Contribution du désordre intrinsèque des protéines aux fonctions impliquées dans le cycle viral et l'évolution adaptative des virus à ARN : étude appliquée au genre modèle Potyvirus / Contribution of protein intrinsic disorder in functions associated to the viral cycle and the adaptive evolution of RNA viruses : study applied to the model genus Potyvirus

Charon, Justine

17 December 2015

Les protéines sont des acteurs majeurs dans les processus moléculaires et cellulaires d’un organisme. La remise en question des modalités associées aux fonctions de ces macromolécules a récemment été apportée par le concept de désordre intrinsèque. Celui-ci définit l’absence (transitoire ou permanente) de structure tridimensionnelle de certaines protéines ou régions protéiques comme étant directement liée à leurs fonctions. Chez les virus à ARN, les propriétés des protéines ou régions désordonnées semblent associées aux capacités de ces micro-organismes à détourner la machinerie cellulaire de l’hôte en interagissant avec de multiples partenaires, et à s’adapter aux nombreuses contraintes auxquelles ils doivent faire face en tant que parasites obligatoires. Ce travail porte sur les potyvirus, figurant parmi les pathogènes de plantes les plus dommageables étudiés à ce jour. L'objectif de cette thèse a été d’explorer les fonctions associées au désordre intrinsèque dans le cycle infectieux des potyvirus ainsi que dans le processus d’adaptation. Notre approche a ainsi démontré que : i) le désordre est ubiquitaire chez le genre Potyvirus ; ii) les régions de désordre conservées chez plusieurs protéines de potyvirus semblent être associées à leur(s) fonction(s) pendant l'infection ; iii) les régions désordonnées sont généralement associées à moins de contraintes évolutives, suggérant ainsi leur implication dans les processus adaptatifs des potyvirus ; iv) les régions prédites comme désordonnées semblent privilégier l’apparition de mutations et donc la capacité d’un virus à accumuler de la diversité génétique au cours de l'évolution sur son hôte naturel ; v) ce travail a permis de corréler le taux en désordre de la protéine viral genome-linked (VPg) du Potato virus Y à sa capacité à s’adapter à la résistance récessive pvr23 du piment. / Proteins are essential actors involved in a majority of molecular and cellular processes. The features associated with the functions of these macromolecules have been recently questioned with the emergence of the intrinsic disorder concept. It defines the transitory or permanent lack of 3D structure in some proteins or regions as directly related to their functions. Among RNA viruses, the properties of disordered proteins may be linked to the ability of these microorganisms to hijack the host machinery by interacting with multiple partners, as well as to adapt to the multiple constraints they must face as obligatory parasites. This work focuses on the Potyvirus genus, which includes some of the most damaging plant pathogens studied to date. The goal of this thesis was to explore the functions associated with intrinsic disorder in the infectious cycle of this viral genus as well as in its process of adaptation. Our studies have shown that i) intrinsic disorder is ubiquitous in potyviruses; ii) intrinsically disordered regions (IDR) of some of potyviral proteins are likely to be associated with important functions for the viral cycle ; iii) IDR are generally less evolutionary constrained, suggesting an adaptive potential of these regions ; iv) predicted IDR seem to favor the appearance of mutations and therefore virus ability to accumulate genetic diversity during its evolution in natural host ; v) an experimental disorder modulation within the Viral genome-linked (VPg) protein has been demonstrated as positively correlated with the adaptive ability of the Potato virus Y to overcome the pvr23 recessive resistance in pepper.

Désordre intrinsèque des protéines

Potyvirus

Virus à ARN

Adaptation

Potato virus Y

Protein intrinsic disorder

Potyvirus

RNA viruses

Adaptation

Potato virus Y

Differentiating PVY Infection from Nitrogen Deficiency in Potato Using Spectral Reflectance

Rahman, Sanzida

January 2019

Potato Virus Y (PVY) infection and nitrogen (N) deficiency cause similar symptoms (chlorosis and stunting) on potato foliage. While conventional methods, including ELISA and petiole testing, require destructive sampling and a longer time to diagnose, spectral analysis can be non-destructive, rapid and efficient. Spectral reflectance for potato cultivars representing three market types, chip processing, red-skinned fresh, and fresh and processing russets, were assessed in separate greenhouse trials in response to three N rates (90, 200, and 290 kg/ha) and two PVYN:O infection levels (clean and infected) at 4, 6, and 8 weeks after inoculation (WAI). Normalized Difference Vegetation Index (NDVI) was able to differentiate clean and PVYN:O infected samples of red-skinned and chip processing cultivars, at 4 and 8 WAI, respectively. Overall, cultivars differed in their spectral responses, indicating the importance of studying cultivar-specific spectral responses against PVY infection in future.

