Global ETD Search

11	RNA interference mediated virus resistance in transgenic wheat Rupp, Jessica Lynn Shoup January 1900 (has links) Doctor of Philosophy / Plant Pathology / John P. Fellers / Harold N. Trick / Wheat streak mosaic virus (WSMV) and Triticum mosaic virus (TriMV) are two viruses affecting wheat in the Great Plains region of the United States. Genetic resistance is severely limited, requiring management methods focusing on the deployment of resistant varieties and various cultural practices. Evaluation of resistance is complicated by the lack of a standard rating scale. The objective of this work was to develop new avenues to mitigate these challenges. A standardized virus symptom rating scale was developed using historical Kansas rating scales, and validated using multiple wheat populations. Two independent RNA interference (RNAi) expression vectors targeting portions of viral coat protein (CP) of WSMV and TriMV were previously transformed into wheat. T₂ plants and beyond were evaluated using PCR, reverse transcription-PCR and bioassays in which plants were challenged with their respective virus. These lines were evaluated for resistance through the T₆ generation. Crosses were made with the susceptible winter wheat cultivars, ‘Overley’ and ‘Karl 92.’ Real-time PCR results show viral titer was up to 20-fold lower in the T₆ transgenic lines, the F₁, and the BC₁F₁ compared to control plants. This provides evidence that this RNAi silencing method is stable in wheat over multiple generations. WSMV and TriMV use host eukaryotic initiation factors (eIF) in order to facilitate replication of their genomes. Previously created RNAi expression vectors were derived from the sequences of the wheat genes eIF(iso)4E-2 and eIF4G. Evaluation of these lines began in the T₁ generation. Resistance has been demonstrated in three lines of eIF(iso)4E-2 and four lines of eIF4G, derived by single seed descent. T₆ progeny co-infected with WSMV and TriMV continue to be resistant. Crosses have been performed with the winter wheat ‘Karl 92’ and three Kansas elite lines, KS030887K-6, KS09H19-2-3, and KS10HW78-1-1. RNAi construct effectiveness was evaluated using real-time PCR. Results show up to 18-fold reduction in viral titer in the transgenic lines, the F₁, and the BC₁F₁ in comparison to control plants. This research provides the first evidence that a single host transgene can provide resistance to multiple viruses and has great potential benefits to both breeders and producers. Transgenic wheat Virus resistance Host gene silencing Pathogen derived resistance RNA Interference Virus rating scale Plant Pathology (0480)
12	Comparisons biological, and molecular serology between isolated from Cowpea aphid-borne mosaic virus, resistance source for identification and virus interactions between species in Vigna unguiculata / ComparaÃÃes biolÃgicas, sorolÃgicas e moleculares entre isolados de Cowpea aphid-borne mosaic virus, identificaÃÃo de fonte de resistÃncia e interaÃÃes entre espÃcies de vÃrus em Vigna unguiculata Laianny Morais Maia 30 January 2015 (has links) Conselho Nacional de Desenvolvimento CientÃfico e TecnolÃgico / Passion fruit (Passiflora edulis) and cowpea (Vigna unguiculata) are important crops of economical impact for the Northeast of Brazil. Fruit woodiness is an important virus disease of passion fruit, caused by Passionfruit woodiness virus (PWV) and Cowpea aphid-borne mosaic virus (CABMV), both from the genus Potyvirus. CABMV is also responsible for important disease on cowpea. The present research had the objective to study and compare the biological, serological and molecular properties of isolates of CABMV obtained from passion fruit (CABMV-P Pet, CABMV-P Gua, CABMV-P Sb and CABMV-P Uba) and from cowpea (CABMV-C Fort and CABMV-C Bv). CABMV-C Fort and CABMV-C Bv were purified from infected cowpea cv. Pitiuba systemically infected. The obtained purified preparations presented concentrations of 16.4 mg of virus per mL (CABMV-C Bv) and 15.9 mg of virus per mL (CABMV-C Fort). Both purified virus preparations were used for rabbit immunizations to produce