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An epidemiological study on the genetic relationships of foot-and-mouth disease viruses in East AfricaSahle, Mesfin 13 August 2008 (has links)
Within East African countries many of the known infectious diseases of animals occur commonly and are poorly controlled. Foot-and-mouth disease (FMD) is one of the contagious viral diseases that has great impact on economic development both in terms of direct and indirect losses. The epidemiology of the disease is complex due to the presence of six of the seven serotypes and the presence of large numbers of both wild and domestic susceptible animals in the region. Decision-making to determine the importance of FMD control relative to the economic consequences and what FMD control strategies should be applied based on the epidemiological information is required. In this regard the first step is to investigate the genetic relationships/variability of East African isolates and their phylogeographic distribution. These can provide base-line information for designing control strategies by vaccination as well as the determination of the sources of infection. Sufficient genetic information on the FMO serotypes O, SAT-1 and SAT-2 are lacking and therefore the number of viral Iineages and genotypes or topotypes from East African countries could not be determined. Published studies on the relative occurrence and genotype distribution of FMO are largely confined to the southern and western part of the continent. In this study, the genetic profile of the 3 most prevalent serotypes (0, SAT-2 and SAT-1) recovered from outbreaks in East Africa between 1957 and 2003 was addressed. Phylogenetic analysis of partial and complete sequences of the 10 gene revealed the presence of distinct lineages and genotypes for East Africa as well as historical relationships of some of the genotypes with isolates from other regions. A great variation in the occurrence and distribution of these serotypes were found. All the African and the Middle East/South East Asian isolates of serotype O included in this study clustered into one lineage having 8 distinct topotypes. These results indicated that between countries as well as inter-regional (east and west Africa) spread of viruses occurred in the past. Inter-regional spread of the virus between eastern Africa and western Africa was also confirmed for SAT-1 viruses. The fact that phylogenetic links are found with both serotypes implies that the spread of viruses was possibly associated with unrestricted animal movement due to nomadic movement in Africa. The phylogenetic relationships of SAT-1 viruses are more diversified in Africa. Eight lineages and 11 genotypes were identified when the optimal nucleotide sequence differences of ≥ 23% for lineages and ≥ 6% for genotypes were used as a cut-off values. It was observed that viruses from Uganda are evolving independently from viruses elsewhere on the continent and clustered into 3 discrete lineages. In contrast, viruses from countries neighbouring Uganda, Kenya and Tanzania, clustered into one lineage. Uganda also harboured 3 topotypes of SAT-2 virus isolates, one is distinct for Uganda and the other are shared with Kenya and Zaire (DRC). This study highlighted distinct lineages found in Uganda and needs further investigation. Within SAT-2, 67 isolates from 22 African countries and Saudi Arabia clustered into 5 lineages which consisted of 15 genotypes. Clustering of viruses into distinct genotypes (topotypes) according to year of isolation and geographical origin was observed showing countries with common boundaries shared common epizootics in the past. These results also showed a link between eastern and southern African countries. Attempts were also made to investigate the incidence of FMD in Ethiopia using sera collected from cattle, small ruminants and wildlife. The results obtained from the liquid phase blocking ELISA and the 3ABC ELISA indicated the presence of SAT-1 and SAT-2 in buffalo populations in the southern part of Ethiopia while results from small ruminants and other wildlife were not indicative of any significant role in the epidemiology of FMD. Serological results also indicated that SAT-1 is present in cattle, although this serotype has not been previously identified. The cumulative molecular epidemiological results from this and previous studies indicated that genetic variability of FMD viruses can be independently maintained within country/countries or regions as well as inter-regions of Africa. The serological results from buffaloes in East Africa are also suggestive of a possible reservoir of the SAT types FMD in the region which has a great impact on the control of the disease. Furthermore, the numerous lineages and genotypes of FMD virus isolates in Africa having distinct or overlapping distributions as well as the genetic linkage between regions will complicate the epidemiology of the disease. Therefore, it is strategically important to consider a regional approach and the use of a vaccine which contains a cocktails of antigens of FMD virus strains. / Thesis (PhD)--University of Pretoria, 2004. / Veterinary Tropical Diseases / unrestricted
