização. Paralelamente, foi realizada a construção da curva padrão pela análise de qPCR para identificação de Pseudomonas syringae pv. tomato. Foram obtidas treze plantas transgênicas de tomate Micro-Tom com o gene PR-8 e três com o gene CDR-1. As eficiências de transformação foram em torno de 0,38 a 1,98%. Três plantas de tomate Micro-Tom transgênicas com o gene PR-8 foram caracterizadas por Southern blot e o número de inserções variou de 1 a 3. Dezenove plantas transgênicas de laranja ‘Hamlin’ com o gene CDR-1 foram obtidas através dos experimentos de transformação genética. A eficiência de transformação foi de 2,06 a 5,96%. Dessas, apenas uma foi caracterizada por Southern blot apresentando 1 número de cópia do DNA no genoma da planta. / HLB is currently considered the main disease affecting citrus plants. Given this factor, research for cultivars resistant to this disease is needed. Genetic transformation via Agrobacterium with the use of model plants has been an alternative for checking the gene function in response to pathogens, because these model plants have as characteristic a short life cycle and high power of regeneration. Therefore, the aim of this work was to produce transgenic plants, via Agrobacterium tumefaciens, of Micro-Tom tomato (Solanum lycopersicum L.), and sweet orange, with the genes encoding the PR-8 and CDR-1 proteins isolated from Citrus sinensis. The cotyledons from in vitro germinated Micro-Tom tomato seeds were used as explants source for genetic transformation experiments with PR-8 and CDR-1 genes. These explants were subcultured until the appearance of regenerating shoots and after transgenic plants, which were acclimatized and taken to a greenhouse. The transgenic plants were confirmed by PCR and the number of gene insertions by Southern blot. The plants were grown until T1 generation was obtained. Simultaneously genetic transformation experiments were performed with epicotyl segments from \'Hamlin\' sweet orange seeds germinated in vitro with CDR-1 gene in order to obtain transgenic plants and their characterization. Simultaneously, the standard curve construction was performed by qPCR analysis for identification of Pseudomonas syringae pv. tomato. Thirteen transgenic plants of Micro-Tom tomato with PR-8 gene and three with CDR-1 gene were obtained. The transformation efficiencies were around 0,38 to 1,98%. Three transgenic plants of Micro-Tom tomato with PR-8 gene were characterized by southern blot, and the number of inserts ranged from 1 to 3. Nineteen transgenic \'Hamlin\' sweet orange plants with CDR-1 gene were obtained through genetic transformation experiments, and the transformation efficiency was 2,06 to 5,96%. One plant was characterized, by Southern blot and has one DNA copy number in the plant genome.

Pseudomonas syringae pv. tomato

Solanum lycopersicum

HLB

Melhoramento

Planta modelo

Resistência

Pseudomonas syringae pv. tomato

Solanum lycopersicum

HLB

Improvement

Model plant

Resistance

Análise da expressão gênica modulada por óxido nítrico na resposta de defesa de Arabidopsis thaliana à bactéria Pseudomonas syringae / Analysis of gene expression modulated by nitric oxide in the defense response of Arabidopsis thaliana to the bacteria Pseudomonas syringae

