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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Molecular characterisation of the intergenic regions of banana bunchy top virus

Herrera Valencia, Virginia Aurora January 2006 (has links)
Banana bunchy top virus (BBTV) is a circular, single-stranded (css) DNA virus that belongs to the genus Babuvirus in the family Nanoviridae. BBTV is responsible for the most devastating virus disease of banana known as "bunchy top", for which conventional control measures are generally ineffective. Genetically engineered resistance appears to be the most promising strategy to generate BBTV-resistant bananas but the success of this strategy is largely dependent upon the molecular characterisation of the target virus and knowledge of the virus life cycle, particularly the replication strategy. This PhD study was aimed at the molecular characterisation of the intergenic regions of BBTV, in order to complement the molecular information currently available and to potentially contribute to the development of transgenic resistance strategies against BBTV in banana. Three putative iterative sequences (iterons; GGGAC) previously identified in the BBTV intergenic regions were initially characterised. In order to determine their role in the binding of the master BBTV replication initiation protein (M-Rep), the putative iterons (F1 and F2 in the virion sense, and R in the complementary sense) were independently mutated in a BBTV DNA-6 greater-than-genome-length clone (1.1 mer). The DNA-6 1.1 mers (native and mutants) and the M-Rep-encoding component (DNA-1) were co-bombarded into banana (Musa spp. cv."Lady finger") embryogenic suspension cells and transient replication was evaluated by Southern hybridisation. Analysis of the DNA-6 replicative forms showed a significant decrease of approximately 41% for the F1 iteron mutant and 61% for the R iteron mutant in comparison with native levels. However, the mutation in the F2 iteron caused the most dramatic effect, decreasing replication to levels barely detectable by Southern hybridisation. These results suggest that the three iterons all play a role in BBTV replication, most likely as recognition and binding sites for the M-Rep, but that the F2 iteron appears to be the most important in replication. Following the observation that all BBTV isolates sequenced to date have identical iteron sequences, the extent to which the M-Rep would recognise, bind and initiate replication of heterologous components from geographically diverse BBTV isolates (the South Pacific and the Asian groups) was evaluated. Cross replication assays revealed that heterologous M-Reps from Fiji, Hawaii (South Pacific group) and Vietnam (Asian group) were able to initiate replication of the coat protein-encoding component (DNA-3) from the Australian BBTV isolate (South Pacific group). However, replication of DNA-3 from the Vietnamese isolate was not initiated by heterologous M-Reps from the two South Pacific isolates tested (Australia and Hawaii). These results suggest that a broad-range transgenic resistance strategy based on replication using Australian BBTV intergenic regions may be successful as this region will be recognised by the M-Reps from both Asian and South Pacific BBTV isolates. However, a Rep protein-mediated resistance strategy will more likely be specific to geographical isolates and, therefore, less suitable as a broad-range control strategy. To further characterise the BBTV intergenic regions and to gain a better understanding of the BBTV transcription process, the 5' untranslated regions (UTRs) of the major open reading frames (ORFs) associated with each of the six BBTV DNA components were mapped. In all cases, the transcription start sites were located 3' of a putative TATA box and the 5' UTRs varied in length from 23 nucleotides (DNA-6) to 5 nucleotides (DNA-3). Two potential transcription start sites (nt 84 and 87) were mapped for DNA-1, but whether these represent the transcription start sites of the two genes associated with DNA-1 remains to be determined. Two start sites were also associated with DNA-2 which is thought to be monocistronic. Whether one of these start sites is an artefact or whether they are due to natural sequence variability of BBTV is unknown. These results now enable us to define the transcribed regions of each BBTV DNA component and accurately predict their promoter regions in an attempt to gain a fundamental understanding of BBTV gene expression patterns.
2

