Evaluation of the role of PGIPs in plant defense responses

Becker, John van Wyk, 1975-

12 1900

Dissertation (PhD)--University of Stellenbosch, 2007. / ENGLISH ABSTRACT: Plants have developed sophisticated means of combating plant diseases. The events that prepare the plant for, and follow plant-pathogenic interactions, are extremely complex and have been the topic of intensive investigation in recent years. These interactions involve a plethora of genes and proteins, and intricate regulation thereof; from the host and pathogen alike. Studying the contribution of single genes and their encoded proteins to the molecular dialogue between plant and pathogen has been a focus of plant molecular biologists. To this end, a gene encoding a polygalacturonase-inhibiting protein (PGIP) was recently cloned from Vitis vinifera. These proteins have the ability to inhibit fungal endopolygalacturonases (ePGs), enzymes which have been shown to be required for the full virulence of several fungi on their respective plant hosts. The activity of PGIP in inhibiting fungal macerating enzymes is particularly attractive for the improvement of disease tolerance of crop species. The VvPGIP-encoding gene was subsequently transferred to Nicotiana tabacum for high-level expression of VvPGIP. These transgenic plants were found to be less susceptible to infection by Botrytis cinerea in an initial detached leaf assay. Also, it was shown that ePG inhibition by protein extracts from these lines correlated to the observed decrease in susceptibility to B. cinerea. This study expands on previous findings by corroborating the antifungal nature of the introduced PGIP by whole-plant, timecourse infection assays. Six transgenic tobacco lines and an untransformed wildtype (WT) were infected and the lesions measured daily from day three to seven, and again at day 15. The transgenic lines exhibited smaller lesions sizes from three to seven days post-inoculation, although these differences only became statistically significant following seven days of incubation. At this point, four of the six lines exhibited significantly smaller lesions than the WT, with reductions in disease susceptibility ranging between 46 and 69% as compared to the WT. Two of the lines exhibited disease susceptibility comparable to the WT. In these resistant plant lines, a correlation could be drawn between Vvpgip1 expression, PGIP activity and ePG inhibition. These lines were therefore considered to be PGIP-specific resistant lines, and provided ideal resources to further study the possible in planta roles of PGIP in plant defense. The current hypothesis regarding the role(s) of PGIP in plant defense is twofold. Firstly, PGIPs have the ability to specifically and effectively inhibit fungal ePGs. This direct inhibition results in reduced fungal pathogenicity. Alternatively, unhindered action of these enzymes results in maceration of plant tissue and ultimately, tissue necrosis. Subsequently, it could be shown that, in vitro, the inhibition of ePGs prolongs the existence of oligogalacturonides, molecules with the ability to activate plant defense responses. Thus, PGIPs limit tissue damage by inhibition of ePG; this inhibition results in activation of plant defense responses aimed at limiting pathogen ingress. Several publications reported reduced susceptibility to Botrytis in transgenic plant lines overexpressing PGIP-encoding genes. However, none of these publications could expand on the current hypotheses regarding the possible in planta roles of PGIP in plant defense. In this study we used transgenic tobacco lines overexpressing Vvpgip1 as resources to study