Global ETD Search

71	Comparative studies on tomato aspermy and cucumber mosaic viruses Habili, Nooredin. January 1974 (has links) (PDF) Includes bibliographical references (leaves 108-123). Includes the paper: Stabilization of capsid structure and enhancement of immunogenicity of cucumber mosaic virus (Q strain) by formaldehyde / by R.I.B. Franki and N. Habili, originally published in Virology, v. 48, no. 2, 1972 The comparative studies carried out suggest that tomato aspermy virus and the Q strain of cucumber mosaic virus are sufficiently similar to be included in the same taxonomic group. Nevertheless, the two viruses are distinct and the present nomenclature should be retained. Cucumber mosaic virus Genetics RNA viruses Genetics Cucumoviruses Viral genetics
72	Genetic studies of cucumber mosaic and tomato aspermy viruses Rao, Ayalasomayajula Lakshmi Naranya. January 1982 (has links) (PDF) Typescript (photocopy) Includes bibliographical references (leaves 84-94). Eight cucumovirus isolates were examined with respect to their host range, antigenic properties and nucleic acid composition. Cucumber mosaic virus Genetics RNA viruses Genetics Cucumoviruses Viral genetics
73	Genetic requirements for the assembly and cell-to-cell movement of the beet yellows virus Alzhanova, Dina 23 July 2004 (has links) Beet yellows virus (BYV) is a filamentous, positive-strand RNA virus that belongs to the family Closteroviridae. BYV particles encapsidate a 15.5 kb RNA and posses complex polar architecture. A long virion body is formed by the major capsid protein(CP), whereas the minor capsid protein (CPm) assembles a short tail that encapsidates the 5'-terminal region of BYV RNA. In addition to proteins required for viral RNA replication and encapsidation, BYV encodes four proteins whose role in the virus life cycle was unknown. These proteins include a small, 6-kDa, hydrophobic protein (p6), a homolog of the cellular 70-kDa heat shock proteins (Hsp7Oh), a 64-kDa protein (p64), and a 20-kDa protein (p20). It was found recently that Hsp7Oh, p64, and p20 are incorporated into BYV virions, and that Hsp7Oh is required for the virus movement from cell to cell. In this study, we characterized genetic requirements for BYV assembly and cell-to-cell movement, and determined relationships between these two processes. It was demonstrated that in addition to Hsp7Oh, p6, p64, CP, and CPm are each essential, but not sufficient for virus movement. These results indicated that five-component movement machinery of BYV is the most complex among plant viruses. Extensive mutational analysis of CP and CPm revealed strong correlation between abilities of BYV to assemble tailed virions and to move from cell to cell, suggesting that formation of functional virions is a prerequisite for virus translocation. We have found that CPm, Hsp7Oh, and p64 are necessary for the efficient virion tail formation. Assembly of the virion tails and bodies was shown to occur independent of each other and likely to involve two separate packaging signals within the genomic RNA. Our work demonstrated that BYV encodes one conventional movement protein, p6, whose only known function is to mediate virus movement. The other four movement associated proteins of BYV, CP, CPm, Hsp7Oh, and p64 are the virion components, each of which is required for assembly of the tailed, movement-competent virions. Based on these and other data, we propose that BYV and other closteroviruses evolved virion tails as a specialized device for the directional cell-to-cell movement of large RNA genomes. / Graduation date: 2005 / Best scan available. Beet yellows Plant viruses -- Genetics RNA viruses -- Reproduction Viruses -- Morphology
74	Multiple functions of a proteinase in closterovirus life cycle Peng, Chih-Wen 04 April 2002 (has links) More than half of the recognized genera of positive strand RNA viruses employ polyprotein processing as one of the strategies for their genome expression. Normally, this processing is mediated by virus-encoded proteinases that belong to the trypsin-like or papain-like family. In particular, papain-like, leader proteinases were found in diverse families of human, animal, plant, and fungal positive strand RNA viruses. In addition to autocatalytic processing, these proteinases play a variety of roles in the virus life cycle. In plant potyviruses, a papain-like helper component-proteinase (HC-Pro) was implicated in genome amplification, cell-to-cell movement, long distance transport, and suppression of host defense. The p29 proteinase encoded by a fungal hypovirus CHV1 was found to be dispensable for virus replication, but it was identified as a major determinant of viral pathogenicity. In an animal equine aterivirus (EAV), a papain-like proteinase nspl was demonstrated to possess a putative zinc finger domain, which functions in subgenomic RNA