Vitor, Simone Cespedes, 1986-

22 August 2018

Orientador: Ione Salgado / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-22T08:31:31Z (GMT). No. of bitstreams: 1 Vitor_SimoneCespedes_M.pdf: 2469178 bytes, checksum: 5b012d0f044b319a6fb8e2dc382c8242 (MD5) Previous issue date: 2013 / Resumo: O NO é uma molécula sinalizadora versátil muito importante em diversos processos em plantas. Uma de suas principais atuações é na sinalização celular durante o processo de defesa contra o ataque de patógenos. Plantas de Arabidopsis thaliana do genótipo mutante nia1 nia2, deficientes para os dois genes estruturais que codificam para a enzima nitrato redutase (NR), são susceptíveis à bactéria Pseudomonas syringae. Foi sugerido que a resposta de defesa prejudicada no mutante NR-deficiente seria resultante de seus reduzidos níveis de NO, quando comparados àqueles do genótipo selvagem. Em um trabalho recente de nosso grupo, empregando microarranjo de DNA, foi observado que a fumigação com gás NO no mutante nia1 nia2 foi capaz de modular diversos genes relacionados à defesa, alguns dos quais não previamente documentados como responsivos a esse radical. Neste trabalho se analisou por PCR em tempo real o efeito do gás NO na expressão de genes relacionados à defesa em plantas selvagem e no mutante nia1 nia2 infectados com uma linhagem avirulenta da bactéria P. syringae. Genes de defesa, como PR1, foram induzidos pela bactéria e a expressão destes foi maior no genótipo selvagem quando comparado ao nia1 nia2, o que é consistente com a susceptibilidade do mutante. A fumigação com NO também modulou genes relacionados à biossíntese de lignina (CAD1) e à sinalização de auxina (TIR1, ILL1, GH3) e etileno (ACCS7). Análises de quantificação de lignina mostraram uma pequena redução desse composto no genótipo mutante em relação ao selvagem, além de uma diferença em sua composição. Ademais, a fumigação com NO atenuou a expressão de PR1 e outros genes relacionados à via do ácido salicílico em plantas inoculadas e preveniu o crescimento bacteriano em folhas nia1 nia2. Já foi demonstrado que a inoculação do patógeno no mutante induz uma baixa produção de NO e no presente trabalho observou-se uma alta produção de H2O2 comparado ao selvagem. O H2O2 potencializou o efeito microbicida do NO fumigado na suspensão de bactéria. Os resultados sugerem que um efeito microbicida direto do NO, em conjunto com H2O2, pode resultar na atenuação da resposta de defesa na planta, reduzindo o gasto de energia associado à transcrição de genes relacionados à defesa / Abstract: NO is an important signaling and versatile molecule which plays important roles in many processes in plants. One of its main actions is in cell signaling during defense response against pathogen attack. Arabidopsis thaliana plants of the nia1 nia2 mutant genotype, deficient in the two structural genes encoding for the enzyme nitrate reductase (NR), are susceptible to the avirulent bacteria Pseudomonas syringae. It has been suggested that the impaired defense response in the NR-deficient mutant would result from their low NO levels when compared to those of the wild type. Indeed, in a recent study from our group, it was observed through a DNA microarray that fumigation of nia1 nia2 mutant with NO gas was able to modulate many genes related to defense, some of which not previously documented as responsive to this radical. In this work we analyzed by real-time PCR the effect of NO gas on the expression of genes related to defense in the wild type and nia1 nia2 mutant infected with an avirulent strain of Pseudomonas syringae. Defense genes such as PR1 were induced by the bacteria and its expression was higher in wild type when compared to nia1 nia2, which is consistent with the susceptibility of the mutant. NO fumigation also modulated genes related to the biosynthesis of lignin (CAD1) and the auxin (Tir1, ILL1, GH3) and ethylene pathways (ACCS7). Analysis of lignin showed a reduction of this compound in the mutant genotype compared to wild type, and a difference in its composition. In addition, fumigation with NO attenuated the expression of PR1 and other genes related to salicylic acid signaling in infected plants and prevented bacterial growth in nia1 nia2 leaves. Furthermore, pathogen infection is known to induce a low production of NO in nia1 nia2 and here we also observed that there is a higher production of H2O2 in the mutant compared to the wild type. H2O2 potentiated the microbicidal effect of NO fumigated in bacterial suspensions. The results suggest that a direct microbicidal effect of NO, together with H2O2, may result in attenuation of the defense response in the plant, reducing energy expenditure associated with the transcription of genes related to defense / Mestrado / Biologia Vegetal / Mestra em Biologia Vegetal

Nitrato redutases

Óxido nítrico

Expressão gênica

Fitopatologia

Arabidopsis

Pseudomonas syringae

Nitrate reductases

Nitric oxide

Gene expression

Phytopathology

Arabidopsis thaliana

Pseudomonas syringae

Investigating Potential Virulence Genes of Plant Pathogenic Bacterium Pseudomonas syringae pv. syringae Utilizing Whole-genome Sequencing Analysis and Identifying Novel Small Molecule Growth Inhibitors to Manage Pseudomonas Leaf Spot Disease on Pepper Seeds and Seedlings

Ranjit, Sochina

January 2022

No description available.

Biology

Microbiology

Plant Pathology

Identification and characterization of Pseudomonas syringae mutants altering the induction of type III secretion system