the in planta roles for PGIP. Transcriptomic and hormonal analyses were performed on these lines and a WT line, both before and following inoculation with Botrytis cinerea. Transcriptomic analysis was performed on uninfected as well as infected tobacco leaf material utilizing a Solanum tuberosum microarray. From the analysis with healthy, uninfected plant material, it became clear that genes involved in cell wall metabolism were differentially expressed between the transgenic lines and the WT. Under these conditions, it could be shown and confirmed that the gene encoding tobacco xyloglucan endotransglycosylase (XET/XTH) was downregulated in the transgenic lines. Additionally, genes involved in the lignin biosynthetic pathway were affected in the individual transgenic lines. Biochemical evidence corroborated the indication of increased lignin deposition in their cell walls. Additionally, phytohormone profiling revealed an increased indole-acetic acid content in the transgenic lines. These results show that constitutive levels of PGIP may affect cell wall metabolism in the Vvpgip1-transgenic lines which may have a positive impact on the observed reduced susceptibilities of these plants. An additional role for PGIP in the contribution to plant defenses is therefore proposed. PGIP may directly influence defense responses in the plant leading to the strengthening of cell walls. This might occur by virtue of its structural features or its integration in the cell wall. These reinforced cell walls are thus “primed” before pathogen ingress and contribute to the decrease in disease susceptibility observed in lines accumulating high levels of PGIP. Transcriptional and hormonal analyses, at the localized response, were performed on Botrytis-infected leaf tissue of the transgenic lines and a WT line. Several Botrytis responsive genes were found to be upregulated in both the WT and the transgenic lines. Although limited differential expression was observed between the two genotypes, the analyses identified a gene which was upregulated two-fold in the transgenic lines, as compared to WT. This was confirmed by quantitative Real-Time PCR. This gene is involved in the lipoxygenase pathway, specifically the 9-LOX branch, leading to the synthesis of the divinyl ether oxylipins colneleic and colnelenic acid, which show inhibitory effects on Botrytis spore germination. Phytohormone profiling revealed that the transgenic lines accumulated more of the defense-related hormone pool of jasmonates. These are formed via the 13-LOX pathway and have been shown to be important for the restriction of Botrytis growth at the site of infection. Collectively, the results from the infection analyses indicate that in these transgenic lines, both branches of the lipoxygenase pathway are differentially induced at the level of the localized response to Botrytis infection. Similarly, an increased induction of the synthesis of the defense-related hormone salicylic acid could be observed, although this hormone did not accumulate to significantly higher levels. These results are the first report of differential induction of a defense-related pathway in pgip-overexpressing lines and substantiate the proposal that following ePG inhibition by PGIP, signaling which activates plant defense responses, takes place. Taken together, these results significantly contribute to our understanding of the in planta role of PGIP in plant defense responses. / AFRIKAANSE OPSOMMING: Plante het deur evolusie gesofistikeerde meganismes teen die aanslag van plantsiektes ontwikkel. Die gebeure wat die plant voorberei, asook dié wat op plant-patogeen interaksies