chip processing cultivars

fresh market potato cultivars

ndvi

nitrogen deficiency

potato virus y (pvy)

spectral reflectance

Adaptation des populations virales aux résistances variétales et exploitation des ressources génétiques des plantes pour contrôler cette adaptation / Adaptation of viral populations to plant resistance and exploitation of plant genetic resources to control this adaptation

Tamisier, Lucie

07 December 2017

L’utilisation de variétés de plantes porteuses de gènes majeurs de résistance a longtemps été une solution privilégiée pour lutter contre les maladies des plantes. Cependant, la capacité des agents pathogènes à s’adapter à ces variétés après seulement quelques années de culture rend nécessaire la recherche de résistances à la fois efficaces et durables. Les objectifs de cette thèse étaient (i) d’identifier chez la plante des régions génomiques contraignant l’évolution des agents pathogènes en induisant des effets de dérive génétique et (ii) d’étudier l’impact des forces évolutives induites par la plante sur la capacité d’adaptation des pathogènes aux résistances variétales, l’ambition étant par la suite d’employer au mieux ces forces pour limiter l’évolution des pathogènes. Le pathosystème piment (Capsicum annuum) – PVY (Potato virus Y) a été principalement utilisé pour mener ces travaux de recherche. Afin de répondre au premier objectif, une cartographie de QTL (quantitative trait loci) sur une population biparentale de piment et une étude de génétique d’association sur une core-collection de piments ont été réalisées. Ces deux approches ont permis de mettre en évidence des régions génomiques sur les chromosomes 6, 7 et 12 impliquées dans le contrôle de la taille efficace des populations virales lors de l’étape d’inoculation du virus dans la plante. Certains de ces QTL ont montré une action vis-à-vis du PVY et du CMV (Cucumber mosaic virus) tandis que d’autres se sont révélés être spécifiques d’une seule espèce virale. Par ailleurs,le QTL détecté sur le chromosome 6 co-localise avec un QTL précédemment identifié comme contrôlant l’accumulation virale et interagissant avec un QTL affectant la fréquence de contournement d’un gène majeur de résistance. Pour répondre au second objectif, une analyse de la corrélation entre l’intensité des forces évolutives induites par la plante et une estimation expérimentale de la durabilité du gène majeur a été réalisée. De l’évolution expérimentale de populations de PVY sur des plantes induisant des effets de dérive génétique, de sélection et d’accumulation virale contrastés a également été effectuée. Ces deux études ont démontré qu’une plante induisant une forte dérive génétique associée à une réduction de l’accumulation virale permettait de contraindre l’évolution des populations virales, voire d’entraîner leur extinction. Ces résultats ouvrent de nouvelles perspectives pour le déploiement de déterminants génétiques de la plante qui influenceraient directement le potentiel évolutif du pathogène et permettraient de préserver la durabilité des gènes majeurs de résistance. / Plants carrying major resistance genes have been widely used to fight against diseases. However, the pathogensability to overcome the resistance after a few years of usage requires the search for efficient and durable resistances.The objectives of this thesis were (i) to identify plant genomic regions limiting pathogen evolution by inducinggenetic drift effects and (ii) to study the impact of the evolutionary forces imposed by the plant on the pathogenability to adapt to resistance, the goal being to further use these forces to limit pathogen evolution. The pepper(Capsicum annuum) – PVY (Potato virus Y) pathosystem has been mainly used to conduct these researches.Regarding the first objective, quantitative trait loci (QTL) were mapped on a biparental pepper population andthrough genome-wide association on a pepper core-collection. These approaches have allowed the detection ofgenomic regions on chromosomes 6, 7 and 12 controlling viral effective population size during the inoculationstep. Some of these QTLs were common to PVY and CMV (Cucumber mosaic virus) while other were virusspecific.Moreover, the QTL detected on chromosome 6 colocalizes with a previously identified QTL controllingPVY accumulation and interacting with a QTL affecting the breakdown frequency of a major resistance gene.Regarding the second objective, a correlation analysis between the evolutionary forces imposed by the plant andan experimental estimation of the durability of a major resistance gene has been done. Experimental evolution ofPVY populations on plants contrasted for the levels of genetic drift, selection and virus accumulation they imposedhas also been performed. Both studies demonstrated that a plant inducing a strong genetic drift combined to areduction in virus accumulation limits virus evolution and could even lead to the extinction of the virus population.These results open new perspectives to deploy plant genetic factors directly controlling pathogen evolutionarypotential and could help to preserve the durability of major resistance genes.