Deng, Xin

January 1900

Doctor of Philosophy / Genetics Interdepartmental Program, Plant Pathology / Xiaoyan Tang / Pseudomonas syringae bacteria utilize the type III secretion system (T3SS) to deliver effector proteins into host cells. The T3SS and effector genes (together called the T3 genes hereafter) are repressed in nutrient rich medium but are rapidly induced after the bacteria are transferred into minimal medium (MM) or infiltrated into the plant. The induction of the T3 genes is mediated by HrpL, an alternative sigma factor that recognizes the conserved hrp box motif in the T3 gene promoters. The induction of hrpL is mediated by HrpR and HrpS, two homologous proteins that bind the hrpL promoter. To identify additional genes involved in regulation of the T3 genes, P. s. pv. phaseolicola (Psph) NPS3121 transposon insertion mutants were screened for reduced induction of avrPto-luc and hrpL-luc, reporter genes for promoters of effector gene avrPto and hrpL, respectively. Determination of the transposon-insertion sites led to the identification of genes with putative functions in signal transduction and transcriptional regulation, protein synthesis, and basic metabolism. A transcriptional regulator (AefRNPS3121) identified in the screen is homologous to AefR, a regulator of the quorum sensing signal and epiphytic (plant-associated) traits that was not known previously to regulate the T3 genes in P. s. pv. syringae (Psy) B728a. AefRNPS3121 in Psph NPS3121 and AefR in Psy B728a are similar in regulating the quorum sensing signal in liquid medium but different in regulating epiphytic traits such as swarming motility, entry into leaves, and survival on the leaf surface. The two component system RhpRS was identified in Pseudomonas syringae as a regulator of the T3 genes (Xiao et al. 2007). In the rhpS- mutant, the response regulator RhpR represses the induction of the T3 gene regulatory cascade, but induces its own promoter in a phosphorylation-dependent manner. Deletion and mutagenesis analyses revealed an inverted repeat (IR) element GTATC-N6-GATAC in the rhpR promoter that confers the RhpR-dependent induction. Computational search of the P. syringae genomes for the putative IR elements and Northern blot analysis of the genes with a putative IR element in the promoter region uncovered five genes that were upregulated (PSPTO2036, PSPTO2767, PSPTO3477, PSPTO3574, and PSPTO3660) and two genes that were down-regulated (PSPTO0536 and PSPTO0897) in an RhpR-dependent manner. ChIP assays indicated that RhpR binds the promoters containing a putative IR element but not the hrpR and hrpL promoters that do not have an IR element, suggesting that RhpR indirectly regulates the transcriptional cascade of hrpRS, hrpL, and the T3 genes. To identify additional genes involved in the rhpRS pathway, suppressor mutants were screened that restored the induction of the avrPto-luc reporter gene in the rhpS- mutant. Determination of the transposon-insertion sites led to the identification of rhpR, an ATP-dependent Lon protease, a sigma 70 family protein (PSPPH1909), and other metabolic genes. A lon- rhpS- double mutant exhibited phenotypes typical of a lon- mutant, suggesting that rhpS acts with or through lon. The expression of lon was elevated in rhpS- and other T3-deficient mutants, indicating a negative feedback mechanism. Both the lon- rhpS- and the PSPPH1909- rhpS- double mutant displayed enhanced transcription of hrpL in MM than did the rhpS- mutant.

Pseudomonas syringae

Type III secretion system

Gene regulation

AefR

RhpRS

Biology, Genetics (0369)

Le rôle des microARNs dans la mise ne place de la maladie chez les plantes

El Mnouchi, Salma

January 2015

La réussite de la mise en place d’une résistance efficace chez la plante hôte requiert la présence d’un dialogue entre les différentes voies signalétiques menant à l’induction de la défense. L’implication de l’extinction génique post-transcriptionnelle dans la résistance contre des agents pathogènes, autres que les virus, est une nouvelle avenue qui va permettre de disséquer le lien qui peut exister entre les deux voies immunitaires de la plante : celle qui est déjà importante pour lutter contre les bactéries et les champignons (voie induite à la suite de la reconnaissance des éliciteurs) et celle de l’extinction génique post-transcriptionnelle. Les résultats que nous avons obtenus ont une signification très importante concernant l’implication de l’extinction génique post-transcriptionnelle dans la résistance des plantes contre les agents pathogènes d’une manière générale et Botrytis cinerea, Alternaria brassicicola et Pseudomonas syringae en particulier. Mon travail de recherche a permis d’identifier le miR472 comme étant un acteur qui favorise la mise en place de la maladie causée par des agents pathogènes du type nécrotrophe et hémibiotrophe. De plus j’ai pu, en utilisant le modèle P. syringae pv tomato DC3000-Arabidopsis, disséquer dans le détail, comment la bactérie manipule la machinerie de la plante pour activer la voie des microARNs menant à l’accumulation du miR472, responsable de la suppression de la résistance basale et du PTI. Cette suppression passe par l’inhibition de sa cible, la protéine NB-LRR; RDS1 un nouveau régulateur impliqué dans le PTI induit par la Flg22. Cette étude permettra une avancée remarquable dans les connaissances reliées à l’immunité des plantes, ce qui constituerait une étape clé dans la découverte de nouvelles stratégies de lutte contre les agents phytopathogènes. Sur le plan fondamental, cette étude a permis de consolider le dialogue qui existe entre les voies immunes de la plante et de mettre en évidence un nouvel acteur impliqué dans la résistance basale. En matière d’application, comprendre les mécanismes de défense et de résistance des plantes aux agents pathogènes est primordial pour développer des plantes génétiquement résistantes et des stimulateurs de défense naturelle (Vaccin de plantes). Ceci constitue un enjeu majeur dans l'objectif de concevoir de nouveaux moyens de lutte phytosanitaire, à la fois plus respectueux de l’environnement et ayant moins d’impact sur la santé humaine.