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Prediction of interacting motifs within the protein subunits of Picornavirus capsidsRoss, Caroline Jane January 2015 (has links)
The Picornaviridae family contains a number of pathogens which are economically important including Poliovirus, Coxsakievirus, Hepatitis A Virus, and Foot-and-Mouth-Disease-Virus. Recently the emergence of novel picornaviruses associated with gastrointestinal, neurological and respiratory diseases in humans has been reported. Although effective vaccines for viruses such as FMDV, PV and HAV have been developed there are currently no antivirals available for the treatment of picornavirus infections. Picornaviruses proteins are classified as: the structural proteins VP1, VP2, VP3 and VP4 which form the subunits of the viral capsid and the replication proteins which function as proteases, RNA-polymerases, primers and membrane binding proteins. Although the host specificity and viral pathogenicity varies across members of the family, the icosahedral capsid is highly conserved. The capsid consists of 60 protomers, each containing a single copy of VP1, VP2 and VP3. A fourth capsid protein, VP4, resides on the internal side of the capsid. Capsid assembly is integral to life-cycle of picornaviruses; however the process is complex and not fully-understood. The overall aim of the study was to broaden the understanding of the evolution and function of the structural proteins across the Picornaviridae family. Firstly a comprehensive analysis of the phylogenetic relationships amongst the individual structural proteins was performed. The functions of the structural proteins were further investigated by an exhaustive motif analysis. A subsequent structural analysis of highly conserved motifs was performed with respect to representative enteroviruses, Foot-and-Mouth-Disease-Virus and Theiler’s Virus. This was supplemented by the in silico prediction of interacting residues within the crystal structures of these protomers. Findings in this study suggest that the capsid proteins may be evolving independently from the replication proteins through possible inter-typic recombination of functional protein regions. Moreover the study predicts that protomer assembly may be facilitated through a network of multiple subunit-subunit interactions. Multiple conserved motifs and principle residues predicted to facilitate capsid subunit-subunit interactions were identified. It was also concluded that motif conservation may support the theory of inter-typic recombination between closely related virus sub-types. As capsid assembly is critical to the viral life-cycle, the principle interacting motifs may serve as novel drug targets for the antiviral treatment of picornavirus infections. Thus the findings in the study may be fundamental to the development of treatments which are more economically feasible or clinically effective than current vaccinations.
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Antigenic refocusing of a SAT2 foot-and-mouth disease vaccine seed virusRamulongo, Tovhowani Dapheny 16 July 2020 (has links)
The majority of the world’s most widespread and problematic pathogens evade host immune responses by inducing strain-specific immunity. The host immune system seems to induce a vigorous immune response towards hypervariable epitopes, seemingly attracting less attention to more highly conserved vital regions. The South African Territory (SAT)-2 foot-and-mouth disease virus (FMDV) is the most prevalent and antigenic diverse of the SAT serotypes with the occurrence of multiple antigenic and genetic subtypes. Identification of the fine antigenic structure of the capsid of these viruses remains essential in the design and engineering of a vaccine seed strain that confers cross-protection against intra-typic viruses. Towards