Dérive génétique

Quantitative trait locus (QTL)

Durabilité des résistances

Évolution expérimentale

Capsicum annuum

Potato virus Y

Cucumber mosaic virus

Genetic drift

Quantitative trait locus (QTL)

Resistance durability

Experimental evolution

Capsicum annuum

Potato virus Y

Cucumber mosaic virus

A study of genomic variation in and the development of detection techniques for potato virus Y in South Africa

Visser, Johan Christiaan

03 1900

Thesis (MSc)--University of Stellenbosch, 2008. / ENGLISH ABSTRACT: Potato virus Y (PVY) is responsible for considerable yield losses in the South African potato industry. The incidence of this virus has greatly increased over the past few years. Even more worrying is the variation of symptoms observed during PVY infection and the recent appearance of the more virulent PVYNTN strain in local fields. This project aimed to investigate the possible genetic variation within the viral genome and to establish the origin of strains. The project also aimed to establish a dependable, area specific enzyme-linked immunosorbent assay (ELISA) to replace the currently used ELISAs. Currently seed potato certification is done using ELISA kits imported from Europe. These kits were developed for the detection of overseas variants of PVY and the use thereof in South Africa has in the past lead to false negatives. Finally, this project set out to develop, optimize and establish a sensitive and reliable real-time reverse transcriptase polymerase chain reaction (qRT-PCR) detection protocol for PVY. In the first part of the study the coat protein (CP) gene of PVY isolates from plant material obtained from various parts of South Africa was amplified using RT-PCR. The resulting cDNA was then sequenced directly or cloned into a vector and then sequenced. The resulting sequences were aligned in a data matrix with international reference sequences, analyzed and grouped according to strain. Examination of the CP gene within this matrix as well as phylogenetic analysis revealed six main groups of PVY. These six groups included the traditional PVYN and PVYO groups and a recombinant group. Furthermore it also revealed variants of PVYN and PVYO. These mutants and recombinants pose a threat as they may lead to South African strains of PVY expressing coat proteins which vary from those found overseas. This may render the currently used European ELISA method of detection less effective and subsequently result in an increase in viral prevalence. This reinforced the need for a detection method based on local viral strains. Phylogenetic and Simplot analysis also confirmed that a recombinant strain between PVYN and PVYO had evolved and that PVYNTN was such a recombinant. The second part of the study aimed to develop and establish detection methods based on local variants of PVY. This included the development of ELISA and qRT-PCR detection methods of PVY. Previously amplified cDNA of the PVY CP gene was cloned into an expression vector and successfully expressed. Antibodies produced against the recombinant protein, when used in ELISA, however, failed to achieve the required levels of sensitivity. This prompted the development of qRT-PCR detection methods for PVY. Primer combinations for PVY were designed using the previously established CP gene data matrix. A reliable and sensitive SYBR® Green I based qRT-PCR assay was developed for the detection of PVY. The assay effectively detected all known South African variants of PVY. Furthermore, a Taqman® assay was developed for the detection of all variants of PVY. The Taqman® assay was 10 fold less sensitive and does not allow for amplicon verification through melting curve analysis, but it does add more specificity due to the