Arabidopsis thaliana

Botrytis cinerea

Alternaria brassicicola

Pseudomonas syringae

MicroARN

CC-NB-LRR

The metabolic context for virulence in Pseudomonas syringae

McCraw, Sarah Louise

January 2014

The apoplast is the site of infection for many important bacterial crop pathogens, including the model pathogen Pseudomonas syringae pv. tomato DC3000 (Pst DC3000). The chemical environment within the plant apoplast can determine the outcome of bacterial infection and the composition of this compartment is known to change in response to the presence of invading organisms. However, this metabolically dynamic environment has received little attention in the literature, and even less is known about how metabolites in the apoplast influence the expression of virulence genes. In this study, several aspects of the metabolic context of virulence were assessed. First, a broad-scale analysis of the tomato apoplast was undertaken, which identified metal ions, sugars, organic acids and amino acids, the most abundant of which was the non-protein amino acid gamma-aminobutyric acid (GABA). The impact these components had on the expression of virulence genes and metabolism in Pst DC3000 were then tested. Components such as fructose and aspartate caused high levels of virulence gene expression which correlated with the accumulation of intracellular glutamate, whereas repressive components, such as GABA and threonine, resulted in lower glutamate levels. Second, metabolic flux analysis showed that Pst DC3000 underwent major changes in central carbon metabolism in response to virulence gene inducing conditions. The identification of altered internal metabolism in Pst DC3000 cells expressing virulence genes led to the conclusion that Pst DC3000 may understand its external environment by sensing intracellular metabolites or metabolic fluxes. Third, the role of GABA assimilation in virulence was explored, and it was found that high internal GABA levels resulted in virulence gene repression. In addition, previously unidentified mechanisms for GABA uptake and transport were detected by the use of a novel ‘unlabelling’ experiment.

632

The Transcriptional Regulation of the Central Plant Defense Signal, Salicylic Acid

Zheng, Xiao-yu

January 2014

<p>Salicylic acid (SA) is a central plant defense signal. It is not only required for closing the stomata upon infection to prevent pathogens from entering into the plant apoplast, but also mediates defense responses activated by pathogen-originated microbe-associated molecular patterns (MAMPs) and effectors in the infected tissues. In addition, SA is a necessary and sufficient signal for systemic acquired resistance (SAR). In <italic>Arabidopsis</italic> <italic>thaliana</italic>, SA level increases in response to pathogen attack, which is essential for activating defense responses. This SA accumulation involves transcriptional activation of several genes including <italic>ICS1</italic> (<italic>ISOCHORISMATE</italic> <italic>SYNTHASE</italic> <italic>1</italic>), <italic>EDS5</italic> (<italic>ENHANCED</italic> <italic>DISEASE</italic> <italic>SUSCEPTIBILITY</italic> <italic>5</italic>), <italic>EDS1</italic> (<italic>ENHANCED</italic> <italic>DISEASE</italic> <italic>SUSCEPTIBILITY</italic> <italic>1</italic>), <italic>PAD4</italic> (<italic>PHYTOALEXIN-DEFICIENT</italic> <italic>4</italic>) and <italic>PBS3</italic> (<italic>avrPphB</italic> <italic>SUSCEPTIBLE</italic> <italic>3</italic>). However, it is not well understood how pathogenic signals induce these SA accumulation genes. Interestingly, our time-course transcriptome analysis showed that these five genes share a similar pathogen-induced expression pattern, suggesting the existence of common transcription factors (TFs). Through yeast-one-hybrid screening, a TF NTL9 was identified for its interactions with the promoters of the SA accumulation genes. Preferentially expressed in guard cells, NTL9 activates the expression of SA accumulation genes in guard cells. The <italic>ntl9</italic> mutant is defective in pathogen-induced stomatal closure mediated by a well-characterized MAMP, flg22. Consistent with the stomatal closure defect, the <italic>ntl9</italic> mutant exhibits elevated susceptibility to surface-inoculated pathogens. The stomatal closure defect of the <italic>ntl9</italic> mutant can be rescued by exogenous application of SA, demonstrating that NTL9 acts upstream of SA in stomatal closure response. These results suggest that NTL9-mediated activation of SA accumulation genes is essential for MAMP-triggered stomatal closure.</p><p>While plants induce SA to activate defense responses, pathogens can also produce virulence factors to counteract the effects of SA. Coronatine is one such virulence factor produced by <italic>Pseudomonas</italic> <italic>syringae</italic>. Coronatine is known to promote opening of stomata for bacterial entry, bacterial growth in the apoplast, systemic susceptibility and development of disease symptoms such as chlorosis. In the process of examining the mechanisms underlying coronatine-mediated virulence, three homologous TFs, ANAC019, ANAC055 and ANAC072, were found to be activated by coronatine directly through the TF, MYC2. Genetic characterization of these three TF mutants revealed that these TFs mediate multiple virulence effects of coronatine by inhibiting SA accumulation. To exert this inhibitory effect, these TFs repress <italic>ICS1</italic> and activate <italic>BSMT1</italic>, genes involved in SA biosynthesis and inactivation modification, respectively. Thus, a signaling cascade downstream of coronatine was illustrated to dampen SA-mediated defense responses through differential transcriptional regulation of genes related to SA level.</p><p>Taken together, my dissertation studies revealed novel transcriptional regulation of SA production and demonstrated that this transcriptional regulation is a vital point not only for plant defense activation but also for pathogen manipulation to counteract defense responses. Further studies on the interplay of this transcriptional regulation by different TFs would broaden our understanding about the dynamics of plant-pathogen interaction.</p> / Dissertation