volg, is uiters kompleks en vorm die kern van verskeie navorsingstemas die afgelope paar jaar. Etlike plant- én patogeengene en proteïene is by hierdie interaksies betrokke en aan komplekse reguleringsprosesse onderworpe. Die bestudering van die bydrae van enkelgene en hul gekodeerde proteïene tot die molekulêre interaksie tussen ‘n plant en patogeen is ‘n sterk fokus van plant-molekulêre bioloë. Met hierdie doel as fokus, is ‘n geen wat vir ‘n poligalakturonaseinhiberende proteïen (PGIP) kodeer, van Vitis vinifera gekloneer. Hierdie proteïene beskik oor die vermoë om fungiese endopoligalakturonases (ePG's), ensieme wat benodig word vir die virulensie van verskeie fungi op hul gasheerplante, te inhibeer. Die inhibisie van ePG's deur PGIP en die gepaardgaande verminderde weefseldegradasie is ‘n baie belowende strategie vir die verbetering van verboude gewasse se patogeentoleransie. Die VvPGIPenkoderende geen is gevolglik na Nicotiana tabacum oorgedra vir hoëvlakuitdrukking van VvPGIP. Daar is gevind dat hierdie transgeniese plante minder vatbaar vir Botrytis cinerea-infeksies was in ‘n inisiële antifungiese toets wat gebruik gemaak het van blaarweefsel wat van die moederplant verwyder is. Daar is ook ‘n korrelasie gevind tussen B. cinerea-siekteweerstand en ePG-inhibisie deur proteïenekstrakte van die transgeniese populasie. Die huidige studie bou voort op en bevestig vorige bevindinge betreffende die antfungiese aard van die heteroloë PGIP in die heelplant en oor tyd. Ses transgeniese tabaklyne en 'n ongetransformeerde wilde-tipe (WT) is geïnfekteer en die lesies is vanaf dag drie tot sewe, en weer op dag 15, gemeet. Die transgeniese lyne het in die tydperk van drie tot sewe dae ná-inokulasie kleiner lesies as die WT getoon, alhoewel hierdie verskille slegs statisties beduidend geword het na sewe dae van inkubasie. Op daardie tydstip het vier van die ses lyne aansienlik kleiner lesies as die WT getoon, en verlagings in siektevatbaarheid het, in vergelyking met die WT, van 46% tot 69% gewissel. Twee van die lyne het siektevatbaarheid getoon wat vergelykbaar was met dié van die WT. In die siekteweerstandbiedende plantlyne was daar 'n verband tussen Vvpgip1-ekspressie, PGIP-aktiwiteit en ePG-inhibisie. Hierdie plantlyne is dus as PGIP-spesifieke siekteweerstandslyne beskou en dien dus as ideale eksperimentele bronne vir die ontleding van die moontlike in plantafunksies van PGIP in plantsiekteweerstandbiedendheid. Die huidige hipotese betreffende die funksie(s) van PGIP in plantsiekteweerstand is tweeledig. Eerstens het PGIP die vermoë om fungusePG's spesifiek en doeltreffend te inhibeer. Hierdie direkte inhibisie veroorsaak ‘n vermindering in patogenisiteit van die fungus op die gasheer. Indien ePG's egter hulle ensimatiese aksie onverstoord voortsit, sal weefseldegradasie en uiteindelik weefselnekrose die gevolg wees. Daar kon ook bewys word dat die in vitroinhibisie van ePG's deur PGIP die leeftyd van oligogalakturoniede, molekules wat die vermoë het om die plantweerstandsrespons aan te skakel, kan verleng. PGIP het dus nie net die vermoë om ePG's, en dus weefseldegradasie, te inhibeer nie; maar hierdie inhibisie lei ook daartoe dat plantweerstandsresponse aangeskakel word met die oog op die vermindering van patogeenindringing. Verskeie publikasies het reeds gerapporteer oor verminderde Botrytisvatbaarheid in PGIP transgeniese plantlyne. Geeneen van hierdie publikasies kon egter uitbrei op die huidige hipotese aangaande die moontlike in planta-funksie van PGIP in plantsiekteweerstand nie. In hierdie studie is transgeniese tabaklyne wat PGIP ooruitgedruk gebruik om hierdie moontlike in