polyclonal antisera with reactive titers of 1:128.000 in PTA-ELISA. Electrophoresis analyses of the virus purified preparations revealed the presence of only one capsidial protein with molecular weight of 34 kDa for both virus isolates. Parts of the genomes, corresponding to the coat protein gene (cp), from the virus isolates obtained from cowpea and from passion fruit were amplified by RT-PCR. The philogenetic analyses of the amplified cDNA fragments grouped with the CABMV isolates sequences deposited in the GenBank, according to their original host. Based on the biological, serological and molecular results, the virus isolates studied were classified into two biotypes: Biotype Cowpea (CABMV-C) including CABMV-C Bv and CABMV-C Fort obtained from cowpea, and biotype Passion fruit (CABMV-P) including CABMV-P Pet, CABMV-P Gua, CABMV-P Sb and CABMV-P Uba obtained from passion fruit. Source of immunity to CABMV-C Bv and CABMV-C Fort was identified in cowpea and the genotype was designate Lab-Poty. Studies of virus interaction in cowpea demonstrated strong synergistic effect among CABMV-C, Cucumber mosaic virus (CMV) and Cowpea severe mosaic virus (CPSMV). / O maracujazeiro (Passiflora edulis) e o feijoeiro caupi (Vigna unguiculata) sÃo culturas de elevada importÃncia econÃmica para o Nordeste brasileiro. Entre as viroses que se manifestam no maracujazeiro, destaca-se o endurecimento dos frutos causado por Passionfruit woodiness virus (PWV) e Cowpea aphid-borne mosaic virus (CABMV), ambos pertencentes ao gÃnero Potyvirus, sendo o CABMV responsÃvel por importante doenÃa do feijoeiro caupi. A presente pesquisa teve como objetivo estudar e comparar as propriedades biolÃgicas, sorolÃgicas e moleculares de isolados de CABMV obtidos de maracujazeiro (CABMV-P Pet, CABMV-P Gua, CABMV-P Sb e CABMV-P Uba) e isolados obtidos de feijoeiro caupi (CABMV-C Fort e CABMV-C Bv). Os isolados CABMV-C Fort e CABMV-C Bv foram purificados a partir de plantas de feijoeiro caupi cv. Pitiuba sistemicamente infetadas. As preparaÃÃes purificadas obtidas apresentaram concentraÃÃes de 16,4 mg de vÃrus por mL (CABMV-C Bv) e 15, 9 mg de vÃrus por mL (CABMV-C Fort), as quais foram usadas na imunizaÃÃo de coelhos, para a produÃÃo de antissoros policlonais, com tÃtulo de 1:128.000 em PTA-ELISA. AnÃlises eletroforÃtica das preparaÃÃes virais revelaram uma Ãnica proteÃna capisidial com peso molecular de 34 kDa. Partes do genoma correspondente ao gene da capa protÃica (cp) dos isolados virais obtidos de feijoeiro caupi e de maracujazeiro foram amplificadas por RT-PCR. AnÃlises filogenÃticas dos fragmentos dos cDNA amplificados se agruparam com sequencias de isolados do CABMV depositadas no GenBank, de acordo com os hospedeiros originais. Com base nos resultados de estudos biolÃgicos, sorolÃgicos e moleculares, os isolados virais estudados foram classificados em dois biÃtipos: BiÃtipo Cowpea (CABMV-C) incluindo CABMV-C Bv and CABMV-C Fort obtidos de feijoeiro caupi e biÃtipo Passion fruit (CABMV-P) incluindo CABMV-P Pet, CABMV-P Gua, CABMV-P Sb e CABMV-P Uba obtidos de maracujazeiro. Fontes de imunidade a CABMV-C Bv e CABMV-C Fort foi identificada em feijoeiro caupi e o genÃtipo foi designado de Lab-Poty. Estudos de interaÃÃo viral em feijoeiro caupi, mostraram forte sinergismo entre CABMV-C, Cucumber mosaic virus (CMV) e Cowpea severe mosaic virus (CPSMV). CABMV Potyvirus ProduÃÃo de antissoro AnÃlises moleculares Fonte de resistÃncia CABMV Potyvirus Antiserum production Virus molecular analyses Source of virus resistance FITOPATOLOGIA