Biology

Genetics

Plant sciences

Arabidopsis

Coronatine

Pseudomonas syringae

Salicylic acid

Stomatal immunity

Transcriptional regulation

Cloning and identification of genes involved in the interaction between the bacterial stone fruit pathogen Pseudomonas syringae pv. syringae strain NV and plum trees

Appel, Maryke

03 1900

Thesis (PhD)--Stellenbosch University, 2001. / ENGLISH ABSTRACT: Bacterial canker of stone fruit, caused by Pseudomonas syringae pv. syringae, is one of the most destructive crop diseases in South Africa. Chemical control has failed completely and effective long-term management strategies will have to rely on the breeding of resistant host trees. To assist in such breeding programmes, investigations into the molecular basis of the interaction between P. s. pv. syringae and stone fruit trees have been undertaken in collaboration with the ARC-Fruit, Wine and Vine Research Institute in Stellenbosch. The aim of this dissertation was to clone and identify genes that are involved in interaction between the bacterial canker pathogen and stone fruit trees. In the first part of the study, the harpin encoding gene of a local strain of the pathogen, P. s. pv. syringae NV, was amplified in a polymerase chain reaction (PCR) strategy with primers based on the hrpAZB sequences of the bean pathogen, P. s. pv. syringae 61. Sequencing of this hrpZpssNvgene revealed a high degree of homology (96%) between the harpin encoding genes and harpin proteins of the two strains. The hrpZpssNvgene was subsequently cloned into the pMAL-c2 expression vector and expressed in Escherichia co/i. This system was used for the production of purified, biologically active, recombinant HrpZpSSNV protein. In the second part of the study, differential display (DD) technology was used to identify genes that are induced in stone fruit trees in response to P. s. pv. syringae and/or its harpin elicitor. For this purpose, actively growing shoots of two Prunus sa/icina cultivars, the moderately resistant cv. 'Laetitia' and the highly susceptible cv. 'Songold' were treated with recombinant harpinpssNvprotein or live P. s. pv. syringae NV bacteria. An untreated control and wounding control was included in the experiment. Total RNA was isolated for comparative mRNA analysis 24 hours after treatment. DD profiles were generated with fifteen primer combinations. Eight candidate bands were re-amplified, cloned and sequenced. Reverse transcription PCR was employed to verify the expression patterns of the cloned bands in the original RNA sample set. Two bands, DDc and DD4 were shown to be differentially expressed between treatments and/or cultivars, while no differences in the expression levels of the remaining six bands (DDa, DDe, DD3, DD5, DD6 and DD7) were observed. BLAST similarity searches yielded significant matches for DDe, DD4 and DD7 with plant defense-related genes. / AFRIKAANSE OPSOMMING: Bakteriese kanker van steenvrugte, wat deur Pseudomonas syringae pv. syringae veroorsaak word, is een van die mees verwoestende siektes van landbougewasse in Suid-Afrika. Chemiese beheermaatreëls het geheel en al misluk en effektiewe langtermyn beheerstrategieë sal op die teling van weerstandbiedende gasheerbome moet staatmaak. Ondersoeke na die molekulêre basis van die interaksie tussen P. s. pv. syringae en steenvrugbome is in samewerking met die LNR-Vrugte-, Wyn- en Wingerdnavorsingsinstituut in Stellenbosch van stapel gestuur om tot sulke telingsprogramme by te dra. Die doelwit van hierdie proefskrif was om gene wat betrokke is in die interaksie tussen die bakteriese kanker patogeen en steenvrugbome te kloneer en te identifiseer. In die eerste gedeelte van die studie is die harpien-koderende geen van 'n plaaslike ras van die patogeen, P. s. pv. syringae NV, geamplifiseer in 'n polimerase kettingreaksie (PKR)-strategie met peilers wat op die hrpAZB-geenopeenvolgings van die boontjiepatogeen, P. s. pv. syringae 61, gebaseer is. Volgordebepaling van hierdie hrpZpssNv-geen het 'n hoë vlak van homologie (96%) tussen die harpien-koderende gene en harpien proteïene van die twee rasse getoon. Die hrpZpssNv-geen is vervolgens in die uitdrukkingsvektor pMAL-c2 gekloneer en uitgedruk in Escherichia coli. Hierdie sisteem is vir die produksie van suiwer, biologies-aktiewe, rekombinante HrpZpssNv-proteingebruik. In die tweede gedeelte van die studie is die differensiaalvertoon (DD) tegniek gebruik om gene te identifiseer wat deur P. s. pv. syringae en/of sy harpien elisitar in steenvrugbome geïnduseer word. Vir hierdie doel is aktief-groeiende lote van twee Prunus sa/icina kultivars, die matig weerstandbiedende kv. 'Laetitia' en die hoogs vatbare kv. 'Songold', met rekombinante harpienpssNvproteïen of lewende P. s. pv. syringae NV bakterieë behandel. 'n Onbehandelde- en verwondingskontrole is in die eksperiment ingesluit. Totale RNA is 24 uur na behandeling vir vergelykende mRNA-analise geïsoleer. DD-profiele is met vyftien peilerkombinasies gegenereer. Agt kandidaatbande is geheramplifiseer en gekloneer, waarna hul DNA-opeenvolgings bepaal is. Trutranskriptase-PKR is gebruik om die ekspressiepatrone van die gekloneerde bande in die oorspronklike RNA monsters na te gaan. Daar is vasgestel dat twee van die bande, DDc en DD4, differensieel tussen kultivars en/of behandelings uitgedruk is, terwyl geen verskille in die ekspressievlakke van die oorblywende ses bande (DDa, DOe, 003, DOS, 006 en DO7) waargeneem is nie. BLAST-soektogte het betekenisvolle ooreenkomste vir DDe, DD4 en DD7 met plant weerstandsgeassosieerde gene opgelewer.