addition of the probe. Although these qRT-PCR detection methods are still too expensive to replace the routine diagnostics done with ELISA, they do offer the opportunity to screen valuable mother material and confirm borderline cases in seed certification. / AFRIKAANSE OPSOMMING: Aartappel virus Y (PVY) is verantwoordelik vir aansienlike opbrengsverliese in die Suid-Afrikaanse aartappelindustrie. Die insidensie van infeksie deur die virus het drasties toegeneem oor die afgelope jare. Wat egter meer kommerwekkend is, is die groter variasie in simptome van PVY infeksie en die onlangse voorkoms ‘n meer virulente ras, PVYNTN. Hierdie projek poog om moontlike genetiese variasie van PVY te ondersoek en om die oorsprong van rasse op te spoor. Die projek het ook gepoog ook om ‘n bruikbare, betroubare en area spesifieke “enzyme-linked immunosorbent assay” (ELISA) toets te ontwikkel om die huidige ingevoerde ELISA te vervang. Hierdie toetse is ontwikkel om oorsese variante van PVY op te spoor en die gebruik daarvan het in die verlede gelei tot vals negatiewes. Verder is daar ook ondersoek ingestel na die ontwikkeling van ‘n sensitiewe en betroubare “real-time reverse transcriptase polymerase chain reaction” (qRT-PCR) protokol vir die opsporing van PVY. In die eerste deel van die studie is die mantelproteïen geen van PVY isolate vanuit plant materiaal geamplifiseer deur die gebruik van RT-PCR. Hierdie materiaal is vanaf verskeie streke in Suid-Afrika ontvang. ‘n Volgordebepalingsreaksie is uitgevoer op gekloneerde of ongekloneerde cDNA verkry uit die RT-PCR. DNA volgordes is in ‘n data matriks geplaas en vergelyk met internationale volgordes om die plaaslike isolate te analiseer en te groepeer. Deur vergelyking en filogenetiese ontleding kon ses hoofgroepe van PVY geïdentifiseer word, wat tradisionele PVYN en PVYO, sowel as ‘n rekombinante ras en variante binne die tradisionele PVYN en PVYO groepe ingesluit het. Rekombinante en mutante kan veroorsaak dat Suid-Afrikanse rasse van PVY mantelproteïene uitdruk wat afwyk van die oorsese rasse wat tot gevolg mag hê dat die ELISAs van oorsee minder effektief kan wees en kan lei tot verhoogde virus voorkoms. Die realiteit en gevaar versterk die gedagte dat ‘n deteksie metode gebaseer op plaaslike virusse absoluut krities is. Filogenetiese sowel as Simplot analise het bevestig dat ’n mutante ras tussen PVYN en PVYO ontstaan het en dat PVYNTN ’n rekombinante ras is. Die tweede deel van die studie was daarop gemik om deteksie metodes te ontwikkel wat gebaseer was op plaaslike variante van PVY. Dit sluit die ontwikkeling van ELISA sowel as qRT-PCR deteksie van PVY in. Voorheen geamplifiseerde cDNA is in ‘n ekspressievektor gekloneer en suksesvol uitgedruk. Teenliggaampies teen die rekombinante proteïen, indien in ELISA aangewend, kon egter nie die nodige sensitiwiteit oplewer nie. Dit het aanleiding gegee tot ontwikkeling van qRT-PCR deteksie metodes. Inleier kombinasies vir PVY was ontwikkel deur die gebruik van die bestaande mantelproteïen geen data matrikse. ‘n Betroubare en sensitiewe SYBR® Green I qRT-PCR deteksie protokol was ontwikkel vir die effektiewe deteksie van alle bekende Suid-Afrikanse rasse van PVY. Verder is ‘n sogenaamde “Taqman®” protokol ook ontwikkel vir deteksie van alle rasse. Die “Taqman®” protokol was 10 voudiglik minder gevoelig and laat nie bevestiging deur smeltkurwe analise toe nie, maar verleen meer spesifisiteit deur die toevoeging van die “Taqman® probe”. Hierdie qRT-PCR deteksie metodes is tans te duur om as roetine diagnostiese toetse te gebruik en kan dus nie ELISA vervang nie, maar hulle bied wel die geleentheid om waardevolle moeder materiaal te toets en grensgevalle in aartappelsaad sertifisering te bevestig.

