Structure analysis of biologically important prokaryotic glycopolymers

Of the many post-translational modifications organisms can undertake, glycosylation is the most prevalent and the most diverse. The research in this thesis focuses on the structural characterisation of glycosylation in two classes of glycopolymer (lipopolysaccharide (LPS) and glycoprotein) in two domains of life (bacteria and archaea). The common theme linking these subprojects is the development and application of high sensitivity analytical techniques, primarily mass spectrometry (MS), for studying prokaryotic glycosylation. Many prokaryotes produce glycan arrangements with extraordinary variety in composition and structure. A further challenge is posed by additional functionalities such as lipids whose characterisation is not always straightforward. Glycosylation in prokaryotes has a variety of different biological functions, including their important roles in the mediation of interactions between pathogens and hosts. Thus enhanced knowledge of bacterial glycosylation may be of therapeutic value, whilst a better understanding of archaeal protein glycosylation will provide further targets for industrial applications, as well as insight into this post- translational modification across evolution and protein processing under extreme conditions. The first sub-project focused on the S-layer glycoprotein of the halophilic archeaon Haloferax volcanii, which has been reported to be modified by both glycans and lipids. Glycoproteomic and associated MS technologies were employed to characterise the N- and O-linked glycosylation and to explore putative lipid modifications. Approximately 90% of the S-layer was mapped and N-glycans were identified at all the mapped consensus sites, decorated with a pentasaccharide consisting of two hexoses, two hexuronic acids and a methylated hexuronic acid. The O-glycans are homogeneously identified as a disaccharide consisting of galactose and glucose. Unexpectedly it was found that membrane-derived lipids were present in the S- layer samples despite extensive purification, calling into question the predicted presence of covalently linked lipid. The H. volcanii N-glycosylation is mediated by the products of the agl gene cluster and the functional characterisation of members of the agl gene cluster was investigated by MS analysis of agl-mutant strains of the S-layer. Burkholderia pseudomallei is the causative agent of melioidosis, a serious and often fatal disease in humans which is endemic in South-East Asia and other equatorial regions. Its LPS is vital for serum resistance and the O-antigen repeat structures are of interest as vaccine targets. B. pseudomallei is reported to produce several polysaccharides, amongst which the already characterised ‘typical’ O-antigen of K96243 represents 97% of the strains. The serologically distinct ‘atypical’ strain 576 produces a different LPS, whose characterisation is the subject of this research project. MS strategies coupled with various hydrolytic and chemical derivatisation methodologies were employed to define the composition and potential sequences of the O-antigen repeat unit. These MS strategies were complemented by a novel NMR technique involving embedding of the LPS into micelles. Taken together the MS and NMR data have revealed a highly unusual O-antigen structure for atypical LPS which is remarkably different from the typical O-antigen. The development of structural analysis tools in MS and NMR applicable to the illustrated types of glycosylation in these prokaryotes will give a more consistent approach to sugar characterisation and their modifications thus providing more informative results for pathogenicity and immunological studies as well as pathway comparisons.Open Acces