refocusing the antigenicity of SAT2/ZIM/07/83 virus, two strategies were utilised, (1) replacement of predicted antigenic determinants to corresponding sites of the antigenic distant SAT2/EGY/09/12 virus and (2) charge-dampening of previously identified epitope regions with alanine residues. The antigenic distance of refocused mutants was evaluated by (1) virus neutralisation assays using parental and heterologous convalescent bovine sera and (2) through antigenic profiling with non-neutralising SAT2-specific murine monoclonal antibodies (mAbs). One antigenic site on VP1 (Site 3) was identified using bovine polyclonal antibodies, whereas an additional three epitope regions were elucidated using the murine mAbs. Furthermore, the cell culture-adapted vSAT2 was shown to utilise a third FMDV alternate receptor to infect integrin- and heparin sulphate-deficient cell lines. Comprehensive knowledge on the antigenic structure of these viruses will assist in the fundamental design of engineered vaccines by incorporating critical antigenic sites that confer increased antigenicity and cross-protective immune response against myriad SAT2 field strains. Furthermore, this information will not only improve design of vaccine seed viruses, but will also contribute towards novel vaccine constructs or even empty nanoparticles as a vaccine strategy in the future. / Thesis (PhD)--University of Pretoria, 2020. / Agricultural Research Council / National Research Foundation / Red Meat Industry Trust / Poliomyelitis Research Foundation / Microbiology and Plant Pathology / PhD / Unrestricted
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Investigating potential factors affecting foot-and-mouth disease virus internalisationChitray, Melanie 19 February 2009 (has links)
Foot-and-mouth disease (FMD) is a highly contagious disease caused by the FMD virus (FMDV) belonging to the Picornaviridae family. The virus affects cloven-hoofed animals and occurs as seven immunologically distinct serotypes where six of the seven serotypes occur in Africa. This fact, as well as the role of wildlife in virus maintenance, makes eradication and control of FMDV in Africa difficult. Thus, it is imperative to attain more information regarding the genetic diversity of FMD viruses prevalent on the African continent to further our knowledge of the virus as well as to enable better control strategies and the development of improved vaccines. Sufficient genetic information regarding the Leader (L) and complete capsid-coding, P1, region of serotype A and O viruses prevalent on the African continent is lacking, although the SAT isolates have been extensively characterised in the past. In this study the sequence of the L/P1-coding region was successfully determined using a genome-walking approach for a small number of A and O viruses recovered from outbreaks isolated from various species in East and West Africa over the last 33 years. Phylogenetic analysis of the P1 and capsid-coding regions 1A, 1B, 1C and 1D revealed that the African isolates grouped strictly according to serotype and geographic region which indicated the possibility of transboundary spread of the virus within East and West African countries respectively. In contrast, phylogenetic analysis of the non-structural, Lpro-coding region revealed a different tree topology compared to the capsid-coding regions for the A and O isolates with sub-grouping according to serotype and geographic regions was less apparent. The relatedness between the serotype A and O L region might be the result of genetic recombination. The inter and intratypic nucleotide and amino acid variation of the A and O isolates revealed that the most variable capsid-coding region was the externally located VP1 whilst the internally located VP4 capsid protein was the most conserved. The observed variation is in agreement with other studies and reflects the selective pressures on these proteins which either allow or prevent the occurrence of genetic changes for structural constraints or immune escape. Surprisingly, the L protease-encoding region also displayed a high degree of variation. A detailed analysis of the L/P1 amino acid alignment of the A and O isolates revealed that although the extent of variation is high in these regions, the amino acids identified in previous studies as important for FMDV structure (for the capsid-coding regions) and function were found to be conserved, indicating that the virus has adapted itself to elude the host immune response without affecting its vital