Potato virus Y

Virus diseases of plants -- South Africa

Theses -- Biochemistry

Dissertations -- Biochemistry

A study of the strain evolution and recombination of South African isolates of Potato virus Y

Visser, Johan Christiaan

12 1900

Thesis (PhD)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: Potato virus Y (PVY) is responsible for considerable yield losses in the South African potato industry. The incidence of this virus has greatly increased over the past 20 years. In previous studies nonrecombinant strains of PVY, PVY N and PVY O, were detected in South African potatoes. In a recent study the occurrence of non-recombinant strains of PVY in South African potatoes was shown to have decreased while infection by more virulent recombinant strains, PVY NTN and PVY N-W, had increased dramatically. Infection of potato plants with PVY may cause stunted growth and mosaic or necrotic leaf symptoms which in turn can lead to a significant reduction in yield. Highly virulent recombinant PVY isolates as well as some of the non-recombinant strains may cause potato tuber necrotic ringspot disease (PTNRD) which may result in losses of 10% to total crop failure. For this reason investigation of infection by local recombinant isolates on local cultivars was important. To this end a representative number of isolates were selected for whole genome sequencing based on the relative occurrence of the various isolates in South Africa. A number of these sequenced isolates were subsequently used to infect local cultivars of potato in order to investigate the influence of genetic variation within the viral genome on symptom expression. In this study 27 South African isolates of PVY were sequenced through overlapping RT-PCR fragments. Seven of these isolates, six PVY NTN and one PVY N-W, were used to mechanically infect four local cultivars of potatoes under greenhouse conditions. The infected plants were monitored to establish the rate of systemic spread using a highly sensitive qRT-PCR and resulting tubers were visually screened for PTNRD. Highly variable recombinant isolates appear to be less virulent than the more conserved recombinant isolates possibly indicating molecular determinants for pathogenicity. For this reason the amino acid sequences of the South African isolates were compared to those of international isolates and scrutinized for variation and substitutions. Some South African isolates displayed amino acid substitutions unique to the specific isolate, making them unlike those found internationally. Substitution rates throughout the amino acid sequences differed greatly, with some isolates displaying hardly any changes whilst others varied a great deal from overseas isolates. Certain regions, many of which had specific functions, were more conserved than others. This study further investigated the recombination events within the PVY genome using reticulate phylogenetic analysis, molecular dating and network construction techniques. Unlike existing approaches, the one described in this study neither assumes an underlying strictly bifurcating species tree nor assumes prior knowledge of processes underlying deviations between individual gene trees. Through the use of the resulting robust time calibrated phylogeny, the patterns of diversification and recombination in PVY may be placed in the historical context of human cultivation of potatoes. Through the use of these techniques the study aimed to test whether diversification of the major strains of PVY and recombination between them occurred within the time frame of the domestication and modern cultivation of potatoes. From these analyses it can be deduced that recombinant strains of PVY were imported into South Africa. / AFRIKAANSE OPSOMMING: Aartappel virus Y (PVY) is verantwoordelik vir aansienlike opbrengs verliese in die Suid-Afrikaanse aartappelbedryf. Die voorkoms van die virus het grootliks toegeneem oor die afgelope 20 jaar. In vorige studies is nie-rekombinante rasse van PVY, PVY N en PVY O, gedokumenteer in Suid-Afrikaanse aartappels. 'n Onlangse studie het gevind dat die voorkoms van nie-rekombinante rasse van PVY in Suid- Afrikaanse aartappels aansienlik gedaal het terwyl infeksie deur virulente rekombinante rasse, PVY NTN en PVY N-W, dramaties toegeneem het. Infeksie van aartappelplante met PVY kan vertraagde groei en mosaïek- of nekrotiese blaarsimptome veroorsaak wat kan lei tot aansienlike vermindering in opbrengs. Hoogs virulente rekombinante PVY isolate, sowel as sommige nie-rekombinante rasse, kan aartappel nekrotiese ring simptome (PTNRD) veroorsaak wat verliese van 10% tot totale misoes tot gevolg kan hê. Om hierdie rede was die ondersoek van infeksie deur plaaslike rekombinante isolate op plaaslike kultivare belangrik. Vir hierdie doel is 'n verteenwoordigende aantal isolate gekies, gebaseer op die relatiewe voorkoms daarvan in Suid-Afrika, vir heelgenoom-volgordebepaling. Van die isolate is vervolgens gebruik om plaaslike kultivare te besmet ten einde die invloed van genetiese variasie binne die virale genoom op simptoom uitdrukking te ondersoek. In hierdie studie is 27 heelgenoomvolgordes van Suid-Afrikaanse PVY isolate bepaal deur oorvleuelende RT-PCR fragmente. Sewe van hierdie isolate, ses PVY NTN en een PVY N-W, is gebruik om vier plaaslike aartappel kultivare, gegroei onder kweekhuis kondisies, meganies te infekteer. Die geïnfekteerde plante is gemonitor om die tempo van sistemiese verspreiding vas te stel deur middel van 'n hoogs sensitiewe qRTPCR en knolle is visueel inspekteer vir PTNRD. Hoogs variante rekombinante isolate blyk om minder virulent te wees as die meer bewaarde rekombinante isolate wat dui op molekulêre determinante van patogenisiteit. Om hierdie rede is die aminosuurvolgordes van die Suid-Afrikaanse isolate vergelyk met die van internasionale isolate en ondersoek vir variasie en substitusies. Sommige Suid-Afrikaanse isolate vertoon aminosuur substitusies wat uniek is tot die spesifieke isolaat en maak hul dus anders as internasionale isolate. Die aantal aminosuursubstitusies in die volgordes verskil grootliks. In vergelyking met internasionale isolate toon sommige isolate skaars enige veranderinge terwyl ander ‘n aantal verskille toon. Sekere gebiede, waarvan baie spesifieke funksies het, was meer gekonserveerd as ander. Hierdie studie ondersoek ook rekombinasie gebeure binne die PVY genoom deur retikulêre filogenetiese analise, molekulêre datering en netwerk konstruksie tegnieke. In teenstelling met bestaande benaderinge, aanvaar die tegniek wat hier beskryf word nie ‘n streng bifurkeerende filogenie, wat onderliggende verdeel, of enige voorafgaande kennis van die prosesse onderliggend aan afwykings tussen individuele filogenieë nie. ‘n Robuuste, tyd gekalibreer filogenie kan diversifikasie patrone en rekombinasie van PVY plaas in die historiese konteks van menslike verbouing van aartappels. Deur gebruik te maak van hierdie tegnieke poog die studie om te toets of diversifikasie en rekombinasie van PVY rasse plaasgevind het binne die tydsbestek van die inburgering en moderne verbouing van aartappels. Van hierdie ontledinge word afgelei dat rekombinante rasse van PVY wat in Suid-Afrika voorkom, ingevoer is.