13	Genome and Transcriptome Based Characterization of Low Phytate Soybean and Rsv3-Type Resistance to Soybean Mosaic Virus Redekar, Neelam R. 31 August 2015 (has links) Soybean is a dominant oilseed cultivated worldwide for its use in multiple sectors such as food and feed industries, animal husbandry, cosmetics and pharmaceutical sectors, and more recently, in production of biodiesel. Increasing demand of soybean, changing environmental conditions, and evolution of pathogens pose challenges to soybean production in limited acreage. Genetic research is the key to ensure the continued growth in soybean production, with enhanced yield and quality, while reducing the losses due to diseases and pests. This research is focused on the understanding of transcriptional regulation of two economically important agronomic traits of soybean: low seed phytic acid and resistance to Soybean mosaic virus (SMV), using the 'transcriptomics' and 'genomics' approaches. The low phytic acid (lpa) soybean is more desirable than conventional soybean, as phytic acid is an anti-nutritional component of seed and is associated with phosphorus pollution. Despite the eco-friendly nature of the lpa soybean, it shows poor emergence, which reduces soybean yield. This research is mainly focused on addressing the impact of lpa-causing mutations on seed development, which is suspected to cause low emergence in lpa soybeans. The differences in transcriptome profiles of developing seeds in lpa and normal phytic acid soybean are revealed and the biological pathways that may potentially be involved in regulation of seed development are suggested. The second research project is focused on Rsv3-type resistance, which is effective against most virulent strains of Soybean mosaic virus. The Rsv3 locus, which maps on to soybean chromosome 14, contains 10 genes including a cluster of coiled coil-nucleotide binding-leucine rich repeat (CC-NB-LRR) protein-encoding genes. This dissertation employed a comparative sequencing approach to narrow down the list of Rsv3 gene candidates to the most promising CC-NB-LRR gene. The evidence provided in this study clearly indicates a single CC-NB-LRR gene as the most promising candidate to deliver Rsv3-type resistance. / Ph. D. Seed development Phytic acid Soybean mosaic virus resistance Rsv3 Co-expression network
14	Molecular Analysis of Turnip Crinkle Virus Coat Protein Mutations Zhan, Ye 30 April 2002 (has links) TCV (Turnip crinkle virus) coat protein is required for the resistance response in Arabidopsis thaliana Di-17 plants. An aspartate to asparagine mutation at amino acid four of the coat protein is sufficient to result in resistance-breaking. To determine the essential chemical properties responsible for the induction of resistance, a series of site-directed mutants were produced. Serine as well as asparagine at amino acid four induces systemic disease on both Di-3 and Di-17 plants; however, replacement of aspartate with glutamate retains the ability to induce the HR (hypersensitive response) and resist TCV infection with rapid and strong induction of PR-1 gene. These data suggest that the negative charge at the fourth amino acid of the coat protein is critical for the induction of resistance. Taken together with other mutagenesis research, the N-terminus of the coat protein appears to be the sole viral recognition element. The A. thaliana TIP protein is suggested to be involved in resistance, mainly through its C-terminus. Interestingly, one of the resistance-breaking mutants (D4N) produces a HR on Di-3 plants that are normally susceptible. The Di-3 TIP protein has several differences from the Di-17 TIP. To detect whether the delayed HR is related to interaction between Di-3 TIP and D4N mutation, a yeast two-hybrid assay was attempted. Interactions have not yet been detected. There are a number of possible explanations. protein interaction coat protein resistance arabidopsis turnip crinkle virus Plants Virus resistance Plant-pathogen relationships Genetic aspects Arabidopsis thaliana Turnip crinkle virus
15	Transgenic resistance against Citrus tristeza virus (CTV) and analysis of the viral p23 protein as pathogenicity determinant in citrus Soler Calvo, Nuria 02 September 2013 (has links) El virus de la tristeza de los cítricos (Citrus tristeza virus; CTV) es el agente causal de unas de las enfermedades virales de los árboles cítricos más devastadoras en el mundo. CTV está restringido al floema en su huésped cítrico natural, y ha desarrollado tres proteínas supresoras de silenciamiento que actúan a nivel intra-(p23 y p20) e intercelular (p20 y p25) para superar la fuerte defensa antiviral del huésped. La interferencia de RNA, una