Development of a Rep-inducible, BBTV-based expression system in banana

Bolton, Clair Louise January 2009 (has links)
Banana bunchy top is regarded as the most important viral disease of banana, causing significant yield losses worldwide. The disease is caused by Banana bunchy top virus (BBTV), which is a circular ssDNA virus belonging to the genus Babuvirus in the family Nanoviridae. There are currently few effective control strategies for this and other ssDNA viruses. “In Plant Activation” (InPAct) is a novel technology being developed at QUT for ssDNA virus-activated suicide gene expression. The technology exploits the rolling circle replication mechanism of ssDNA viruses and is based on a unique “split” gene design such that suicide gene expression is only activated in the presence of the viral Rep. This PhD project aimed to develop a BBTV-based InPAct system as a suicide gene strategy to control BBTV. The BBTV-based InPAct vector design requires a BBTV intergenic region (IR) to be embedded within an intron in the gene expression cassette. To ensure that the BBTV IR would not interfere with intron splicing, a TEST vector was initially generated that contained the entire BBTV IR embedded within an intron in a β-glucuronidase (GUS) expression vector. Transient GUS assays in banana embryogenic cell suspensions indicated that cryptic intron splice sites were present within the IR. Transcript analysis revealed two cryptic intron splice sites in the Domain III sequence of the CR-M within the IR. Removal of the CR-M from the TEST vector resulted in an enhancement of GUS expression suggesting that the cryptic intron splice sites had been removed. An InPAct GUS vector was subsequently generated that contained the modified BBTV IR, with the CR-M (minus Domain III) repositioned within the InPAct cassette. Using transient histochemical and fluorometric GUS assays in banana embryogenic cells, the InPAct GUS vector was shown to be activated in the presence of the BBTV Rep. However, the presence of both BBTV Rep and Clink was shown to have a deleterious effect on GUS expression suggesting that these proteins were cytotoxic at the levels expressed. Analysis of replication of the InPAct vectors by Southern hybridisation revealed low levels of InPAct cassette-based episomal DNA released from the vector through the nicking/ligation activity of BBTV Rep. However, Rep-mediated episomal replicons, indicative of rolling circle replication of the released circularised cassettes, were not observed. The inability of the InPAct cassette to be replicated was further investigated. To examine whether the absence of Domain III of the CR-M was responsible, a suite of modified BBTV-based InPAct GUS vectors was constructed that contained the CR-M with the inclusion of Domain III, the CR-M with the inclusion of Domain III and additional upstream IR sequence, or no CR-M. Analysis of replication by Southern hybridisation revealed that neither the presence of Domain III, nor the entire CR-M, had an effect on replication levels. Since the InPAct cassette was significantly larger than the native BBTV genomic components (approximately 1 kb), the effect of InPAct cassette size on replication was also investigated. A suite of size variant BBTV-based vectors was constructed that increased the size of a replication competent cassette to 1.1 kbp through to 2.1 kbp.. Analysis of replication by Southern hybridisation revealed that an increase in vector size above approximately 1.5 - 1.7 kbp resulted in a decrease in replication. Following the demonstration of Rep-mediated release, circularisation and expression from the InPAct GUS vector, an InPAct vector was generated in which the uidA reporter gene was replaced with the ribonuclease-encoding suicide gene, barnase. Initially, a TEST vector was generated to assess the cytotoxicity of Barnase on banana cells. Although transient assays revealed a Barnase-induced cytotoxic effect in banana cells, the expression levels were sub-optimal. An InPAct BARNASE vector was generated and tested for BBTV Rep-activated Barnase expression using transient assays in banana embryogenic cells. High levels of background expression from the InPAct BARNASE vector made it difficult to accurately assess Rep-activated Barnase expression. Analysis of replication by Southern hybridisation revealed low levels of InPAct cassette-based episomal DNA released from the vector but no Rep-mediated episomal replicons indicative of rolling circle replication of the released circularised cassettes were again observed. Despite the inability of the InPAct vectors to replicate to enable high level gene expression, the InPAct BARNASE vector was assessed in planta for BBTV Rep-mediated activation of Barnase expression. Eleven lines of transgenic InPAct BARNASE banana plants were generated by Agrobacterium-mediated transformation and were challenged with viruliferous Pentalonia nigronervosa. At least one clonal plant in each line developed bunchy top symptoms and infection was confirmed by PCR. No localised lesions were observed on any plants, nor was there any localised GUS expression in the one InPAct GUS line challenged with viruliferous aphids. The results presented in this thesis are the first study towards the development of a BBTV-based InPAct system as a Rep-activatable suicide gene expression system to control BBTV. Although further optimisation of the vectors is necessary, the preliminary results suggest that this approach has the potential to be an effective control strategy for BBTV. The use of iterons within the InPAct vectors that are recognised by Reps from different ssDNA plant viruses may provide a broad-spectrum resistance strategy against multiple ssDNA plant viruses. Further, this technology holds great promise as a platform technology for the molecular farming of high-value proteins in vitro or in vivo through expression of the ssDNA virus Rep protein.
3

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

Tsao, Theresa Tsun-Hui January 2008 (has links)
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.

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