Citrus tristeza virus: characterization of Texas isolates, studies on aphid transmission and pathogen-derived control strategies

Herron, Caroline Mary

15 November 2004

Citrus tristeza virus (CTV), an economically important graft-transmissible pathogen of citrus, causes major global declines in citrus production. In the commercial citrus of the Lower Rio Grande Valley of Texas (LRGV), where red grapefruit on tristeza-decline sensitive sour orange rootstocks predominate, incidence of CTV is low. The efficient CTV vector, the brown citrus aphid (BrCA, Toxoptera citricida Kirkaldy) is now established in Mexico and Florida, thus information is needed on the severity of CTV, CTV aphid transmission and the performance of transformed citrus towards CTV before T. citricida arrives in Texas so that appropriate management strategies can be selected. Biological indexing and molecular typing were performed on fifteen Texas CTV isolates. The majority of the CTV isolates tested contained the most severe CTV types known. In Florida, T. citricida were fed on crude CTV preparations in vitro and could transmit CTV to virus-free receptor plants with two CTV isolates, whereas a more highly purified CTV preparation from one CTV isolate was not transmitted by T. citricida. There were no differences in the majority of treatments in infectivity neutralizations using three CTV-derived antibodies (p25, p27 and p20). CTV p20 antibodies significantly enhanced the occurrence of CTV transmission in one test. The CTV genome of isolate H33 was sequenced using 'shot gun' methods. The H33 major component and H33 minor components were phylogenetically compared to the six other full-length CTV sequences. An untranslatable CTV coat protein gene was genetically transformed into the genome of the Texas commercial Rio Red grapefruit variety, and fifty-two independent transgenic lines were produced. CTV challenge responses by the transgenic lines were variable. Individual plants could be identified which had low virus titers by ELISA detection, a temporal decrease in virus titer, or a delay in virus titer accumulation. Comparing all wild types to all transgenic lines over every assessment revealed significant decreases in virus titer in the transgenic lines compared to that of the wild type. An RNA entity with similarities to marafiviruses was identified in a CTV infected plant. The entity appears non-graft transmissible to citrus, and non-mechanically transmissible to a range of herbaceous species.