Molecular and antigenic characterization of Trypanosoma cruzi TolT proteins

Background: TolT was originally described as a Trypanosoma cruzi molecule that accumulated on the trypomastigote flagellum bearing similarity to bacterial TolA colicins receptors. Preliminary biochemical studies indicated that TolT resolved in SDS-PAGE as ~3–5 different bands with sizes between 34 and 45 kDa, and that this heterogeneity could be ascribed to differences in polypeptide glycosylation. However, the recurrent identification of TolT-deduced peptides, and variations thereof, in trypomastigote proteomic surveys suggested an intrinsic TolT complexity, and prompted us to undertake a thorough reassessment of this antigen. Methods/Principle findings: Genome mining exercises showed that TolT constitutes a larger-than-expected family of genes, with at least 12 polymorphic members in the T. cruzi CL Brener reference strain and homologs in different trypanosomes. According to structural features, TolT deduced proteins could be split into three robust groups, termed TolT-A, TolT-B, and TolT-C, all of them showing marginal sequence similarity to bacterial TolA proteins and canonical signatures of surface localization/membrane association, most of which were herein experimentally validated. Further biochemical and microscopy-based characterizations indicated that this grouping may have a functional correlate, as TolT-A, TolT-B and TolT-C molecules showed differences in their expression profile, sub-cellular distribution, post-translational modification(s) and antigenic structure. We finally used a recently developed fluorescence magnetic beads immunoassay to validate a recombinant protein spanning the central and mature region of a TolT-B deduced molecule for Chagas disease serodiagnosis. Conclusion/Significance: This study unveiled an unexpected genetic and biochemical complexity within the TolT family, which could be exploited for the development of novel T. cruzi biomarkers with diagnostic/therapeutic applications.Fil: Lobo, Mabel Maite. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Balouz, Virginia. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Melli, Luciano Jorge. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Carlevaro, Giannina Alejandra. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Cortina, María Eugenia. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Camara, María de los Milagros. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Canepa, Gaspar Exequiel. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Carmona, Santiago Javier. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Altcheh, Jaime Marcelo. Gobierno de la Ciudad de Buenos Aires. Hospital General de Niños "Ricardo Gutiérrez"; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; ArgentinaFil: Campetella, Oscar Eduardo. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Ciocchini, Andres Eduardo. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Agüero, Fernan Gonzalo. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Mucci, Juan Sebastián. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; ArgentinaFil: Buscaglia, Carlos Andres. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata. Instituto de Investigaciones Biotecnológicas. Universidad Nacional de San Martín. Instituto de Investigaciones Biotecnológicas; Argentin

Probing entry inhibitors' activity on HIV and development of new fusion inhibitors : integrating evolutionary biology with virology