functional and structural abilities. Additionally, it was observed that the amino acid residues identified as being important for FMDV attaching to the host cell receptors e.g. the RGD amino acid motif of VP1 was highly conserved for all isolates. To further investigate the FMDV-receptor interaction, RT-PCRs were developed to examine the mRNA expression level of the known FMDV receptors. The â integrins that facilitate FMDV cell entry i.e. â1, â3, â6, â8 and heparan sulphate proteoglycans (HSPG) were investigated in susceptible cell lines used for FMDV vaccine production i.e. IB-RS-2 and BHK-21. The RT-PCRs were successfully developed and optimised. The results showed that the mRNA expression levels were variable for all receptor cDNAs tested across 36 passage levels of IB-RS-2 and BHK-21 cells. No distinct differences in virus susceptibility for three FMDV strains with continuous cell passage of IB-RS-2 and BHK-21 cells at passage levels 5, 21 and 36 could be found. The information gained from this study regarding the viral L and P1 region genetic diversity, and phylogenetic analysis has indeed impacted on our understanding of FMDV African viruses. Additionally, the investigation of the FMDV receptor mRNA expression levels and virus susceptibility on two cell lines with continuous cell passage has proved a vital starting point to determine the possible receptors expressed on the surface of cells used by the vaccine production division at the ARC-OVI-TADP and forms the basis for further investigations of the FMDV receptors on the protein level and the development of a real-time RT-PCR for FMDV receptor expression. / Dissertation (Msc)--University of Pretoria, 2008. / Veterinary Tropical Diseases / unrestricted
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Evolution of Picornaviruses: Impacts of Recombination and SelectionLewis-Rogers, Nicole Noel 21 November 2008 (has links) (PDF)
Picornaviruses are responsible for some of the most common and debilitating diseases affecting humans and animals worldwide. The objectives of this dissertation research were (1) estimate phylogenetic relationships among 11 picornavirus genera and within three species: foot-and-mouth disease virus (FMDV: Aphthovirus) which afflicts cloven-hoofed animals and human rhinovirus A and B (HRV: Enterovirus) which cause the common cold; (2) better understand the impact recombination has on genomic organization and evolution; (3) characterize where positive and purifying selection has occurred in proteins and how selection has influenced phenotype. The dissertation includes four studies. The first chapter provides an overview of the evolutionary significance of recombination, its detection and estimation, and its effect on phylogenetic analysis in four biological systems: bacteria, viruses, mitochondria, and the human genome. Chapter two investigates the inter- and intra-serotypic relationships within FMDV by examining 12 genes. Gene sequences were analyzed to assess recombination breakpoint locations, genetic diversity, and natural selection in FMDV. Recombination breakpoints were located throughout the genome. Paraphyletic relationships among serotypes were not as prevalent as previously reported, suggesting that convergent evolution was prevalent. Purifying selection was the dominant evolutionary force influencing both genotype and phenotype. Chapter three examines inter- and intra-specific relationships of HRV using 11 genes. Similar hypotheses were tested as in chapter two. No recombination was detected and phylogenetic relationships among enteroviruses, HRV-A, and HRV-B remain unresolved. The evolution of HRV-A major serotypes appeared to be under extensive purifying selection, HRV-A minor serotypes under predominantly positive selection, and a nearly equal influence from both kinds of selection was evident for HRV-B serotypes. Chapter four examines phylogenetic relationships among genera using three conserved genes. The hypothesis of cospeciation between picornaviruses and their hosts was also tested. The deepest split in the family separated Hepatovirus, ‘Tremovirus’, Parechovirus, and seal picornavirus type 1 from the remainder of the family. Enterovirus and ‘Sapelovirus’ were sister taxa. Cardiovirus, ‘Senecavirus’, Aphthovirus, Erbovirus, Teschovirus, and Kobuvirus were derived from a common ancestor with Kobuvirus occupying a basal position relative to the other genera in this clade. My analyses suggest that picornaviruses have not cospeciated with their known hosts.