aproximación basada en el uso de dsRNA para desencadenar el silenciamiento de RNA, ha sido utilizada ampliamente para generar plantas transgénicas resistentes a virus. Considerando el importante papel de p23, p20 y p25 en la patogénesis de CTV, hemos transformado plantas de lima Mexicana con un vector intrón-horquilla que porta la secuencia completa en versión no traducible de los genes p25, p20, p23 y el extremo 3¿-UTR de la cepa T36 de CTV, para intentar silenciar su expresión en células infectadas. Se ha observado resistencia completa a la infección viral en tres líneas transgénicas, manteniéndose todas sus propagaciones asintomáticas y libres de virus tras ser inoculadas mediante injerto con CTV-T36, tanto en el portainjertos no transgénico como directamente sobre la variedad transgénica. La acumulación de siRNA derivados del transgén fue necesaria pero no suficiente para lograr resistencia frente a CTV en las plantas. Al inocular propagaciones de las líneas transgénicas inmunes con una cepa de CTV divergente, la resistencia fue parcialmente superada, destacando la importancia de la identidad de secuencia en el mecanismo subyacente a la interferencia de RNA. Este trabajo es el primero en que se consigue resistencia completa a CTV en un huésped cítrico muy sensible, actuando simultáneamente sobre los tres supresores virales de silenciamiento mediante interferencia de RNA. La proteína p23 codificada por el virus es además un importante factor de patogenicidad. La expresión ectópica de p23 en plantas de cítricos induce aberraciones fenológicas semejantes a síntomas de CTV. Para estudiar en más detalle el papel de p23 en la patogénesis de CTV, se ha sobre-expresado en lima Mexicana el gen p23 de CTV T36 y tres versiones truncadas del mismo bajo el control del promotor 35S del virus del mosaico de la coliflor (Cauliflower mosaic virus). Solo la versión truncada, que expresa los aminoácidos del 1 al 157 (p23-¿157) indujo síntomas similares a los producidos por CTV, aunque más suaves que los inducidos por la expresión de la proteína p23 entera (209 aminoácidos), permitiendo delimitar la región responsable de la patogénesis de p23 en cítricos a un fragmento de 157 aminoácidos que incluye el dedo de zinc y los motivos básicos flanqueantes de la proteína. La actividad de p23 como supresor de silenciamiento de RNA en N. benthamiana se perdía en todos los mutantes de p23 probados, lo cual indica que la supresión de silenciamiento implica a la mayoría de las regiones de la proteína. Para profundizar más en el papel de p23 en la patogénesis, en un siguiente paso hemos restringido la expresión de transgenes derivados de p23 a células asociadas al floema de lima Mexicana mediante el uso del promotor especifico de floema del virus del moteado amarillo de la comelina (Commelina yellow mottle virus, CoYMV). Se transformó lima Mexicana con construcciones que portaban el gen p23 completo, ya sea de la cepa agresiva de CTV T36 o de la suave T317, o con un fragmento que comprende el dedo de zinc y los motivos básicos flanqueantes de la primera, todas ellas bajo el control bien del promotor de CoYMV o bien del promotor constitutivo 35S. La expresión de estas construcciones en el floema dio lugar a aberraciones semejantes a los síntomas específicos de CTV, pero no a los síntomas inespecíficos observados cuando se expresaba p23 de forma constitutiva. Por otra parte, la apariencia e intensidad de las aberraciones fenotípicas más notorias similares a síntomas inducidos por CTV generadas por la expresión específica en floema del gen p23 se relacionó positivamente con la agresividad de la cepa origen utilizada. Además, la expresión en tejidos floemáticos del fragmento de p23 que comprende el dominio de dedo de zinc y los motivos básicos flanqueantes fue suficiente para inducir síntomas semejantes a los producidos por la infección con CTV, confirmando así que la región N-terminal delimitada por los aminoácidos 1 y 157 podría determinar, al menos en parte, la patogénesis de CTV en lima Mexicana. / Citrus tristeza virus (CTV) is the causal agent of one of the most devastating viral