Tese de doutoramento, Farmácia (Microbiologia), Universidade de Lisboa, Faculdade de Farmácia, 2011The general aims of this thesis were: 1) to examine the C2, V3 and C3 envelope regions ofHIV-1 and HIV-2 at the molecular, evolutionary and structural levels; 2) to compare HIV-1and HIV-2 susceptibility to entry inhibitors and assess their potential value in HIV-2therapy; 3) to produce a new fusion inhibitor peptide using evolutionary biology basedstrategies.In the first study (Chapter 2), HIV-1 and HIV-2 were compared at the molecular,evolutionary and structural levels in the C2, V3 and C3 envelope regions. We identifiedsignificant structural and functional constrains to the diversification and evolution of C2,V3 and C3 in the HIV-2 envelope but not in HIV-1. In particular, we found that V3 in HIV-2is less exposed and more conserved than in HIV-1, suggesting fundamental differences inthe biology and infection of these viruses as well as in their susceptibility to entryinhibitors.In the second study (Chapter 3) we measured the baseline susceptibility of HIV-1 and HIV-2primary isolates to different fusion inhibitors and coreceptor antagonists, includingenfuvirtide (T-20) and maraviroc (MVC). MVC inhibited HIV-2 R5 variants at significantlyhigher IC90 concentrations than HIV-1 variants. Moreover, as previously found in HIV-1,susceptibility of HIV-2 R5 variants to MVC was inversely related with CD4+ T cell counts attime of virus isolation. These results suggest that the structure of the envelope complex ofR5 variants changes along the course of infection. More importantly, the results call fornew clinical studies to evaluate the efficacy of MVC in HIV-2 infection and to determine itsbest therapeutic dosage in early and late stage disease. We also provide definitiveevidence demonstrating that T-20 is not useful for HIV-2 therapy.In the final study (Chapter 4), we designed a new HIV fusion inhibitor peptide (P3) basedon the ancestral sequences of the HIV-2 and SIV envelope genes. P3 has an a-helixstructure as demonstrated by circular dichroism. It has broad antiviral activity at thenanomolar range against HIV-1 and HIV-2 primary isolates, including HIV-1 variantsresistant to T-20. Binding ELISA assays and selection of resistant mutants suggest that P3prevents viral fusion by binding to the transmembrane protein in the HR1 region. Thesestudies provide proof of concept that viable antiviral peptides can be constructed usingevolutionary biology strategies. Such strategies should be explored to enhance theproduction of peptide drugs and vaccines.O Vírus da Imunodeficiência Humana do tipo 1 e do tipo 2 (VIH-1 e VIH-2) são os agentes etiológicos do Síndrome de Imunodeficiência Adquirida (SIDA). Embora sejam semelhantes na sua organização estrutural e genómica, estes lentivírus humanos apresentam características antigénicas distintas e partilham uma semelhança genética de apenas 50%. Enquanto o VIH-1 é responsável pela pandemia mundial, a infecção pelo VIH-2 localiza-se sobretudo na África Ocidental, em alguns países europeus como Portugal e França, e na Índia. A infecção pelo VIH-2 tem melhor prognóstico, a progressão para a doença é mais lenta e há melhor controlo imunológico do que na infecção pelo VIH-1. Ao contrário do VIH-1, o arsenal terapêutico actualmente disponível para tratar a infecção por VIH-2 é reduzido. Os fármacos antiretrovirais em uso foram especificamente desenvolvidos para o VIH-1 e, consequentemente, a sua actividade pode ser reduzida ou nula no VIH-2. Este é o caso concreto dos inibidores não nucleosídicos da transcriptase reversa e de alguns inibidores da protease. Neste contexto, os inibidores de entrada poderão ser úteis para tratar a infecção por VIH-2. Contudo, a susceptibilidade dos isolados primários de VIH-2 aos inibidores de entrada é actualmente desconhecida. A susceptibilidade do VIH aos inibidores de entrada é determinada pela qualidade da interacção do vírus com os receptores celulares. O VIH-1 e VIH-2 são substancialmente diferentes a este nível. Por exemplo, o VIH-2 pode ligar-se ao co-receptor CCR5 independentemente do receptor CD4 e da região V3 do invólucro. Por outro lado, as regiões C2, V3 e C3 do VIH-2 são substancialmente diferentes do VIH-1 a nível antigénico. Colectivamente, estes dados indicam que a estrutura e conformação das glicoproteínas de superfície do VIH-1 e VIH-2 são substancialmente diferentes e sugerem que a susceptibilidade e resistência dos dois tipos de vírus aos inibidores de entrada podem também ser diferentes. Os principais objectivos desta tese foram: 1) analisar as características moleculares, estruturais e evolutivas das regiões C2, V3 e C3 no VIH-1 e VIH-2; 2) comparar a susceptibilidade do VIH-1 e VIH-2 aos inibidores de entrada e avaliar o seu potencial terapêutico na infecção por VIH-2; 3) produzir um novo inibidor de fusão para o VIH-2. Para melhor compreender as potenciais diferenças destes dois vírus na resposta aos inibidores de entrada começámos por analisar as características moleculares, estruturais e evolutivas da região V3 e as regiões circundantes C2 e C3, num número significativo de vírus VIH-1 e VIH-2 isolados em Portugal e noutras regiões do globo, com recurso a diferentes metodologias de biologia evolutiva e computacional (Capitulo 2). Apesar da menor variabilidade das 3 regiões no VIH-2, verificámos que a região C3 está sob forte selecção positiva e encontra-se exposta à superfície sugerindo que, tal como no VIH-1, esta região poderá constituir um domínio neutralizante. No entanto, ao contrário do VIH-1, a maioria das mutações adaptativas no VIH-2 são prejudiciais e levam à extinção das linhagens virais pelo que o efeito final é um forte constrangimento à variabilidade das regiões analisadas. Ao contrário do VIH-1, verificámos que a ansa V3 do VIH-2 se encontra oclusa no complexo glicoproteico do invólucro, numa conformação que parece ser estabilizada por interacções que mantém com alguns resíduos da regiões C2 e C3. Estes resultados são