Citrus tristeza virus

Toxoptera citricida

the brown citrus aphid

transgenic citrus

pathogen-derived resistance

marafiviruses

Development of a novel rep-inducible tomato leaf curl virus expression system

Williams, Brett Robert

January 2007

Pathogen-derived resistance (PDR) strategies, particularly those based on post-transcriptional gene silencing, have been used with great success for the generation of transgenic plants with resistance to RNA viruses. In contrast, a suitable strategy for transgenic resistance to ssDNA plant viruses, including those viruses belonging to the Geminiviridae, has remained elusive. Further, there is no convincing evidence that either post-transcriptional gene silencing, or pathogen-derived resistance in general, would be broadly applicable to ssDNA plant viruses. Researchers at QUT have been developing a novel resistance strategy against ssDNA viruses based on virus-activated expression of a stably integrated suicide gene. The strategy, based on InPAct (In Plant Activation) technology, relies on a &quotsplit" suicide gene cassette being arranged in such a way that expression of a lethal ribonuclease (barnase) is dependent on the virus-encoded replication-associated protein (Rep). Upon infection, Rep mediates the release of the construct resulting in the reconstitution of a transcribable and translatable episomal suicide gene expression cassette. The research for this PhD describes the development of an InPAct vector designed to confer resistance to Tomato leaf curl begomovirus (ToLCV), a major cause of disease in Solanaceous crops in the tropics and subtropics. ToLCV-based InPAct vectors were constructed based upon two ToLCV isolates from Australia and North Vietnam. Prior to the generation of InPAct cassettes, the entire ToLCV-[Au] and ToLCV-Vie intergenic regions (IRs) were embedded within the castorbean catalase intron of a β-glucuronidase expression vector to determine the effect of the IR upon transcript processing. Using transient reporter gene assays in tobacco NT-1 cells, it was demonstrated that the ToLCV IRs both contained cryptic intron splice sites which interfered with efficient transcript processing and GUS expression. A series of truncations to the IRs were subsequently made to identify the potential cryptic intron splice sites and/or interfering sequences in both the ToLCV-[Au] and ToLCV-Vie IRs. The final truncated IRs, which were used in the construction the InPAct cassettes, comprised approximately 100 bp and appeared to contain all the necessary cis-acting elements required for efficient rolling circle replication (RCR). Using histochemical GUS assays and Southern analyses, the InPAct cassettes were shown to be activated and replicated only in the presence of the cognate viral Rep. GUS expression levels were shown to be further enhanced in the presence of the ToLCV replication-enhancer protein (REn) and by the addition of the Tobacco yellow dwarf mastrevirus origin of second strand synthesis into the cassette. Under these conditions, Rep-activated GUS expression from the InPAct vectors was found to reach levels similar to that of the benchmark CaMV 35S promoter. Fifteen independent transgenic lines containing the ToLCV-[Au] and -Vie InPAct-GUS cassettes were generated by Agrobacterium-mediated transformation of tobacco leaf discs. Using agroinfiltration and histochemical assays, Rep-mediated activation of the InPAct cassettes and subsequent GUS expression was demonstrated in 11 out of the 15 lines tested; six of which showed expression levels equivalent to, or higher than, that obtained using a CaMV 35S promoter control. Evidence for activation of the integrated InPAct cassettes at the molecular level was provided by Southern analyses, with showed both linear and open circular forms of the replicating InPAct episome in genomic DNA extracted from infiltrated leaf tissue. Following the demonstration of Rep-activatable reporter gene expression and episomal replication of the ToLCV-based InPAct-GUS vectors using transient and stable tobacco transformation assays, new ToLCV-based InPAct vectors were designed to express the lethal RNase, barnase, in an attempt to generate virus resistant plants. Although transient assays in NT-1 cells demonstrated some &quotleaky" expression of barnase from the InPAct vectors, the level of barnase-mediated cell death from the InPAct vectors was found to be significantly increased in the presence of the cognate Rep and REn. Thirteen independently transformed tobacco lines containing the ToLCV-[Au] InPAct-barnase cassette were generated by Agrobacterium-mediated transformation of tobacco leaf discs. However, agroinfiltration of these plants with ToLCV Rep and REn failed to activate a barnase response. Subsequent molecular analyses on two transgenic lines revealed that both contained mutations in the barnase-coding gene in a region known to encode the active site. These mutations were presumed to result from the leaky barnase expression during initial stages of the Agrobacterium transformation which would favour the selection of barnase mutant InPAct plants. To overcome the problems associated with leaky expression of barnase, a barstar-expression cassette was included in the ToLCV-[Au] InPAct-barnase cassette. Transient assays in non-transgenic tobacco leaves demonstrated that the basal levels of barstar expressed from the modified InPAct vector were sufficient to negate the effects of leaky barnase expression. Importantly, however, the level of barnase expression in the presence of Rep and REn was shown to be sufficient to overcome the basal levels of barstar. Seventeen independently transformed lines were generated with the ToLCV-[Au] InPAct-barnase/barstar cassette, and analysis of one line revealed the presence of an uncorrupted barnase-coding region. Using transient agroinfiltration assays, seven of the transgenic lines showed varying levels of cognate Rep and REn-activated, barnase-induced cell death. Fifteen transgenic lines were challenged with ToLCV-[Au] by injection of recombinant Agrobacteria containing an infectious ToLCV clone. Unfortunately, all lines displayed typical ToLCV symptoms and tested positive for virus by PCR at 28 days post-inoculation. The inability of the InPAct cassette to confer resistance to ToLCV may have been due to one or a combination of factors, including (i) a delay in barnase-induced cell death, (ii) homology-dependent silencing of the integrated cassette, (iii) generally low-level, Rep-activated barnase expression or (iv) excessive virus load due to the artifical method of inoculation. This study details the first report of a ToLCV-based InPAct system for Rep-induced transgene expression in planta. Despite failing to generate ToLCV-resistant plants, the research findings will provide a solid foundation to develop a more effective InPAct vector and ultimately assist in the generation of transgenic plants with resistance to ToLCV and potentially other ssDNA plant viruses, particularly the begomoviruses.

pathogen-derived resistance (PDR)

tomato leaf curl virus

replication-association protein (Rep)

begomoviruses

Evaluation of two pathogen-derived resistance strategies for Grapevine leafroll-associated virus 3