Reticulate phylogenetic analysis

Potato virus Y

Virus diseases of plants -- South Africa

Dissertations -- Biochemistry

Theses -- Biochemistry

Biochemistry

Vliv biotického stresu na metabolismus sacharidů rostlin tabáku (Nicotiana tabacum L.) / The effect of biotic stress on the metabolism of saccharides in tobacco plants (Nicotiana tabacum L.)

Kloudová, Kateřina

January 2012

Plants have developed a number of ways how to minimise negative influence of the environment. As a consequence of stress action, plants carbohydrate metabolism is quite often influenced, esp. on the level of expression and activities of different enzymes and also several metabolites concentration. One of key enzymes of carbohydrate metabolism is invertase. The aim of this work was to find out, whether the activity of its isoforms (cytoplasmic, vacuolar and extracellular) in tobacco plants is influenced by Potato virus Y (PVY). It was shown, that activity of cytoplasmic invertase was not affected, but the activity of vacuolar and extracellular isoform was enhanced during potyviral infection. Hence, it is likely, that vacuolar and extracellular invertases are related to plant antiviral defence. The effect of PVY on other enzymes of carbohydrate metabolism and several metabolites content was studied. Activity of α-amylase and phosphorylase, starch-degrading enzymes, was strongly enhanced during potyviral infection. That is probably how plant cells get glucose, which is a key source of energy and metabolites for biosynthesis of different compounds. It may also serve as a signal molecule. Activity of other hydrolytic enzymes, β-glucosidase and β-hexosaminidase, was also slightly increased. There was no...

Development of a pepper (Capsicum annuum L.) hybrid variety with resistance to potato virus Y (PVY) using molecular breeding.

Moodley, Vaneson.