Phytopathogenic bacteria

Pseudomonas syringae

Plum -- Diseases and pests

Stone fruit -- Diseases and pests

Dissertations -- Biochemistry

Theses -- Biochemistry

Elektrophysiologische Untersuchungen zur frühen Erkennungsphase zwischen Pflanzen und Mikroorganismen / Electrophysiological analyses of the early recognition phase between plants and microorganism

Jeworutzki, Elena

January 2009

An der pflanzlichen Plasmamembran geschieht die erste Wahrnehmung von mikrobiellen Molekülen, die MAMPs genannt werden. MAMP/PAMP Rezeptoren leiten frühe Abwehrantworten, wie die Produktion von reaktiven Sauerstoffspezies (ROS), externe Alkalisierung oder Ethylen, ein. Die Arabidopsis FLS2 rezeptorartige Kinase (RLK) stellt einen plasmamembran-lokalisierten MAMP Rezeptor dar, der über die Detektion des Flagellum von Pseudomonas species, eine basale Immunität in Arabidopsis thaliana vermittelt. Flg22, der kürzeste aktive Teil des bakteriellen Flagellins besteht aus 22 Aminosäuren und ist der bestuntersuchte bakterielle Elizitor. In der vorliegenden Arbeit zeigen wir eine starke Beteiligung von Ionenflüssen in der Initiationsphase der basalen Immunität. Unsere Messungen an intakten Arabidopsis Pflanzen und Pflanzengeweben sind in höchstem Masse reproduzierbar und öffnen eine neue Sicht, über die Natur von Ionentransporten in der Pflanzen - Mikroben Interaktion. Als Antwort auf die Applikation von flg22, haben wir nach einer Verzögerungsphase von etwa 2 Minuten eine transiente, dosis-abhängige Depolarisation (EC50=0,2 nM) in Mesophyll- und Wurzelhaarzellen von A. thaliana messen können. Das um 2 Aminsäuren kürzere Peptid flg22 &#916;2 oder das Flagellin anderer Bakterien (Agrobacterium or Azospirillum) führten zu keiner Membrandepolarisation. Ebenso konnten keine Membranspannungsänderungen in dem Arabidopsis Ökotypen Ws-0, dem der funktionelle FLS2 Rezeptor fehlt, detektiert werden. Die Komplementation von Ws-0 Pflanzen mit dem intakten FLS2 Rezeptorgen rief eine Resensibilisierung für flg22 hervor. Mit dem EF-Tu Elizitor Peptid aus E.coli, welches durch den Arabidopsis MAMP Rezeptor EFR detektiert wird, wurden ähnliche Ergebnisse erzielt. Auf der Basis von Aequorin wurden Kalzium-induzierte Lumineszenzmessungen durchgeführt, in denen ein transienter Anstieg der zytosolischen Kalziumkonzentration als Antwort auf die Applikation von flg22 gemessen werden konnte. Dosis-Abhängigkeitsmessungen von flg22 und [Ca2+]cyt wiesen zwei unterschiedliche EC50 Werte, von 43 ± 2 pM und 67 ± 42 nM, auf. Möglicherweise wird auf zwei verschiedene Kalziumpools zugegriffen oder es werden zwei verschiedene Kalziumleitfähigkeiten aktiviert. Die Ionenkanalaktivierung und folgende Depolarisation benötigt die aktive Rezeptorkinase. In bak1-4 Arabidopsis Pflanzen, in denen die FLS2 Untereinheit BAK1 – eine weitverbreitete RLK, die auch mit dem Brassinosteroid Rezeptor assoziiert ist – fehlt, konnte keine Depolarisation als Antwort auf flg22 gemessen werden. Arabidopsis Mesophyllzellen zeigten die typische Alkalisierung des Apoplasten als Antwort auf flg22. Nicht-invasive MIFETM Experimente mit Ionen-selektiven Elektroden ergaben, dass der pH-Anstieg durch einen Einstrom von Protonen hervorgerufen wurde. Zusätzlich wurde ein Ausstrom von Chlorid und Kalium aufgezeichnet. Ähnlich wie das Kalziumsignal waren alle detektierten Ionenströme von transienter Natur. Im zweiten Ansatz wurden Membranpotential-Messungen durchgeführt, während in der externen Lösung die Konzentrationen von Protonen, Kalzium, Kalium oder Anionen variiert wurden. Nur eine Änderung des Anionengradienten hatte einen entscheidenden Einfluss auf die flg22-induzierte Depolarisation, was die Wichtigkeit der Anionenkanalaktivierung unterstreicht. Exudat Analysen ergaben, dass Nitrat das bevorzugt transportierte Ion ist. Unter zahlreichen getesteten Ionenkanalblockern erwies sich lediglich Lanthan als effektiver Blocker des flg22-induzierten zytosolichen Kalziumanstiegs, des Protoneneinstroms und der Membrandepolarisation. Da Lanthan bekanntlich unspezifische Kationenkanäle blockt, kann man an diesem Punkt davon ausgehen, dass Kalzium-aktivierte Anionenkanäle die Membrandepolarisation vermitteln und darauf eine Aktivierung von auswärtsgerichteten Kaliumkanälen folgt. Zukünftige Studien mit Doppelläufigen-Mikroelektroden Spannungsklemmexperimenten oder externen ionenselektiven Elektroden an intakten Schliesszellen werden helfen weitere Informationen über die Natur der Ionenkanäle in der basalen Immunität oder generell in der Pflanzen-Mikroben Interaktion zu erhalten. Über die elektrophysiologische Charakterisierung der multiplen Ionenströme in der basalen Immunität hinaus, ist natürlich der nächste wichtige Schritt das oder die Gene zu finden, die für die Ionenkanäle oder Transporter kodieren, die durch nicht nekrotisierende