Suidgeest, Faira

04 1900

Thesis (MSc)--Stellenbosch University, 2015. / ENGLISH ABSTRACT: Grapevine leafroll disease (GLD), caused by the members of the family Closteroviridae, is one of the most economic important viral diseases affecting grapevine. Grapevine leafroll associated virus 3 (GLRaV-3), of the genus Ampelovirus, is the most widespread member of the leafroll associated virus family. To prevent the spread of GLD, management strategies such as rogueing and insect vector control are required to limit crop losses. Alternative control strategies based on genetic modification of the grapevine genome, such as pathogen-derived resistance (PDR), is proven to be effective in conferring resistance to several viruses. Therefore, the focus of this study was to evaluate pathogen-derived resistance strategies for GLRaV-3 using the following two approaches; 1) evaluation of transgenic plants expressing a dysfunctional GLRaV-3 heat shock protein 70 homolog (HSP70h) in order to confer resistance against GLRaV-3, and 2) the construction of artificial microRNAs (amiRNAs) to use as a tool for silencing specific sequences of GLRaV-3 in the grapevine host and the development of an amiRNA-mediated silencing validation system. In the first part of this study, six transgenic plant lines (plant lines #1, #3, #9, #14, #15 and #17) as well as a non-modified plant line, were inoculated with GLRaV-3 by grafting buds of each onto GLRaV-3 infected plant material. After approximately five months, GLRaV-3 virus titres of all grafted plants were quantified relative to two reference genes using RT-qPCR. Results were evaluated by comparing the relative virus titre of each transgenic plant line to that of the non-modified control plant line. Results showed that resistance levels of plant line #3 was significantly enhanced (>99%) and remarkably, plant line #14, showed to be more susceptible to the virus. The second part of the study was the construction and validation of amiRNAs targeting GLRaV-3 sequences. Two 21 nt regions of GLRaV-3 were successfully incorporated into miRNA backbone vvi167b of grapevine. Moreover, target constructs were developed by incorporating corresponding GLRaV-3 target sequences into the 3’ UTR of a green fluorescence protein (GFP) gene. Subsequently, the target constructs were co-infiltrated with the constructed amiRNA in Nicotiana benthamiana and GFP expression levels were quantified to determine the silencing efficiency of the amiRNAs. Results showed that the amiRNAs were successful in silencing the GFP target construct, however, they were not specific in silencing exclusively their corresponding target. These amiRNA constructs are ideal for further viral studies to determine the efficiency of silencing GLRaV-3 in GLD infected grapevines. / AFRIKAANSE OPSOMMING: Wingerd rolblaar siekte (GLD), wat veroorsaak word deur die lede van die familie Closteroviridae, is een van die ekonomies mees belangrike virus siektes van wingerd. Grapevine leafroll-associated virus 3 (GLRaV-3), van die genus Ampelovirus, is die mees wydverspreide lid van die rolblaar geassosieerde virus familie. Om die verspreiding van GLD te voorkom, is bestuur strategieë, soos die verwydering van geïnfekteerde plante en insekvektor beheer, ’n vereiste om oes verliese te beperk. Alternatiewe beheer strategieë gebaseer op genetiese modifikasie van die wingerdgenoom, soos patogeen-afgeleide weerstand (PDR), is bewys om effektief te wees in die verlening van weerstand teen verskeie virusse. Daarom was die fokus van hierdie studie om patogeen-afgeleide weerstand strategieë vir GLRaV-3 te evalueer met behulp van die volgende twee benaderings; 1) die evaluering van transgeniese plante wat 'n disfunksionele GLRaV-3 hitte-skok proteïen 70 homoloog (HSP70h) uitdruk, ten einde weerstand te verleen teen GLRaV-3, en 2) die konstruksie van kunsmatige mikroRNAs (amiRNAs) om te gebruik as 'n instrument vir die ondrukking van spesifieke genoomvolgordes van GLRaV-3 in die wingerd gasheer en die ontwikkeling van ’n stelsel om amiRNA-bemiddelde onderdrukking te bevestig. In die eerste deel van hierdie studie, is ses transgeniese plant lyne (plant lyne # 1, # 3, # 9, # 14, # 15 en # 17) sowel as 'n nie-gemodifiseerde gesonde plant lyn, geïnokuleer met GLRaV- 3 deur enting van ogies van elk op GLRaV-3 besmette plantmateriaal. Na ongeveer vyf maande, is GLRaV-3 virus konsentrasies van alle ingeënte plante gekwantifiseer relatief tot twee verwysing gene deur gebruik te maak van tru-transkripsie kwantitatiewe PCR (RTqPCR). Resultate is geëvalueer deur die relatiewe virus konsentrasie van elke transgeniese plant lyn te vergelyk met dié van die nie-gemodifiseerde kontrole lyn. Resultate het getoon dat weerstand vlakke van plant lyn # 3 beduidend verbeter is (> 99%) en merkwaardig is plant lyn # 14 bewys om meer vatbaar vir die virus te wees. Die tweede deel van die studie was die konstruksie en bevestiging van kunsmatige mikroRNAs (amiRNAs) wat GLRaV-3 genoomvolgordes teiken. Twee 21 nt streke van GLRaV-3 is suksesvol geïnkorporeer in die ruggraat van wingerd mikroRNA vvi167b. Verder is teiken konstrukte ontwikkel deur die inkorporering van ooreenstemmende GLRaV-3 teiken genoomvolgordes in die 3'UTR (3’ ongetransleerde area) van 'n groen fluoressensie proteïen (GFP) geen. Daarna is die teiken konstrukte gesamentlik geïnfiltreer met die gekonstrueerde amiRNA in Nicotiana benthamiana en GFP uitdrukkingsvlakke is gekwantifiseer deur die onderdrukkingsdoeltreffendheid van die amiRNAs te bepaal. Resultate het getoon dat die amiRNAs suksesvol was in die onderdrukking van die GFP teiken konstruk, maar hulle was egter nie-spesifiek in die eksklusiewe onderdrukking van die ooreenstemmende teiken. Hierdie amiRNA konstrukte is ideaal vir verdere virus studies om die doeltreffendheid van GLRaV-3 onderdrukking in GLD besmette wingerdstokke te bepaal.