03 June 2014

Pepper (Capsicum annuum L.) is an important vegetable crop grown and consumed worldwide. Potato virus Y (PVY) is a globally economically important pathogen which significantly reduces the yield and quality of cultivated pepper. The virus is considered as a major limiting factor to the economic production of pepper in the province of KwaZulu-Natal (KZN) in the Republic of South Africa (RSA). Many applied practices to control the spread of PVY are ineffective to mitigate the losses incurred by many farming communities across the KZN province. Therefore, the objectives of this study was to determine the full genome sequence of a PVY isolate from KZN, to identify resistance alleles in commercially available pepper varieties in KZN and to develop a pepper hybrid variety with resistance to PVY using a molecular breeding strategy The first part of the study was conducted to determine the first full genome sequence of a PVY isolate (JVW-186) infecting pepper from KZN. The complete genome sequence of JVW-186 was assembled from overlapping RT-PCR clones using MEGA 5 software. Individual ORFs were identified using the nucleotide data base NCBI and aligned using CLUSTALW. RDP4 software was used to identify recombination junctions in the sequence alignment of JVW-186. CLC Main Workbench 6 software was used to determine the nucleotide sequence similarity of recombinant and non-recombinant fragments of JVW-186 in conjunction with ten PVY parental isolates. Based on sequence data, virus morphology and the coat protein size as determined by SDS-PAGE analysis, the identity of the isolate JVW-186 was confirmed as PVY. Phylogenetic trees were constructed from all recombinant and non-recombinant segments of the sequence by the maximum likelihood method using MEGA 5 software. The full length sequence of JVW-186 consisted of 9700bp. Two ORF’s were identified at position 186 and 2915 of the sequence alignment encoding the viral polyprotein and the frameshift translated protein P3N-PIPO, respectively. RDP4 software confirmed two recombination breakpoints at position 343 and 9308 of the sequence resulting in four segments of the genome. At each recombination event, a 1021-bp fragment at the 5’ end in the region of the P1/HC-Pro protein and a 392-bp fragment in the region of the coat protein shared a high sequence similarity of 91.8 % and 98.89 % to the potato borne PVYC parental isolate PRI-509 and the PVYO parental isolate SASA-110 respectively. The non-recombinant fragment 1 clustered within the C clade of PVY isolates; however the large 7942-bp fragment 3 did not cluster within any of the clades although it shared > 80% nucleotide sequence similarity to other PVY isolates used in this study. Our results suggest that isolate JVW-186 is a novel recombinant strain of PVY that could have evolved due to the dynamics of selection. The second part of the study aimed to evaluate different pepper lines for resistance to PVY. Two recessive alleles (pvr21 and pvr22) located on the pvr2-elF4E locus are known to confer resistance to the virus. To this end, six pepper lines were challenged with PVY infected Nicotiana tabacum cv. Xanthi leaf material using mechanical inoculation under greenhouse conditions. Each line was assessed for resistance to PVY by visual screening for disease severity and quantitative enzyme linked immunosorbent assay (ELISA) for virus load. Pepper lines were further characterized using tetra-primer ARMS-PCR (amplification refractory mutation system polymerase chain reaction) to identify and differentiate the presence of homozygous/heterozygous resistance alleles that confer PVY resistance. Evaluations revealed two resistant pepper lines (Double Up and Cecelia) and varying levels of susceptibility in the other four pepper lines challenged with PVY. The most susceptible pepper line was Benno, although high levels of susceptibility were observed in three other lines (IP, Mantenga and Excellence). The pvr2+ allele was positively identified in all the susceptible pepper lines using the T200A tetra-primer which confirms that the presence of this allele is dominant for PVY susceptibility. Double Up and Cecelia were genotyped homozygous pvr21/pvr21 and pvr22/pvr22 respectively, and remained asymptomatic throughout the trial which indicates that these alleles confer resistance to the isolate of PVY used in this study. The information generated in this study can be incorporated into breeding programs intended to control PVY on pepper in KZN. The final part of the study focused on the development of resistant varieties as the best alternative to manage PVY diseases on pepper. Homozygous F2 pepper lines were developed from local germplasm carrying PVY resistance genes (pvr21 and pvr22) using marker assisted selection (MAS). The F1 progeny was obtained by crossing a homozygous pvr21 (resistant) ‘Double Up’ cultivar with a heterozygous susceptible (pvr2+/pvr22) ‘Benno’ cultivar. F1 and F2 generations were assessed for the presence of PVY resistance/susceptibility alleles (pvr2+/pvr21/pvr22) at the pvr2-elF4e locus using the tetra primer amplification refractory mutation system – polymerase chain reaction (ARMS-PCR) procedure. Negative selection was carried out using the tetra-primer T200A marker to detect the pvr2+ (susceptible) allele. All F1 progeny displaying the pvr2+ allele were eliminated from further study. All 302 plants belonging to 29 F2 families expressing homozygous recessive traits were tested via mechanical inoculation for their response to PVY infection and resistance to PVY was confirmed in all selected families based on symptomatology in greenhouse house screens using double antibody sandwich enzyme linked immunosorbent assay (DAS-ELISA). These results show that ARMS-PCR can be used to successfully screen pepper genotypes for alleles that confer PVY resistance thereby contributing to the improvement of pepper production using molecular breeding approaches. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2013.

Peppers--Varieties--KwaZulu-Natal.

Potato virus Y--KwaZulu-Natal.

Peppers--Breeding--KwaZulu-Natal.

Theses--Plant pathology.

Vliv přítomnosti proteinu Hsp70 na infekci způsobenou Y virem bramboru / The effect of Hsp70 protein on the infection caused by Potato virus Y

Doričová, Vlasta

January 2014

Whithin their natural environment, plants are subjected to a combination of stress conditions. Since potential interactions between signal pathways, plants respond to multiple stresses differently from how they do to individual stresses, activating a specific programme. Heat shock proteins (HSP70) overexpressed after heat shock influence the viral infection. On one side HSP70 can participate on refolding of aggregated or partially denaturated proteins, on the other side HSP70 can interact with viral proteins and facilitate propagation of viral replication complexes. In this work the effect of heat shock (42řC, 2. hours) applied before or after the inoculation of plants Nicotiana tabacum L. cv. Petit Havana SR1 with Potato virus Y on viral infection was detected. This effect was studied in two biological experiments. The amount of coat protein of PVYNTN and protein HSP70 were detected simultaneously with the activity assays of Hatch-Slack cycle enzymes, glycosidases and peroxidase. Both experimental approaches (heat shock applied before or after the inoculation by PVYNTN ) enhanced amount of the virus and in the 2nd experiment it accelerated infection development. Immediately after application of heat shock the amount of HSP70 was increased. The enhancement of HSP70 by viral infection occurred...

Characterization of potato virus Y (PVY) isolates infecting solanaceous vegetables in KwaZulu-Natal (KZN), Republic of South Africa (RSA)

Ibaba, Jacques Davy.