planta-funksies vir PGIP uit te klaar. Transkriptoom- en hormonale analises is op hierdie plantlyne en ‘n WT voor en ná inokulasie met die nekrotroof Botrytis cinerea uitgevoer,. Transkriptoomanalises is uitgevoer op ongeïnfekteerde, sowel as geïnfekteerde tabakblaarmateriaal deur gebruik te maak van ‘n Solanum tuberosum-mikroraster. Die analises met gesonde, ongeïnfekteerde plantmateriaal het daarop gewys dat gene betrokke by selwandmetabolisme tussen die transgeniese lyne en die WT verskillend uitgedruk was. Dit kon bewys word dat, sonder infeksiedruk, die geen wat xiloglukaan-endotransglikosilase (XET) kodeer, in die transgeniese lyne afgereguleer was. Gene wat betrokke is in die lignien-biosintetiese pad was ook in die individuele transgeniese lyne beïnvloed. Biochemiese toetse het ook die aanduiding van verhoogde ligniendeposisie in die transgeniese lyne se selwande bevestig. Addisionele fitohormoonprofiele het getoon dat hierdie lyne ook beskik oor verhoogde vlakke van indoolasynsuur (IAA). Hierdie resultate wys daarop dat konstitutiewe vlakke van PGIP selwandmetabolisme in die Vvpgip1-transgeniese lyne moontlik kan beïnvloed, wat plantsiekteweerstand in dié lyne positief kan beïnvloed. Dit wil dus voorkom asof PGIP 'n bykomende funksie in plantsiekteweerstand het. Plantweerstandsreponse kan direk deur PGIP beïnvloed word, wat tot die versterking van plantselwande kan lei; dit kan geskied by wyse van die strukturele eienskappe van die proteïen of die integrasie daarvan in die selwand. Hierdie selwande is dus “voorberei” alvorens patogeenindringing plaasvind en kon bydra tot die verminderde siektevatbaarheid wat waargeneem is in lyne wat hoë vlakke van PGIP akkumuleer. Transkriptoom- en hormonale analises is ook uitgevoer op Botrytisgeïnfekteerde blaarmateriaal van beide die transgeniese lyne en ‘n WT. Verskeie Botrytis-responsgene is in beide die transgeniese lyne en die WT opgereguleer. Differensïele geenekspressie tussen die twee genotipes was taamlik beperk, maar in die analises kon ‘n geen geïdentifiseer word wat tweevoudig in die transgeniese lyne opgereguleer was in vergelyking met die WT. Hierdie resultaat is ook bevestig met behulp van die “Real-Time” Polimerasekettingreaksie (PKR). Hierdie geen is betrokke in die lipoksigenase (LOX) -pad (spesifiek die 9-LOXarm), wat tot die sintese van die diviniel-eter oksilipiene “colneleic-” en “colnelenic”-suur lei. Daar is al bewys dat hierdie twee verbindings Botrytisspoorontkieming kan inhibeer. Fitohormoonprofiele van die geïnfekteerde plante het gewys dat die transgeniese lyne verhoogde vlakke van die poel van jasmonate wat plantsiekteweerstands-hormone is, ná inokulasie akkumuleer. Hierdie hormone word in die 13-LOX-arm van die lipoksigenase pad gevorm en is belangrik vir die beperking van Botrytis by die infeksiesetel. Die resultate van die analises wat op Botrytis-infeksie volg, dui daarop dat beide arms van die lipoksigenasepad in die transgeniese lyne verskillend by die lokale respons geïnduseer word. ‘n Verhoogde induksie van ‘n ander plantsiekteweerstandshormoon, salisielsuur, kon ook opgemerk word, alhoewel die totaal geakkumuleerde vlakke nie beduidend hoër was as dié van die WT nie. Hierdie resultate is die eerste wat onderskeidende induksie van ‘n siekteweerstandspad in enige van die pgip-ooruitgedrukte plantlyne rapporteer. Daarmee ondersteun dit ook die hipotese dat, seintransduksie wat plantweerstandsresponse aanskakel, ná inhibisie van ePG deur PGIP plaasvind. Die resultate wat met hierdie studie verkry is, dra dus beduidend by tot die huidige kennis van die in planta-funksie van PGIP in plantsiekteweerstandsresponse.