diseases of citrus trees in the world. CTV is phloem-restricted in natural citrus hosts, and has evolved three silencing suppressor proteins acting at intra- (p23 and p20) and inter-cellular level (p20 and p25) to overcome strong host antiviral defense in citrus. RNA interference (RNAi), an approach based on using dsRNA to trigger RNA silencing, has been widely used for generating transgenic plants resistant against viruses. Considering the important role of p23, p20 and p25 in CTV pathogenesis, we have transformed Mexican lime plants with an intron-hairpin vector carrying full untranslatable versions of genes p25, p20, p23 and the 3¿-UTR from the CTV strain T36, to attempt silencing their expression in CTV-infected cells. Complete resistance to viral infection was observed in three transgenic lines, with all their propagations remaining symptomless and virus-free after graft-inoculation with CTV-T36, either in the non-transgenic rootstock or directly in the transgenic scion. Accumulation of transgene-derived siRNAs was necessary but not sufficient for CTV resistance. Challenging immune transformants with a divergent CTV strain resulted in partial breakage of the resistance, stressing the importance of sequence identity in the underlying RNAi mechanism. This is the first evidence that it is possible to achieve full resistance to CTV in a highly sensitive citrus host by targeting simultaneously its three viral silencing suppressors through RNAi. The p23 protein encoded by the virus is additionally an important pathogenicity factor. Ectopic expression of p23 in transgenic citrus plants induces developmental aberrations resembling CTV symptoms. To explore in more detail the role of p23 in CTV pathogenesis, the p23 gene from CTV T36 and three truncated versions thereof under the control of the Cauliflower mosaic virus 35S promoter were used to transform Mexican lime. Only the truncated version expressing amino acids 1 to 157 (p23¿158-209) elicited CTV-like symptoms, similar to, albeit milder than, those incited by expressing the whole p23 protein (209 amino acids), thus delimiting the region responsible for p23 pathogenesis in citrus to a 157 amino acid fragment including the Zn finger and flanking basic motifs of the protein. RNA silencing suppressor activity of p23 in N. benthamiana was abolished by all mutants tested, indicating that silencing suppression involves most p23 regions. To better define the role of p23 in CTV pathogenesis, we next restricted the expression of p23-derived transgenes to phloem-associated cells in Mexican lime plants by means of using the phloem-specific promoter from Commelina yellow mottle virus (CoYMV). Constructions carrying the complete gene p23 from either the severe T36 or the mild T317 CTV strains, or a fragment comprising the zinc-finger and flanking basic motifs from the former, either under the control of the CoYMV promoter or the constitutive 35S promoter were used for genetic transformation of Mexican lime. Expression of these constructs in the phloem incited aberrations resembling CTV-specific symptoms, but not the unspecific symptoms observed when p23 was constitutively expressed. Moreover, appearance and intensity of the most notorious CTV-like phenotypic aberrations induced by the phloem-specific expression of the p23 gene were positively related with the aggressiveness of the source CTV strain used. Additionally, expression in phloem-tissues of the p23 fragment comprising the zinc-finger domain and flanking basic motifs was sufficient to induce CTV-like symptoms, corroborating that the N-terminal region (delimited by amino acids 1 and 157) determines, at least in part, CTV pathogenesis in Mexican lime. / Soler Calvo, N. (2013). Transgenic resistance against Citrus tristeza virus (CTV) and analysis of the viral p23 protein as pathogenicity determinant in citrus [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/31631 / TESIS Transgenic citrus RNA interference RNA silencing suppressor Antiviral defence Virus resistance Closterovirus Intron-hairpin Small interfering RNAs Phloem-specific expression Virus symptoms.