January 2009

Potato virus Y (PVY) is an economically important virus worldwide. In South Africa, PVY has been shown to be a major limiting factor in the production of important solanaceous crops, including potato (Solanum tuberosum L.), pepper (Capsicum annuum L.), tomato (Lycopersicon esculentum Mill.) and tobacco (Nicotiana spp). The variability that PVY displays, wherever the virus occurs, merits the study of the isolates occurring in KwaZulu-Natal (KZN) in the Republic of South Africa (RSA). This characterization will provide a clear understanding of strains/isolates from local vegetables and how they relate to the other PVY strains already identified, as well as information that can be used to manage the diseases they cause. Hence, the aim of this project was to study the biological and genetic properties of PVY isolates infecting potato, tomato and pepper in KZN. Enzyme-linked immunosorbent assay (ELISA) using monoclonal antibodies and reverse transcription polymerase chain reaction (RT-PCR) using primers specific to all PVY strains were used to detect the virus in plant material showing PVY-like symptoms collected from various locations in KZN. A total of 39 isolates (18 isolates infecting tomato, 12 infecting potato and 9 infecting pepper) were further differentiated into strains by means of ELISA using strain specific antibodies and RT-PCR using primers specific to the different strains of PVY identified around the world. All PVY isolates infecting tomato and pepper tested positive for the ordinary PVYO strain with both ELISA and RT-PCR. PVY isolates infecting potato were more diverse and comprised the PVYN, PVYNTN and PVYNWilga strains, with mixed infections noted in some cases. The biological properties were studied by mechanically inoculating Chenopodium quinoa, Nicotiana tabacum cv Xanthi, N. tabacum cv Samsun, N. glutinosa, and N. rustica with leaf extracts from plants infected with the different PVY strains detected in this study. All inoculated C. quinoa plants did not show symptoms. All tobacco plants showing symptoms were tested for the presence of PVY by means of ELISA using monoclonal antibodies targeting all strains and electron microscopy using the leaf dip technique. Not all the inoculated tobacco tested positive with ELISA. The symptoms observed were therefore divided into PVY-related and PVY non- related. PVY-related symptoms included vein clearing, mosaic chlorosis, stunting, and vein necrosis. PVY non-related symptoms included wrinkles and leaf distortions. Potyvirus-like particles of about 700 nm were observed under the transmission electron microscope (TEM) from plants showing PVY-related symptoms while rod shaped viral particles of sizes varying between 70 and 400 nm were observed from plants showing non-PVY related symptoms. A portion of the virus genome (1067 bp) covering part of the coat protein gene and the 3’ non-translated region (NTR) of three PVYO isolates infecting tomato, one PVYO isolate infecting pepper and one PVYNWilga isolate infecting potato were amplified, cloned and sequenced. The 5’ NTR, P1, HC-Pro and part of P3 regions (2559 bp) of a PVYN isolate infecting potato were also amplified, cloned and sequenced. Sequence data was compared with selected PVY sequences from different geographical locations around the world. These were available on the NCBI website and subsequently used for phylogenic analyses. The sequenced genomic regions of the PVYN isolate were found to be 99% similar to the New Zealand PVYN isolate (GenBank accession number: AM268435), the Swiss PVYN isolate CH605 (X97895) and the American PVYN isolate Mont (AY884983). Moreover, the deduced amino acid sequence comparison of the genomic regions of the PVYN isolate revealed the presence of five distinct amino acids residues. The three amino acid residues (D205, K400, and E419), which determine the vein necrosis phenotype in tobacco, were also identified. The coat protein and 3’ NTR sequences of all KZN PVYO isolates infecting pepper and tomato were closely similar to each other than to KZN PVYNWilga isolate infecting potato. The phylogenic analysis clustered the KZN PVYN isolate with the European sublineage N, PVYNWilga isolate infecting potato with the American PVYO isolate Oz (EF026074) in the O lineage and all PVYO isolates infecting tomato and pepper in a new sublineage within the O lineage. Taken together, these results point to the presence of PVY in solanaceous vegetables cultivated in KZN and they lay the foundation for the formulation of effective control measure against PVY diseases in KZN. / Thesis (M.Sc.) - University of KwaZulu-Natal, Pietermaritzburg, 2009.

Potato virus Y--KwaZulu-Natal.

Plant molecular virology.

Plant viruses--Genetics.

Plant viruses--Genetics.

Virus diseases of plants--Diagnosis.

Viruses--Isolation.

Solanaceae--Diseases and pests.

Theses--Plant pathology.