Plant-pathogen relationships

Grapes -- Disease and pest resistance

Grapes -- Defenses

Polygalacturonase

Agricultural biotechnology

Plant defenses

Polygalacturonase-inhibiting proteins

Theses -- Wine biotechnology

Dissertations -- Wine biotechnology

Factors influencing the control of citrophilous mealybug Pseudococcus calceolarie (Maskell) by Coccophagus gurneyi Compere in the Riverland of South Australia

Alfaro Lemus, Ana Lilia.

January 2001

Includes bibliographical references (leaves 102-114) The highly successful biological control of the citrophilous mealybug Pseudococcus calceolarie (Maskell) (CM) by the parasitic wasp Coccophagus gurneyi Compere in several countries led to the release of this parasitoid in the Riverland of South Australia as part of an integrated pest management program. However CM has not been successfully controlled in this region. The results of this study may help to explain the lack of effective biological control of CM in Riverland citrus.

Metabolism and pathogenicity in the phytopathogen Rhodococcus fascians / Métabolisme et pathogénicité chez le phytopathogène Rhodococcus fascians

Forizs, Laetitia

10 February 2012

Rhodococcus fascians is a Gram-positive phytopathogenic bacterium which induces the development of leafy galls, local amplifications of multiple buds, on most infected plants. This process is linked to the production of phytohormones along with the presence of essential virulence-associated genes like the plasmid loci att and fas and the chromosomal gene vicA. However, the presence of these genes is not sufficient to ensure the infection phenotype development, indicating that other genes play a role in R. fascians pathogenicity. In this work, we studied the metabolic modifications occurring when the bacterium interacts with its host using a proteomic approach. A comparison between virulent and avirulent strains showed variations in the expression of catalases. In the virulent strain, besides the transitory induction of the att locus expression, the bacterium changes its metabolism from the Krebs cycle to the glyoxylate shunt, a process which is frequently observed in bacteria confronted to a hostile environment. The expression of the shunt-specific enzyme isocitrate lyase increased, while expression of fumarate hydratase and pyruvate dehydrogenase decreased. Hence, we focused on the link between the glyoxylate shunt and virulence. A screening of a R. fascians mutant library based on the capacity of bacteria to use acetate as the sole carbon source, a metabolic pathway depending on the glyoxylate shunt, resulted in the identification of a new gene essential for R. fascians pathogenicity. This gene encodes a glycosyl transferase, an enzyme known to be involved in the bacterial cell wall biosynthesis but possibly also implicated in cytokinin secretion. A mutant in this gene harboured an altered colony phenotype and could not induce malformations on infected plants. Accordingly, our results were integrated in the leafy gall pathology model recently presented by Stes et al. (2011). Finally, the several questions that are raised by this work, allowed us to suggest further research perspectives in order to unveil a little more of the R. fascians mysterious ways to interact with the plant./Rhodococcus fascians est une bactérie Gram-positive phytopathogène qui induit le développement de galles feuillées, des amplifications locales de multiples bourgeons, sur la plupart des plantes infectées. Ce processus est lié à la production de phytohormones ainsi qu’à la présence de gènes essentiels associés à la virulence tels que les loci plasmidiques att et fas et le gène chromosomique vicA. Cependant, la présence de ces gènes ne suffit pas à garantir le développement du phénotype d’infection, indiquant que d’autres gènes jouent un rôle dans la pathogénicité de R. fascians. Dans ce travail, nous avons étudié les modifications métaboliques qui se produisent lorsque la bactérie interagit avec son hôte par une approche protéomique. Une comparaison entre les souches virulente et avirulente a mis en évidence des variations d’expression au niveau des catalases. Dans la souche virulente, outre l’induction transitoire de l’expression du locus att, la bactérie change son métabolisme pour passer du cycle de Krebs au shunt du glyoxylate, un processus fréquemment observé chez les bactéries confrontées à un environnement hostile. L’expression de l’isocitrate lyase, enzyme spécifique au shunt, augmente, tandis que celle de la fumarate hydratase et de la pyruvate déhydrogénase diminue. Nous nous sommes donc intéressés au lien entre le shunt du glyoxylate et la virulence. Le screening d’une banque de mutants de R. fascians basé sur la capacité de la bactérie à utiliser l’acétate comme seule source de carbone, une voie métabolique dépendant du shunt du glyoxylate, a permis d’identifier un nouveau gène essentiel pour la pathogénicité de R. fascians. Ce gène code pour une glycosyl transferase, une enzyme impliquée dans la biosynthèse de la paroi bactérienne mais également dans la sécrétion des cytokinines. Un mutant dans ce gène présente un phénotype de colonie altéré et ne peut induire de malformations chez les plantes infectées. Finalement, nos résultats et les pistes d’interprétations que nous avons émisent nous permettent de compléter le modèle de l’interaction R. fascians-plante proposé récemment par Stes et al. (2011). Des perspectives de recherches visant une meilleure compréhension de ce pathosystème sont proposées. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Biologie

Sciences exactes et naturelles

Virulence (Microbiology)

Rhodococcus

Gram-positive bacteria

Gram-positive bacterial infections

Phytopathogenic microorganisms

Virulence (Microbiologie)

Rhodococcus

Bactéries Gram positives

Infections à bactéries Gram positives

Micro-organismes phytopathogènes

virulence

leafy gall

pathogenicity

metabolism

phytopathogen

rhodococcus fascians

Integrated use of yeast, hot water and potassium silicate treatments for the control of postharvest green mould of citrus and litchi.