Grapevine leafroll virus

Grapes -- Disease and pest resistance

Pathogen-derived resistance

Virus diseases of plants

UCTD

Studies on Transformation of Tomato(Solanum lycopersicum L.) and Arabidopsis thaliana using Chimerical constructs of varying Tospoviral Origin

Cobb, Joshua Nathaniel

14 July 2008

Pathogen derived resistance (PDR) is a recent breakthrough where plant hosts can be made to be resistant to viral infections through transformation with conserved viral genes. Given the severity of Tospovirus diseases worldwide (particularly in tomato), PDR has the potential to garner large yield returns where pathogen populations have overcome the established resistance. Tomato breeding lines FLA7804, FLA8044, and the research line MP1 were used in transformation experiments with potions of the Tomato spotted wilt virus (TSWV) N-gene, and two other chimerical viral nucleocapsid gene constructs from, Impatiens necrotic spot virus (INSV), and Groundnut ringspot virus (GRSV). We conducted 19 independent transformations consisting of 300 to 700 14-day old whole cotyledons each for a total number of approximately 9,000 potentially transformed explants. Of those, approximately 6,300 explants failed to produce regenerants, 2,419 explants underwent abnormal development on elongation media, 187 failed to root, and 215 plants to be characterized genetically. Of the 215 plants, 9 were from FLA 7804, 96 from FLA 8044, and 110 from MP1. Both PCR and Southern blot hybridization analysis later confirmed that none of the 215 plants were transgenic. Opposite to tomato, we were able to transform Arabidopsis thaliana ecotype wassilewskija (Ws) via floral dip with the above listed constructs demonstrating that constructs were not deleterious within a plant once fully introgressed. Sixteen independent transformants in the T0 generation resulted from 19,000 germinated seed from three dipped plants resulting in a total transformation rate of 0.08%. Of the 1,000 T1 seed germinated on kanamycin media from each of the 16 putative Arabidopsis plants transformed with the construct containing elements of the N-gene from all three of the aforementioned tospoviruses, four populations exhibited simple Mendelian inheritance of the transgene. DNA walking analysis yielded amplification of the unknown region outside the nptII region of the insert for three of the four remaining transformants, which was subsequently sequenced and mapped to chromosomes 1, 3, and 4. There were 25 T1 individuals selected from each population and transferred to soil for DNA extraction and zygosity determination. Homozygous T2 seed was collected for future resistance studies.