16	Plant-Pathogen Interactions: Turnip Crinkle Virus Suppression of the Hypersensitive Response in Arabidopsis thaliana Christopher, Stephen James 29 April 2003 (has links) The presence of turnip crinkle virus (TCV) in Arabidopsis thaliana plants has previously been shown to suppress the ability of these plants to produce a hypersensitive response (HR) upon inoculation with pathogens that would normally elicit this defense response. The ecotype Colombia-0 was examined using wildtype TCV and non-pathogenic strains of Pseudomonas syringae pv. glycinea Race 4 containing virulence genes avrRpt2, avrRpm1 and avrRps4. Transgenic lines of A. thaliana that express the TCV proteins p8, p9 or CP were also examined in an attempt to determine if these proteins play a role in suppression of the HR. Crosses of these transgenic lines were made in order to determine if binary combinations of these proteins were sufficient for HR suppression. In addition, assays were completed to determine if the inhibition of the HR correlated with suppression of resistance to the virulent Pseudomonas syringae pv. maculicola ES4236 avrRpt2 growth in the plant. Finally, PR-1 protein expression was inspected by visual and quantitative GUS reporter gene assays to determine if TCV also played a role in inhibition of the plants ability to develop systemic acquired resistance (SAR). Turnip crinkle virus arabidopsis thaliana TCV avrRpt2 avrRpm1 avrRps4 systemic acquired resistance resistance plant disease susceptability PR-1 transgenics avirulence virulence Avr gene R gene pseudomonas syringae. Plants Virus resistance Turnip crinkle virus Arabidopsis
17	Molecular characterization of Tobacco rattle virus proteins involved in pathogenicity / Molecular characterization of Tobacco rattle virus proteins involved in pathogenicity Ghazala, Walid 24 May 2007 (has links) No description available. 000 Allgemeines Wissenschaft Agricultural Sciences Tobravirus Kartoffeln virus-resistenz RNA silencing suppressor proteins Kernlokalisationsignale Tobravirus Solanum tuberosum spraing virus-resistance RNA silencing suppressor proteins nuclear localization signal 42.32 WUZ 500: Virologie Virus {Mikrobiologie}
18	Isolation and molecular characterisation of tomato spotted wilt virus (TSWV) isolates occuring in South Africa. Sivparsad, Benice. January 2006 (has links) Tomato spotted wilt virus (TSWV), a Tospovirus, is one of the ten most economically destructive plant viruses worldwide, causing losses exceeding one billion U.S. dollars annually on several crops. In South Africa (SA), TSWV has become an important virus in many economically important crops. The main objective of this research project was to isolate, identify and characterise TSWV isolates occurring in SA. A review of current literature assembled background information on TSWV molecular biology, epidemiology, transmission, detection and control. A TSWV isolate infecting pepper (Capsicum sp.) occurring in KZN was isolated and partially characterised. The virus was positively identified as TSWV using the enzyme-linked immunosorbent assay (ELISA) and the presence of typical necrotic TSWV symptoms on Nicotinia rustica L. Symptomatic leaves were harvested and the virus was partially purified using standard procedures. Under the transmission electron microscope (TEM), typical quasi-spherical and dumbbell-shaped particles of 80-100nm in diameter were observed in negatively stained preparations of both crude and purified virus samples. In negatively stained ultra-thin virus infected leaf sections, an abundance of mature viral particles (100nm) housed in the cisternae of the endoplasmic reticulum (ER) were observed among typical viroplasm inclusions (30nm) and hollow tubules (200-300nm). A viral protein migrating as a 29kDa band, which corresponds to the TSWV nucleocapsid (N) protein, was observed after sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) analysis. Total plant RNA, isolated from N. rustica displaying typical symptoms was subjected to reverse-transcription polymerase chain reaction (RT-PCR) using .primers specific to the nucleocapsid (N) gene. An expected 760bp product was amplified. The results obtained in this study confirm the presence of TSWV in infected pepper plants from KZN. The genetic diversity of TSWV isolates occurring in SA was examined. The nucleocapsid (N) gene sequences of six SA TSWV isolates originating from Gauteng, KwaZulu-Natal, North West, Limpopo and Mpumulanga provinces were determined and used in a phylogenetic tree comparison with TSWV isolates occurring in different geographical locations in the world. Nucleotide sequence comparisons of the N gene revealed high levels of similarity between the SA isolates and TSWV isolates from Asia and Europe. SA isolates showed a high degree of sequence similarity (99-100%) which was reflected in their distinct clustering pattern. The resistance of tomato (Lycopersicon escuJentum Mill.) plants with natural and transgenic resistance against mechanical inoculation with TSWV isolates occurring in SA was evaluated. The Stevens cultivar which has natural resistance conferred by the Sw-5 gene and the transgenic 13-1 line, which expresses the nucleocapsid (N) protein gene of the TSWV-BL isolate, was used as test cultivars. Plants were assessed for TSWV resistance using a disease severity rating scale and measurements of virion accumulation levels (A405nm). There were no significant differences among the reactions produced by the six TSWV isolates on the test plants. Although both plants were susceptible to the SA TSWV isolates by exhibiting similarly high viral accumulation levels, the transgenic tomato line showed milder disease severity compared to the natural resistant cultivar. Results suggest that transgenic resistance is a more effective approach in the control of TSWV in SA. The information generated in this study will be useful in formulating effective control measures using genetic engineering approaches for this economically important virus. Such approaches will be used as a tool to make strategic decisions in an integrated control programme for ISWV. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2006. Viruses--Isolation. Virus resistant transgenic plants. Bunyaviruses. Plants--Virus resistance. Plant molecular virology. Theses--Plant pathology.
19	The development of transgenic sweet potato (Ipomoea batatas L.) with broad virus resistance in South Africa. Sivparsad, Benice. 20 November 2013 (has links) Sweet potato (Ipomoea batatas Lam.) is ranked as the seventh most important food crop in the world and its large biomass and nutrient production give it a unique role in famine relief. However, multiple virus infection is the main disease limiting factor in sweet potato production worldwide. The main objective of this research project was to develop a transgenic sweet potato cultivar with broad virus resistance in South Africa (SA). A review of current literature assembled background information pertaining to the origin, distribution and importance of the sweet potato crop; viruses and complexes infecting sweet potato; and the strategies used in sweet potato virus detection and control. A survey to determine the occurrence and distribution of viruses infecting sweet potato (Ipomoea batatas Lam.) was conducted in major sweet potato-growing areas in KwaZulu-Natal (KZN). A total of 84 symptomatic vine samples were collected and graft inoculated onto universal indicator plants, Ipomoea setosa Ker. and Ipomoea nil Lam. Six weeks post inoculation, typical sweet potato virus-like symptoms of chlorotic flecking, severe leaf deformation, stunting, chlorotic mosaic, and distinct interveinal chlorotic patterns were observed on indicator plants. Under the transmission electron microscope (TEM), negatively stained preparations of crude leaf sap and ultra-thin sections from symptomatic grafted I.setosa plants revealed the presence of elongated flexuous particles and pinwheel type inclusions bodies‟ that are characteristic to the cytopathology of Potyviruses. Symptomatic leaf samples from graft-inoculated I. setosa and I. nil were assayed for Sweet potato feathery mottle virus (SPFMV), Sweet potato mild mottle virus (SPMMV), Sweet potato chlorotic stunt virus (SPCSV), Sweet potato chlorotic fleck virus (SPCFV), Sweet potato virus G (SPVG), Sweet potato mild speckling virus (SPMSV), Sweet potato caulimo-like virus (SPCaLV), Sweet potato latent virus (SPLV), Cucumber mosaic virus (CMV), and Sweet potato C-6 virus (C-6) using the nitrocellulose membrane enzyme-linked immunosorbent assay (NCM-ELISA). The majority of leaf samples (52%) tested positive for virus disease and showed the