Abraham, Abraha Okbasillasie.

January 2010

There is a growing recognition globally that many agrochemicals are hazardous to humans, animals and the environment. Therefore, there is a need to substitute these chemical products with biological and physical treatments, and to change agronomic practices in order to control pests and diseases in agriculture. The primary objective of this thesis was to develop and test in laboratory, field and commercial packhouses trials as alternative control measures against green mould of citrus (caused by Penicillium digitatum Pers: Fr. Sacc) and Penicillium molds of litchi (caused by several Penicillium). A South African isolate of P. digitatum, isolated from an infected orange fruit, was found to be resistant to imazalil (the standard postharvest fungicide used in South Africa). Sixty yeast and 92 Bacillus strains were screened for their antagonistic activity against this isolate of P. digitatum. None of the yeasts or Bacillus isolates produced a curative action against P. digitatum on oranges. However, yeast Isolate B13 provided excellent preventative control of P. digitatum, superior to all the Bacillus isolates, when it was applied to citrus fruit prior to artificial inoculation with P. digitatum. Electron microscopy showed that yeast Isolate B13 inhibited conidial germination of P. digitatum. For the control of P. digitatum pre-harvest, trees were sprayed with a yeast, Isolate B13, a few months or a few days before harvest. However, this treatment alone proved to be ineffective in providing preventative control of green mould on Valencia oranges. For the control of P. digitatum preharvest, trees were treated with potassium silicate for a full season. Regular potassium silicate treatments resulted in a significant preventative control of P. digitatum infection on both navel and Valencia oranges. Treatment of Eureka lemons with potassium silicate as a postharvest treatment for the control of P. digitatum resulted in reduced disease lesion diameters when applied preventatively or curatively. Electron microscopy showed that potassium silicate inhibited germination of P. digitatum conidia and growth of its mycelium. Hot-water dip treatment at 50-58°C for 60-180 seconds (in increments of 15 seconds), significantly reduced infection development in inoculated wounds of Valencia oranges compared with control fruit treated with tap water, without causing any rind damage. The integration of the yeast, a hot water dip and potassium silicate pre-and postharvest applications provided control of P. digitatum control in multiple packhouse trials. The control achieved by the yeast Isolate B13 or hot-water, and potassium silicate in the packhouse alone was superior or equivalent to that provided by imazalil. A similar study was also carried out to determine possible control measures for Penicillium sp. on litchis. In this study, a total of 23 yeast and 13 Bacillus isolates were obtained from litchi fruit surfaces. Ten yeast and 10 Bacillus isolates that had shown good efficacy against P. digitatum of citrus were added to these for screening against Penicillium sp. of litchis. None of the yeasts or Bacillus isolates produced a curative action against Penicillium sp. infection on litchis. However, several yeast isolates (YL4, YL10, YLH and B13) resulted in reduced severity of the pathogen, when applied preventatively, compared with an untreated control. The yeast isolates were superior to all the Bacillus isolates, when applied to litchis prior to artificial inoculation by Penicillium infection on litchis. Potassium silicate as a postharvest treatment for the control of the pathogen caused reduced lesion diameters when applied preventatively or curatively to naturally infected litchis. The results presented in this thesis highlight the use of biological, physical and agronomic practices singly or in combination as an alternative control strategy against citrus postharvest green mould. This thesis also provides an insight into expanding these strategies, partly or fully, for the control of other postharvest Penicillium infections using litchi as an example. / Thesis (Ph.D.)-University of KwaZulu-Natal, Pietermaritzburg, 2010.

Penicillium.

Biological pest control agents.

Molds (Fungi)

Theses--Plant pathology.