tomato

TSWV

Tospovirus

pathogen derived resistance

PDR

plant transformation

Solanum lycopersicum

Arabidopsis thaliana

Animal Sciences

RNA interference mediated virus resistance in transgenic wheat

Rupp, Jessica Lynn Shoup

January 1900

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)

Towards the development of transgenic banana bunchy top virus (BBTV)-resistant banana plants : interference with replication

Tsao, Theresa Tsun-Hui

January 2008

Banana bunchy top virus (BBTV) causes one of the most devastating diseases of banana. Transgenic virus resistance is now considered one of the most promising strategies to control BBTV. Pathogen-derived resistance (PDR) strategies have been applied successfully to generate plants that are resistant to numerous different viruses, primarily against those viruses with RNA genomes. BBTV is a circular, single-stranded (css) DNA virus of the family Nanoviridae, which is closely related to the family Geminiviridae. Although there are some successful examples of PDR against geminiviruses, PDR against the nanoviruses has not been reported. Therefore, the aim of this thesis was to investigate the potential of BBTV genes to interfere with virus replication when used as transgenes for engineering banana plants resistance to BBTV. The replication initiation protein (Rep) of nanoviruses is the only viral protein essential for viral replication and represents an ideal target for PDR. Therefore, this thesis focused on the effect of wild-type or mutated Rep genes from BBTV satellite DNAs or the BBTV integral genome on the replication of BBTV in banana embryogenic cell suspensions. A new Rep-encoding satellite DNA, designated BBTV DNA-S4, was isolated from a Vietnamese BBTV isolate and characterised. When the effect of DNA-S4 on the replication of BBTV was examined, it was found that DNA-S4 enhanced the replication of BBTV. When the replicative capabilities of DNA-S4 and the previously characterised Rep-encoding BBTV satellite, DNA-S1, were compared, it was found that the amount of DNA-S4 accumulated to higher levels than DNA-S1. The interaction between BBTV and DNA-S1 was also examined. It was found that over-expression of the Rep encoded by DNA-S1 using ubi1 maize polyubiquitin promoter enhanced replication of BBTV. However, when the Rep-encoded by DNA-S1 was expressed by the native S1 promoter (in plasmid pBT1.1-S1), it suppressed the replication of BBTV. Based on this result, the use of DNA-S1 as a possible transgene to generate PDR against BBTV was investigated. The roles of the Rep-encoding and U5 genes of BBTV DNA-R, and the effects of over-expression of these two genes on BBTV replication were also investigated. Three mutants of BBTV DNA-R were constructed; plasmid pUbi-RepOnly-nos contained the ubi1 promoter driving Rep expression from DNA-R, plasmid pUbi-IntOnly-nos contained the ubi1 promoter driving expression of the DNA-R internal gene product (U5), while plasmid pUbi-R.ORF-nos contained the ubi1 promoter driving the expression of both Rep and the internal U5 gene product. The replication of BBTV was found to be significantly suppressed by pUbi-RepOnly-nos, weakly suppressed by pUbi-IntOnly-nos, but strongly enhanced by pUbi-R.ORF-nos. The effect of mutations in three conserved residues within the BBTV Rep on BBTV replication was also assessed. These mutations were all made in the regions in the ATPase motifs and resulted in changes from hydrophilic to hydrophobic residues (i.e. K187→M, D224→I and N268→L). None of these Rep mutants was able to initiate BBTV replication. However, over-expression of Reps containing the K187→M or N268→L mutations significantly suppressed the replication of BBTV. In summary, the Rep constructs that significantly suppressed replication of DNA-R and -C in banana embryogenic cell suspensions have the potential to confer resistance against BBTV by interfering with virus replication. It may be concluded that BBTV satellite DNAs are not ideal for conferring PDR because they did not suppress BBTV replication consistently. Wild-type Rep transcripts and mutated (i.e. K187→M and N248→L) Rep proteins of BBTV DNA-R, however, when over-expressed by a strong promoter, are all promising candidates for generating BBTV-resistant banana plants.