consistentes com o facto de a V3 não ser imunodominante no VIH-2, ficando assim mais protegida da resposta imunitária e das eventuais mutações que dela resultam. A forte conservação da V3, da C2 e da C3 também é consistente com a sua potencialmente importante actividade imunosupressora. Em conclusão, este primeiro estudo permitiu caracterizar algumas das características estruturais e funcionais que distinguem as glicoproteínas do invólucro do VIH-1 e do VIH-2 e que estão associadas às diferentes características biológicas e fenotípicas destes dois vírus. Estes dados podem ter impacto na resposta dos dois vírus aos inibidores de entrada (analisado no Capítulo 3) e no desenvolvimento de novas vacinas. No segundo estudo (Capítulo 3) comparámos a actividade antiviral dos antagonistas dos coreceptores (AMD3100, TAK-779 e maraviroc) e dos inibidores de fusão (T-20 e T-1249) entre um grupo de 20 isolados de VIH-2 (19 isolados primários + um isolado laboratorial) e nove isolados de VIH-1 (sete isolados primários + dois isolados laboratoriais). Verificámos que a sensibilidade ao AMD3100 e ao TAK-779 é semelhante no VIH-1 e o VIH-2. No entanto, o perfil da curva dose-resposta do maraviroc (MVC) obtido para os isolados R5 foi diferente nos dois tipos de vírus. No VIH-2 os valores de IC90 foram significativamente mais elevados do que no VIH-1; por outro lado, os declives da curva dose-resposta foram mais baixos no VIH-2 do que no VIH-1. Colectivamente, estes resultados sugerem que poderão ser necessárias concentrações mais elevadas de MVC para tratar os doentes infectados pelo VIH-2. Adicionalmente, encontrámos uma correlação forte e de sentido inverso entre as susceptibilidade do VIH-2 ao MVC e o número de células T CD4+ dos doentes quando os vírus foram isolados. Vírus isolados em doentes em fase de SIDA foram menos susceptíveis ao MVC do que os vírus isolados em doentes com uma contagem de células T CD4+ superior a 200 células/ul. Ao contrário do VIH-1 não encontrámos qualquer correlação entre a carga da V3 e a susceptibilidade dos isolados R5 de VIH-2 ao MVC. De um modo geral, os nossos resultados sugerem que são necessários ensaios clínicos para avaliar a efectividade do MVC na infecção pelo VIH-2, determinar a dose terapêutica mais adequada e esclarecer se é necessário fazer um ajuste de dose de acordo com a fase da doença. Adicionalmente, e uma vez que isolados VIH-2 X4 e populações duplas/mistas são totalmente ou parcialmente resistentes ao MVC, é de extrema importância o desenvolvimento de um ensaio de tropismo (genotípico e/ou fenotípico) para o VIH-2 de modo a determinar o tropismo antes do início da terapia com MVC. Sem o conhecimento prévio do tropismo viral, o tratamento com MVC poderá seleccionar espécies X4 minoritárias que estão associadas a maior resistência à neutralização e uma progressão mais rápida da doença. No que diz respeito aos inibidores de fusão, verificámos que o T-20 tem actividade reduzida no VIH-2, confirmando estudos anteriores realizados com dois isolados laboratoriais. Por outro lado, observámos uma elevada susceptibilidade deste vírus ao T- 1249, indicando que os inibidores de fusão são potencialmente eficazes na infecção pelo VIH-2. Assim, o desenvolvimento de um novo inibidor de fusão do VIH-2 foi o objectivo do último estudo desta tese (Capítulo 4). No Capítulo 4, desenvolvemos novos péptidos inibidores de fusão a partir da reconstrução de sequências ancestrais da glicoproteína gp36 do invólucro de VIH-2 e de Vírus de Imunodeficiência dos Símios (VIS). Com esta abordagem inovadora pretendemos incorporar a história evolutiva dos vírus na sequência dos péptidos e desta forma melhorar a tolerância destas moléculas aos polimorfismos naturais da sua região alvo bem como às mutações de resistência seleccionadas na sua presença. Obteve-se um péptido ancestral (P3) constituído por 34 aminoácidos, cuja sequência corresponde às posições homólogas 628 – 661 da proteína Env do isolado VIH-1 HXB2 (ou 623 – 656 do isolado VIH-2 ROD). A sequência do P3 difere em 21 aminoácidos da sequência consenso de VIH-1, 14 aminoácidos da sequência do T-20 e 6 aminoácidos da sequência consenso de VIH-2. Ao contrário da natureza não-estruturada do T-20, o P3 tem uma conformação típica em hélice-a, o que lhe poderá conferir maior a estabilidade contra a degradação proteolítica, bem como maior afinidade para a região alvo. Por outro lado, o P3 foi facilmente solúvel em soluções aquosas o que é uma vantagem num futuro desenvolvimento de uma fórmula farmacêutica. O P3 demonstrou ter uma forte actividade antiviral contra isolados primários e laboratoriais de VIH-1 e VIH-2 (IC50 médio, 11 nM para o HIV-1 e 63.8 nM para o HIV-2), incluindo variantes resistentes ao T-20 (IC50, 0.15 – 11.8 nM). Através da passagem consecutiva de vírus em cultura na presença do péptido, foi seleccionada uma mutação de resistência na região HR1 da gp41 (VIH-1), a qual é responsável pela redução da susceptibilidade do VIH-1 ao P3 em 120x. Nas mesmas condições, e após 60 dias em cultura, não foi possível seleccionar mutações de resistência ao P3 no VIH-2. Estes resultado, em conjugação com a sua forte ligação à glicoproteína transmembranar de um isolado de VIH-2, indicam que, tal como outros péptidos baseados na região HR2 (T-20, T- 1249), o P3 inibe a entrada do VIH pela interacção com a região HR1 da gp41 e sugerem que a barreira genética para a resistência ao P3 é significativamente superior no VIH-2 do que no VIH-1. Neste estudo demonstrámos ainda que o P3 é significativamente menos antigénico do que o T-20 nos doentes infectados pelo VIH-1 o que poderá traduzir-se numa maior duração da eficácia clínica do P3 em comparação com o T-20. Os resultados obtidos com o P3 demonstram pela primeira vez que é possível desenvolver péptidos com actividade antiviral significativa utilizando metodologias de biologia evolutiva, pelo que esta abordagem poderá ser explorada no futuro para a produção de medicamentos peptídicos e, eventualmente, de vacinas