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Optimisation of the Montanide ISA 206 B oil adjuvanted foot and mouth disease vaccine containing the southern African territories (SAT) serotypes.Peta, Faith Rosemary Masekgala. January 2013 (has links)
M. Tech. Veterinary Technology. / Aims of this study were to: determine the suitable buffers and optimal concentrations of these buffers, to be used in the ISA 206 B oil-based vaccine formulations that will ensure pH levels of ≥%x; 7.0; consistent emulsion type and particle sizes following a storage period of at least 24 months at 4 C ; determine the effects of temperature on the stability of the vaccine formulation during storage ; determine the optimal buffer antigen ratio in the water phase of the ISA 206 B oil-adjuvanted FMD vaccine containing SAT serotypes ; determine the effects of saponin (Q-Vac trade mark) on the buffering capacity during storage, in the ISA 206 B oil-adjuvanted FMD vaccine containing the SAT serotypes; and determine the shelf life of this improved (stabilised) oil vaccine. Previous research by the ARC scientists has shown that the immunity elicited by the ISA 206 oil adjuvanted vaccines could persist up to 50 weeks post vaccination in cattle (Cloete et al., 2008; Hunter, 1996). However, they did not show if this immunity was protective or not. Although it is known within the FMD field that sometimes immunity levels do not always translate into protection against an infection, if protection can be shown - even after vaccination using a stored vaccines - achievement of the above mentioned objectives could enable a once-a-year vaccination regimen in the control zone of RSA. Moreover, this once-a-year vaccination regimen could also substantially reduce the logistical costs involved during vaccination campaigns, compared to the current biannual vaccination regimen. Once the shelf life of the vaccine has been established, the vaccine could also be registered as a stock remedy under the Fertilisers, Farm Feed, Agricultural Remedies and Stock Remedies Act, 36 of 1947, administered by DAFF. The registration of this vaccine could in turn enable the RSA to supply the vaccine to neighbouring South African Development Community (SADC) countries and the rest of African countries where the SAT serotypes occur.
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Optimisation of the Montanide ISA 206 B oil adjuvanted foot and mouth disease vaccine containing the southern African territories (SAT) serotypes.Peta, Faith Rosemary Masekgala. January 2013 (has links)
M. Tech. Veterinary Technology. / Aims of this study were to: determine the suitable buffers and optimal concentrations of these buffers, to be used in the ISA 206 B oil-based vaccine formulations that will ensure pH levels of ≥%x; 7.0; consistent emulsion type and particle sizes following a storage period of at least 24 months at 4 C ; determine the effects of temperature on the stability of the vaccine formulation during storage ; determine the optimal buffer antigen ratio in the water phase of the ISA 206 B oil-adjuvanted FMD vaccine containing SAT serotypes ; determine the effects of saponin (Q-Vac trade mark) on the buffering capacity during storage, in the ISA 206 B oil-adjuvanted FMD vaccine containing the SAT serotypes; and determine the shelf life of this improved (stabilised) oil vaccine. Previous research by the ARC scientists has shown that the immunity elicited by the ISA 206 oil adjuvanted vaccines could persist up to 50 weeks post vaccination in cattle (Cloete et al., 2008; Hunter, 1996). However, they did not show if this immunity was protective or not. Although it is known within the FMD field that sometimes immunity levels do not always translate into protection against an infection, if protection can be shown - even after vaccination using a stored vaccines - achievement of the above mentioned objectives could enable a once-a-year vaccination regimen in the control zone of RSA. Moreover, this once-a-year vaccination regimen could also substantially reduce the logistical costs involved during vaccination campaigns, compared to the current biannual vaccination regimen. Once the shelf life of the vaccine has been established, the vaccine could also be registered as a stock remedy under the Fertilisers, Farm Feed, Agricultural Remedies and Stock Remedies Act, 36 of 1947, administered by DAFF. The registration of this vaccine could in turn enable the RSA to supply the vaccine to neighbouring South African Development Community (SADC) countries and the rest of African countries where the SAT serotypes occur.