synthesis, although it is not essential for virus replication. The Lab proteinase of the foot and mouse disease virus (FMDV) is involved in inhibition of cellular mRNA translation and in virus spread in infected animals. In general, it appears that functional plasticity of the papain-like leader proteinases played an important role in the evolution of viral diversity. Here, we examined the functions of a papain-like leader proteinase (L-Pro) in the life cycle of the beet yellows closterovirus (BYV). It was found that L-Pro is required for autoproteolytic processing, genome amplification, virus invasiveness and cell-to-cell movement for BYV. The gene swapping experiments involving several closterviruses, a potyvirus, as well as CHV1, FMDV, and EAV revealed complex functional profiles of the papain-like leader proteinases. The possible mechanisms that underlie L-Pro functions are discussed. / Graduation date: 2002 Viral proteinases Papain RNA viruses -- Genetics Beet yellows
75	Pathogenic and molecular characterization of three closely related isolates of infectious pancreatic necrosis virus (IPNV) Bruslind, Linda D. 07 January 1997 (has links) Three closely related isolates belonging to the A�� serotype of infectious pancreatic necrosis virus (IPNV) were selected for comparison, to provide insight into the nature of variation in the virulence of IPN viruses. Brook trout fry (Salvelinus fontinalis) were experimentally infected with the three isolates by immersion. Cumulative mortalities over a 62 day period for the three isolates were 67%, 78%, and 93%. The negative control was 3%. Virus titers from whole fish homogenates sampled at peak mortality for each isolate were statistically similar, indicating that quantity of virus does not account for virulence differences. For the two least virulent isolates, the virus titer was inversely correlated with fish weight, whereas for the most virulent isolate, no correlation was observed. Amino acid sequences of the viral capsid protein VP2 were determined using the reverse transcriptase polymerase chain reaction (RT-PCR). There were two amino acid changes at residue 217 and 288 between the two least virulent isolates and the most virulent isolate. These changes might provide a specific molecular basis for the variations in virulence among isolates. The progression of IPN virus infection in the experimentally infected fry was followed using histopathology, in situ cDNA hybridization, and alkaline phosphatase immunohistochemistry (APIH). While microscopic lesions were limited almost exclusively to necrosis of the pyloric caeca and pancreas, positive reactions with in situ hybridization and APIH were observed in tissues throughout infected fish. An IPNV infection appeared to be established in the fish by two routes: by entering the skin/lateral line and diffusing through the muscle, and from the oral region into the gastrointestinal tract by ingestion. In a second experiment, within a group of experimentally infected brook trout fry, external and behavioral signs of IPN disease in moribund fish disappeared, with the fish becoming healthy in appearance. Several of these fish were sampled, along with dead, moribund, and asymptomatic fish (never showed signs of IPN disease). Very few differences were observed among the fish sampled, using histopathology and in situ hybridization. Fish that appeared to recover after displaying signs of IPN disease died within a 2 week period. / Graduation date: 1997 RNA viruses Fishes -- Virus diseases -- Pathogenesis Fishes -- Viruses
76	Search for protein-protein interactions underlying the cis-preferential replication of turnip yellow mosaic virus Wallace, S. Ellen 28 January 1997 (has links) Coreplication experiments have revealed that replication of turnip yellow mosaic virus (TYMV) RNA in turnip protoplasts is cis-preferential. Genomes encoding mutant p141 or p66, proteins essential for virus replication, were inefficiently rescued by a helper genome. One model for the cis-preferential replication of TYMV is that p66 and p141 form a complex that associates with the RNA from which they are translated, limiting their availability in trans. Three types of experiments were used in this study in an attempt to obtain physical evidence for the hypothetical interaction between p66 and p141. Immunoprecipitations from in vitro translation reactions using antiserum that recognizes p66 (and its progenitor, p206) coprecipitate p141, indicating that the proteins form a complex in vitro. The results of coimmunoprecipitations of translation products with in-frame deletions did not lead to definitive information about interaction domains. p66 and the helicase domain of p141 do not detectably interact in the yeast two-hybrid system or in GST fusion interaction assays. Problems with the expression of full length p141 fusions make conclusions about the interaction of other p141 domains with p66 not possible at this time. Since the helicase domain of p141 does not appear to interact with p66, future experiments will focus on obtaining expression of smaller domains of p141, outside the helicase domain, and determining if they interact with p66. Variations to the model that do not necessitate the direct interaction between p66 and p141 are also considered. / Graduation date: 1997 Turnip yellow mosaic virus -- Genetics RNA viruses -- Genetics