occurrence of SPFMV, SPMMV, SPCSV, SPCFV, SPVG, SPMSV, and SPCaLV. Of these 7 viruses, the most frequently detected were SPFMV (39%), SPVG (30%), followed by SPCSV (13%) and SPMMV (12%). SPCaLV and SPCFV at 10% and SPMSV at 7% were found exclusively in samples collected from one area. SPFMV, SPVG, SPCSV, and SPMMV were identified as the most prevalent viruses infecting sweet potato in KZN. The genetic variability of the three major viruses infecting sweet potato (Ipomoea batatas Lam.) in KZN was determined in this study. A total of 16 virus isolates originating from three different locations (Umbumbulu, Umfume and Umphambanyomi River) in KZN were analyzed. These comprised of 10 isolates of Sweet potato feathery mottle virus (SPFMV), five isolates of Sweet potato virus G (SPVG) and one isolate of Sweet potato chlorotic stunt virus (SPCSV). The phylogenetic relationships of the SPFMV, SPVG and SPCSV isolates from KZN relative to isolates occurring in SA and different parts of the world were assessed. The division of SPFMV into four genetic groups (strains) according to the phylogenetic analysis of coat protein encoding sequences revealed mixed infections of the O (ordinary) and C (common) strains in sweet potato crops from KZN. All SPFMV isolates showed close lineage with isolates from South America, East Asia and Africa. The SPVG isolates showed high relatedness to each other and close lineage with other isolates, especially those from China and Egypt. Analysis of the partial sequence of the Heat shock protein 70 homologue (Hsp70h) gene indicated that the SPCSV isolate from KZN belongs to the West African (WA) strain group of SPCSV and showed close relatedness to an isolate from Argentina. The knowledge of specific viral diversity is essential in developing effective control measures against sweet potato viruses in KZN. Multiple virus infections of Sweet potato feathery mottle virus (SPFMV), Sweet potato chlorotic stunt virus (SPCSV), Sweet potato virus G (SPVG) and Sweet potato mild mottle virus (SPMMV) cause a devastating synergistic disease complex of sweet potato (Ipomoea batatas Lam.) in KZN. In order to address the problem of the multiplicity and synergism of sweet potato viruses in KZN, this study aimed to develop transgenic sweet potato cv. Blesbok with broad virus resistance. An efficient and reproducible plant regeneration protocol for sweet potato (Ipomoea batatas Lam.) cultivar Blesbok was also developed in this study. The effect of different hormone combinations and type of explants on shoot regeneration was evaluated in order to optimize the regeneration protocol. Coat protein (CP) gene segments of SPFMV, SPCSV, SPVG and SPMMV were fused to a silencer DNA, the middle half of the nucleocapsid (N) gene of Tomato spotted wilt virus (TSWV) and used as a chimeric transgene in a sense orientation to induce gene silencing in the transgenic sweet potato. Transformation of apical tips of sweet potato cv. Blesbok was achieved by using Agrobacterium tumefaciens strain LBA4404 harboring a modified binary vector pGA482G carrying the plant expressible neomycin phosphotransferase ll gene (nptll), the bacterial gentamycin-(3)-N-acetyl-transferase gene and the expression cassette. A total of 24 putative transgenic plants were produced from the transformed apical tips via de novo organogenesis and regeneration into plants under 50mg/L kanamycin and 200 mg/L carbenicillin selection. Polymerase chain reaction (PCR) and Southern blot analyses showed that six of the 24 putative transgenic plants were transgenic with two insertion loci and that all plants were derived from the same transgenic event. The six transgenic sweet potato plants were challenged by graft inoculation with SPFMV, SPCSV, SPVG and SPMMV- infected Ipomoea setosa Ker. Although virus presence was detected using NCM-ELISA, all transgenic plants displayed delayed and milder symptoms, of chlorosis and mottle of lower leaves when compared to the untransformed control plants. These results warrant further investigation under field conditions. / Thesis (Ph.D.)-University of KwaZulu-Natal, Pietermaritzburg, 2013. Sweet potatoes--Breeding--South Africa. Virus diseases of plants--South Africa. Virus-resistant transgenic plants. Plants--Virus resistance. Theses--Plant pathology.

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