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Engineering Cell-Free Systems for Vaccine Development, Self-Assembling Nanoparticles and Codon Reassignment ApplicationsSmith, Mark T 01 April 2014 (has links) (PDF)
This dissertation reports on the technology of cell-free protein synthesis (CFPS) including 1) stabilized lyophilized cell-free systems and 2) enhanced heterogeneous cell extracts. This work further considers applications of CFPS systems in 1) rapid vaccine development, 2) functional virus-based nanoparticles, 3) site-specific protein immobilization, and 4) expanding the language of biology using unnatural amino acids. CFPS technology is a versatile protein production platform that has many features unavailable in in vivo expression systems. The primary benefit cell-free systems provide is the direct access to the reaction environment, which is no longer hindered by the presence of a cell-wall. The “openness" of the system makes it a compelling candidate for many technologies. One limitation of CFPS is the necessity of freezing for long-term viable storage. We demonstrate that a lyophilized CFPS system is more stable against nonideal storage than traditional CFPS reagents. The Escherichia coli-based CFPS system in this work is limited by the biocatalytic machinery found natively in E. coli. To combat these limitations, exogenous biocatalysts can be expressed during fermentation of cells prepared into extract. We demonstrate that simple adjustments in the fermentation conditions can significantly increase the activity of the heterogeneous extract. Towards virus-based particles and vaccines, we demonstrate that the open nature of CFPS can be utilized for coexpression of virus proteins and self-assembly of virus particles. This technique allows for the rapid production of potential vaccines and novel functional virus-based nanoparticles. Unnatural amino acids expand the effective language of protein biology. Utilizing CFPS as an expression system, we demonstrated that the incorporation of a single specific unnatural amino acid allows for site-specific immobilization, thus stabilizing the protein against elevated temperatures and chemical denaturants. Current unnatural amino acid incorporation technologies are limited to one or few simultaneous incorporations and suffer from low efficiency. This work proposes a system that could potentially allow for upwards of 40 unnatural amino acids to be simultaneously incorporated, effectively tripling the protein code. These projects demonstrate the power and versatility of CFPS technologies while laying the foundation for promising technologies in the field of biotechnology.
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The in silico prediction of foot-and-mouth disease virus (FMDV) epitopes on the South African territories (SAT)1, SAT2 and SAT3 serotypesMukonyora, Michelle 24 January 2017 (has links)
Foot-and-mouth disease (FMD) is a highly contagious and economically
important disease that affects even-toed hoofed mammals. The FMD virus
(FMDV) is the causative agent of FMD, of which there are seven clinically
indistinguishable serotypes. Three serotypes, namely, South African
Territories (SAT)1, SAT2 and SAT3 are endemic to southern Africa and are
the most antigenically diverse among the FMDV serotypes. A negative
consequence of this antigenic variation is that infection or vaccination with
one virus may not provide immune protection from other strains or it may only
confer partial protection. The identification of B-cell epitopes is therefore key
to rationally designing cross-reactive vaccines that recognize the
immunologically distinct serotypes present within the population.
Computational epitope prediction methods that exploit the inherent physicochemical properties of epitopes in their algorithms have been
proposed as a cost and time-effective alternative to the classical experimental
methods. The aim of this project is to employ in silico epitope prediction
programmes to predict B-cell epitopes on the capsids of the SAT serotypes.
Sequence data for 18 immunologically distinct SAT1, SAT2 and SAT3 strains from across southern Africa were collated. Since, only one SAT1 virus has
had its structure elucidated by X-ray crystallography (PDB ID: 2WZR),
homology models of the 18 virus capsids were built computationally using
Modeller v9.12. They were then subjected to energy minimizations using the
AMBER force field. The quality of the models was evaluated and validated
stereochemically and energetically using the PROMOTIF and ANOLEA
servers respectively. The homology models were subsequently used as input
to two different epitope prediction servers, namely Discotope1.0 and Ellipro.
Only those epitopes predicted by both programmes were defined as epitopes.
Both previously characterised and novel epitopes were predicted on the SAT
strains. Some of the novel epitopes are located on the same loops as
experimentally derived epitopes, while others are located on a putative novel antigenic site, which is located close to the five-fold axis of symmetry. A
consensus set of 11 epitopes that are common on at least 15 out of 18 SAT
strains was collated. In future work, the epitopes predicted in this study will be
experimentally validated using mutagenesis studies. Those found to be true
epitopes may be used in the rational design of broadly reactive SAT vaccines / Life and Consumer Sciences / M. Sc. (Life Sciences)
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