77	Analysis of Connections Between Host Cytoplasmic Processing Bodies and Viral Life Cycles Beckham, Carla Jolene January 2007 (has links) In the past few years, cytoplasmic processing bodies (P-Bodies) have been identified in eukaryotic cells. P-bodies have roles in translational repression, mRNA storage, mRNA decay and are conserved cytoplasmic aggregations of non-translating mRNAs in conjunction with translation repression and mRNA degradation factors. In this work, I, in collaboration with others provide evidence for a new biological role for P-bodies in viral life cycles. This work can be summarized thus:In a collaborative effort, I have identified connections between retrovirallike transposon life cycles and P-bodies. For example, genetic evidence in yeast indicates that key proteins within P-bodies are required for the life cycles of the Ty1 and Ty3 retrotransposons. Moreover, Ty3 genomic RNA (gRNA) as well as viral structural proteins accumulate in P-bodies, suggesting that P-bodies may serve as sites of viral assembly.Second, I have shown, with assistance of collaborators, that the positivestrand RNA virus, Brome Mosaic Virus (BMV) gRNA accumulates in P-bodies Moreover, viral RNA dependent RNA polymerase (RdRp) colocalizes with and co-immunoprecipitates with the P-body protein Lsm1p, suggesting that P-bodies may participate in viral replication. Remarkably, the accumulation BMV gRNA in P-bodies is dependent on cis-elements that have been demonstrated to play critical roles in viral RNA replication.The identification of P-bodies as sites of accumulation of viral gRNA and viral proteins of both retro-virus like elements and positive-stranded RNA viruses, expands the list of important biological roles played by P-bodies. Since P-body proteins and structure are highly conserved, these findings imply that Pbodies will be important for other RNA viruses. RNA viruses P-bodies Retrovirus cis-element replication complex
78	The roles of turnip yellow mosaic virus genes in virus replication Weiland, John J. 10 April 1992 (has links) Turnip yellow mosaic virus is a monopartite, plus sense RNA virus infecting the Cruciferae, and is a model system for the study of RNA virus replication. A cDNA clone (pTYMC) representing an infectious RNA genome of the European isolate of TYMV was constructed and used to assess the importance of virus genes in virus infectivity. Derivatives of pTYMC with alterations in open reading frame 69 (ORF- 69) were made. The mutations disrupted the expression of ORF-69 in vitro as predicted. Although the ORF-69 mutants were competent for replication in protoplasts, none of the mutants detectably infected turnip or Chinese cabbage plants, except where reversion mutations led to the restoration of an uninterrupted ORF-69. The data suggest a role for ORF-69 expression in the cell-to-cell movement of the virus. Mutant RNAs with a deletion or frameshift in the coat protein ORF infected protoplasts and plant leaves. No systemic infection symptoms were generated by these mutants, and no viral products were detected in young, expanding tissue of infected plants. When the coat protein deletion mutant and an ORF-69 mutant were co-inoculated onto plants, only a virus producing a coat protein of wild type size was detected in symptomatic, systemic tissue in these inoculations, emphasizing a requirement for the expression of native size coat protein for the systemic translocation of TYMV infection. The role of ORF-206 expression in TYMV replication was examined. Three classes of mutants were made in ORF-206: those affecting the synthesis of the 150 kDa protein, those affecting the synthesis of the 70 kDa protein, and those affecting the synthesis of both the 150 and the 70 kDa proteins. All ORF- 206 mutations eliminated RNA infectivity. Protoplast inoculations using mixtures of individual ORF-206 mutant RNAs and a helper genome demonstrated that co-replication of defective genomes could occur. Moreover, inoculations in which individual 150 kDa and 70 kDa protein mutant RNAs were combined showed that complementation between these two classes of mutants was possible. The data indicate that RNAs expressing wild type 150 kDa protein are favored replication substrates in mixed infections, and suggest that the 150 kDa protein functions preferentially in cis. / Graduation date: 1993 Turnip yellow mosaic virus -- Genetics RNA viruses -- Reproduction