Elizitoren wie flg22 in der basalen Immunantwort in Pflanzen aktiviert werden. / The plant plasma membrane represents the first site for recognition of microbial patterns called MAMPs. MAMP receptors mediate early defense responses including production of reactive oxygen species (ROS), external alkalinisation or ethylene. The Arabidopsis FLS2 receptor-like kinase (RLK) represents a plasma-membrane localized MAMP receptor that provides for innate immunity in Arabidopsis thaliana plants by specifically recognizing the flagellum (flg) of Pseudomonas species. Flg22, the shortest active part of flagellin, composed by 22 aminoacids is the best established bacterial elicitor that. About the role of ion channels in innate immunity nothing was known yet. In the current work we show a strong involvement of ion fluxes in the initiating phase of innate immunity. Our measurements on intact Arabidopsis plants and plant tissues are highly reproducible and open a new view of ion channel functions in plant microbe interactions. In response to the application of flg22, after a delay of about 2 minutes, we recorded a transient, dose-dependent depolarization (EC50=0.2 nM) in mesophyll and root hair cells of A. thaliana. Following wash-out of the peptide elicitor and recovery of the membrane potential to resting potential values within 70 ± 9 min, depolarizations could be elicited several times. No membrane depolarization was evoked upon application of flg22&#916;2, a truncated flg22 peptide, or by application of flagellin from other bacteria (Agrobacterium or Azospirillum). Likewise, depolarization was not observed in the natural knockout mutant of the Arabidopsis ecotype Ws-0 lacking the functional FLS2 receptor. Complementation of transgenic Ws-0 plants with the functional FLS2 receptor restored flg22 sensitivity, indicating that FLS2 is essential for flg22 evoked membrane potential changes. Similar results were obtained using the E. coli EF-Tu elicitor peptide elf18, which is recognized by the Arabidopsis MAMP receptor EFR. Aequorin based calcium measurements allowed us to record a transient increase in cytosolic calcium concentration in response to applied flg22. Dose-response studies revealed two distinct EC50 values for the calcium response of 43 ± 2 pM and 67 ± 42 nM respectively. This indicates that two different calcium pools or two different calcium permeabilities in the plasma membrane were activated by flg22. In line with a requirement of receptor-kinase activity for ion channel activation and subsequent depolarization, the latter was completely blocked by the kinase inhibitor K-252a. In bak1-4 Arabidopsis plants, lacking the FLS2 subunit BAK1 – a promiscuous RLK also associated with the brassinosteroid receptor - no depolarisation was measured in response to flg22. This indicated that both RLKs – FLS2 and BAK1 – are required for flagellin induced ion channel activation. Arabidopsis mesophyll cells showed the typical alkalinization of the apoplast in response to flg22. Noninvasive experiments with vibrating ion-selective electrodes revealed that this pH rise was due to an influx of protons. In addition an efflux of chloride and potassium was recorded. All fluxes were transient in nature, as was the observed calcium signal. Simultaneous measurements using two ion-selective electrodes showed a delay of the potassium efflux in comparison to the other ions that participate in the flg22 response. In the second approach, membrane potential measurements were performed while changing extracellular concentrations of protons, calcium, potassium or anions. Changing the anion gradient had the greatest impact on flg22 induced depolarization, suggestive of anion channel activation. Exudates analyses of flg22 treated leaves revealed that nitrate was the favored anion transported. Among many putative channel blocking agents tested, only lanthanum was identified to be potent in blocking the flg22 induced the cytosolic calcium rise, proton influx, and membrane potential depolarization. Since lanthanum represents a non-specific cation channel blocker, we favor to conclude that a calcium dependent activation of anion channels mediated membrane potential depolarization and consequently outward rectifying potassium channels. Future studies with double-barreled microelectrode voltage-clamp or external ion selective electrodes on intact guard cells may help to gain further information about the nature of ion channels in innate immunity or plant microbe interaction in general. Of course, all over the electrophysiological characterization of the multiple ion fluxes in innate immunity the next important step would be to discover the gene(s) coding for ion channels or transporters activated by non necrotic elicitors as flg22 in the innate immune response of plants.