Molecular Evolution of Human H1N1 and H3N2 Influenza A Virus in Thailand, 2006–2009

Annual seasonal influenza outbreaks are associated with high morbidity and mortality.To index and document evolutionary changes among influenza A H1N1 and H3N2 viruses isolated from Thailand during 2006-2009, using complete genome sequences.Nasopharyngeal aspirates were collected from patients diagnosed with respiratory illness in Thailand during 2006-2009. All samples were screened for Influenza A virus. A total of 13 H1N1 and 21 H3N2 were confirmed and whole genome sequenced for the evolutionary analysis using standard phylogenetic approaches.Phylogenetic analysis of HA revealed a clear diversification of seasonal from vaccine strain lineages. H3N2 seasonal clusters were closely related to the WHO recommended vaccine strains in each season. Most H1N1 isolates could be differentiated into 3 lineages. The A/Brisbane/59/2007 lineage, a vaccine strain for H1N1 since 2008, is closely related with the H1N1 subtypes circulating in 2009. HA sequences were conserved at the receptor-binding site. Amino acid variations in the antigenic site resulted in a possible N-linked glycosylation motif. Recent H3N2 isolates had higher genetic variations compared to H1N1 isolates. Most substitutions in the NP protein were clustered in the T-cell recognition domains.In this study we performed evolutionary genetic analysis of influenza A viruses in Thailand between 2006-2009. Although the current vaccine strain is efficient for controlling the circulating outbreak subtypes, surveillance is necessary to provide unambiguous information on emergent viruses. In summary, the findings of this study contribute the understanding of evolution in influenza A viruses in humans and is useful for routine surveillance and vaccine strain selection