79	Mechanisms of replication and genomic diversity in human caliciviruses Bull, Rowena, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW January 2007 (has links) Norovirus (NoV) and Sapovirus (SaV) are major causes of outbreak gastroenteritis worldwide. NoV and SaV are highly infectious, have multiple transmission routes and have a short incubation period, thereby facilitating rapid intercontinental spread of new variants. Consequently, a treatment would be advantageous for controlling them. However, currently little is known about the replication cycle and evolution of human NoV or SaV as neither are culturable. NoV and SaV are RNA viruses of the Caliciviridae family and have great genetic diversity which is thought to facilitate irnmune evasion. Consequently variants of NoV GI1.4 arose in 1996, 2002, 2004 and in 2006 and resulted in pandemics. Therefore, in this study, the role of the two main mechanisms associated with generating viral diversity; recombination, and point mutation were investigated for NoV and SaV. Physiological and kinetic properties of three NoV RdRps (genotypes, Gll.b, Gll.4, Gll.7) and two SaV RdRps (genogroups GI, GII) were also investigated. RNA recombination is a significant driving force in viral evolution. Increased awareness of recombination within the Calicivirus genus Norovirus (NoV) has led to a rise in the identification of NoV recombinants and they are now reported at high frequency. Despite this no classification system exists for recombinant NoVs As a result, there is duplication in reporting novel recombinants and the precise number of novel NoV recombinant types is unknown. Therefore, in order to elucidate thero!e of recombination in NoV evolution, 121 NoV nucleotide sequences, compiled from the GenBank database and published literature, were analysed for recombination events. NoV recombinants and their recombination breakpoint were identified using three methods: phylogenetic analysis, Simplot analysis and the Maximum Chi-Squared method. In total 19 unique NoV recombinant types were identified in circulation across the globe and they had a common recombination point near the ORF1/2 overlap. Recombination at the ORF1/0RF2 overlap could have important implications in NoV evolution as it enables a virus to swap its antigenic determinates (capsid) and thereby avoid immune clearance in an analogous manner to antigenic shift in influenza virus. This study also examined the role of NoV and SaV replication in generating viral diversity by comparing the physiological, kinetic and biochemical properties of five genotypically distinct RdRps from two different genera of the Caliciviridae. Genetically diverse HuCV RdRps were expressed in Escherichia coli and characterised in an in vitro assay designed for this study. The results indicated that despite high sequence variation between the five enzymes (between 6% and 71% amino acid difference) they shared similar physiological properties. Though there was some variation in their template usage and kinetic properties. SaV was able to perform primer dependent replication on homopolymeric A RNA whereas the NoV RdRps were not. Additionally, NoV RdRps had a higher incorporation rate and were more kinetically efficient than the two SaV RdRps. The incorporation fidelity of the five enzymes was similar (between 2.2x10-5 to 8.9x10-4 ), although interestingly the most prevalent strain, Gll.4, had the lowest fidelity of the caliciviruses. Therefore, suggesting that RdRp fidelity has an important role in NoV evolution. Overall, this study illustrated that NoV and SaV generate genetic diversity in a similar fashion to other RNA viruses, that is, a delicate combination of recombination, point mutation and replication efficiency. Understanding the mechanisms involved in viral replication and genomic diversity of the calicivirus RdRps is essential if a successful control strategy for the human caliciviruses is going to be developed. Viral gastroenteritis -- Diagnosis. Viral gastroenteritis. Viruses -- Reproduction. RNA viruses. Caliciviruses.
80	Further studies on the structure and function of the cucumber mosaic virus genome : a thesis submitted to the University of Adelaide, South Australia for the degree of Doctor of Philosophy / by Rhys Harold Verdon George Williams Williams, Rhys Harold Verdon George January 1988 (has links) Includes bibliographical references (leaves [102]-120). / 5, 120, [ca. 50] leaves, [3] leaves of plates : ill. ; 30 cm / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Studies the structure of the cucumber mosaic virus genome and the control of its expression. / Thesis (Ph.D.)--University of Adelaide, Dept. of Biochemistry, 1988 Cucumber mosaic virus Genetics. RNA viruses Genetics. Cucumoviruses. Viral genetics.

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