Calcium

Induzierte Resistenz

Ackerschmalwand

Ionenkanal

Elektrophysiologie

Pseudomonas syringae

Membranpotenzial

Flagelline

ddc:580

Identification and Characterization of Pseudomonas syringae Type Three Effectors that Alter Auxin Responses.

Nievas, Maria Soledad

13 January 2014

Plant hormones act in a complex network where their pathways regulate and interact to control different mechanisms, such as development and stress responses. This crosstalk between hormones can be exploited by pathogens to suppress plant defense responses and thereby increase pathogen growth. Pseudomonas syringae pathogenicity is reliant on a Type III secretion system (TTSS) that acts as a specialized injection apparatus to deliver virulence proteins, known as type III effectors (TTEs), into the plant cell cytosol. In my work, I have screened hormone inducible promoter::GUS transgenic Arabidopsis thaliana lines against a P. syringae TTE library in order to identify TTEs involved in the perturbation of hormone signaling in planta. Through this screen I identified two P. syringae TTEs, HopAK1 and HopAL1, both belonging to the same bacterial strain P. syringae pv. maculicola ES4326. I found that HopAK1 can sensitize A. thaliana plants to auxin. On the other hand, HopAL1 activates auxin signaling. Monitoring of auxin signaling was done using transgenic DR5::GUS plants. Both TTEs render the plant susceptible to bacterial infection, highlighting a potential relationship between increased auxin signaling and virulence.

auxin

type three effector

plant hormones

Pseudomonas syringae

high-throughput screening

0480