Viral and host factors required for avian H5N1 influenza A virus replication in mammalian cells

Following the initial and sporadic emergence into humans of highly pathogenic avian H5N1 influenza A viruses in Hong Kong in 1997, we have come to realize the potential for avian influenza A viruses to be transmitted directly from birds to humans. Understanding the basic viral and cellular mechanisms that contribute to infection of mammalian species with avian influenza viruses is essential for developing prevention and control measures against possible future human pandemics. Multiple physical and functional cellular barriers can restrict influenza A virus infection in a new host species, including the cell membrane, the nuclear envelope, the nuclear environment, and innate antiviral responses. In this review, we summarize current knowledge on viral and host factors required for avian H5N1 influenza A viruses to successfully establish infections in mammalian cells. We focus on the molecular mechanisms underpinning mammalian host restrictions, as well as the adaptive mutations that are necessary for an avian influenza virus to overcome them. It is likely that many more viral and host determinants remain to be discovered, and future research in this area should provide novel and translational insights into the biology of influenza virus-host interactions

Soluble Host Defense Lectins in Innate Immunity to Influenza Virus

Host defenses against viral infections depend on a complex interplay of innate (nonspecific) and adaptive (specific) components. In the early stages of infection, innate mechanisms represent the main line of host defense, acting to limit the spread of virus in host tissues prior to the induction of the adaptive immune response. Serum and lung fluids contain a range of lectins capable of recognizing and destroying influenza A viruses (IAV). Herein, we review the mechanisms by which soluble endogenous lectins mediate anti-IAV activity, including their role in modulating IAV-induced inflammation and disease and their potential as prophylactic and/or therapeutic treatments during severe IAV-induced disease

Identification of novel subgroup a variants with enhanced receptor binding and replicative capacity in primary isolates of anaemogenic strains of feline leukaemia virus

<b>BACKGROUND:</b> The development of anaemia in feline leukaemia virus (FeLV)-infected cats is associated with the emergence of a novel viral subgroup, FeLV-C. FeLV-C arises from the subgroup that is transmitted, FeLV-A, through alterations in the amino acid sequence of the receptor binding domain (RBD) of the envelope glycoprotein that result in a shift in the receptor usage and the cell tropism of the virus. The factors that influence the transition from subgroup A to subgroup C remain unclear, one possibility is that a selective pressure in the host drives the acquisition of mutations in the RBD, creating A/C intermediates with enhanced abilities to interact with the FeLV-C receptor, FLVCR. In order to understand further the emergence of FeLV-C in the infected cat, we examined primary isolates of FeLV-C for evidence of FeLV-A variants that bore mutations consistent with a gradual evolution from FeLV-A to FeLV-C.<p></p> <b>RESULTS:</b> Within each isolate of FeLV-C, we identified variants that were ostensibly subgroup A by nucleic acid sequence comparisons, but which bore mutations in the RBD. One such mutation, N91D, was present in multiple isolates and when engineered into a molecular clone of the prototypic FeLV-A (Glasgow-1), enhanced replication was noted in feline cells. Expression of the N91D Env on murine leukaemia virus (MLV) pseudotypes enhanced viral entry mediated by the FeLV-A receptor THTR1 while soluble FeLV-A Env bearing the N91D mutation bound more efficiently to mouse or guinea pig cells bearing the FeLV-A and -C receptors. Long-term in vitro culture of variants bearing the N91D substitution in the presence of anti-FeLV gp70 antibodies did not result in the emergence of FeLV-C variants, suggesting that additional selective pressures in the infected cat may drive the subsequent evolution from subgroup A to subgroup C.<p></p> <b>CONCLUSIONS:</b> Our data support a model in which variants of FeLV-A, bearing subtle differences in the RBD of Env, may be predisposed towards enhanced replication in vivo and subsequent conversion to FeLV-C. The selection pressures in vivo that drive the emergence of FeLV-C in a proportion of infected cats remain to be established

Dissecting Human Antibody Responses Against Influenza A Viruses And Antigenic Changes That Facilitate Immune Escape

Influenza A viruses pose a serious threat to public health, and seasonal circulation of influenza viruses causes substantial morbidity and mortality. Influenza viruses continuously acquire substitutions in the surface glycoproteins hemagglutinin (HA) and neuraminidase (NA). These substitutions prevent the binding of pre-existing antibodies, allowing the virus to escape population immunity in a process known as antigenic drift. Due to antigenic drift, individuals can be repeatedly infected by antigenically distinct influenza strains over the course of their life. Antigenic drift undermines the effectiveness of our seasonal influenza vaccines and our vaccine strains must be updated on an annual basis due to antigenic changes. In order to understand antigenic drift it is essential to know the sites of antibody binding as well as the substitutions that facilitate viral escape from immunity. In this dissertation, we explore both the epitopes targeted in human antibody responses and how influenza viruses evade these responses. We first demonstrate that prior exposure shapes the sites targeted in human antibody responses, and show that many middle-age adults mounted an antibody response against H1N1 viruses that is focused against sites on HA conserved between contemporary strains and strains that circulated in early childhood. In addition, we demonstrate that a viral substitution in this epitope allows influenza viruses to evade neutralizing antibody responses. We next demonstrate that an H3N2 HA substitution introducing a glycosylation site prevents the binding of neutralizing antibodies present in a large number of individuals. Importantly, our egg-based vaccines lack this glycosylation due to culture-adaptive substitutions, but a vaccine containing this glycosylation motif more potently induced antibody responses against circulating strains. Finally, we identify and characterize antibodies that target conserved residues in the receptor-binding site (RBS) of HA. We demonstrate that in some individuals RBS antibodies in sera contribute to neutralization of antigenically distinct strains, even in the case of an antigenically mismatched vaccine. Overall, the work presented here helps address the complex interaction of influenza viruses and human immunity. Importantly, our work identifies shortcomings with our current process of vaccine strain selection and production and investigates epitopes of interest for universal influenza vaccine efforts

Horizontal gene transfer of epigenetic machinery and evolution of parasitism in the malaria parasite Plasmodium falciparum and other apicomplexans

Background The acquisition of complex transcriptional regulatory abilities and epigenetic machinery facilitated the transition of the ancestor of apicomplexans from a free-living organism to an obligate parasite. The ability to control sophisticated gene expression patterns enabled these ancient organisms to evolve several differentiated forms, invade multiple hosts and evade host immunity. How these abilities were acquired remains an outstanding question in protistan biology. Results In this work, we study SET domain bearing genes that are implicated in mediating immune evasion, invasion and cytoadhesion pathways of modern apicomplexans, including malaria parasites. We provide the first conclusive evidence of a horizontal gene transfer of a Histone H4 Lysine 20 (H4K20) modifier, Set8, from an animal host to the ancestor of apicomplexans. Set8 is known to contribute to the coordinated expression of genes involved in immune evasion in modern apicomplexans. We also show the likely transfer of a H3K36 methyltransferase (Ashr3 from plants), possibly derived from algal endosymbionts. These transfers appear to date to the transition from free-living organisms to parasitism and coincide with the proposed horizontal acquisition of cytoadhesion domains, the O-glycosyltransferase that modifies these domains, and the primary family of transcription factors found in apicomplexan parasites. Notably, phylogenetic support for these conclusions is robust and the genes clearly are dissimilar to SET sequences found in the closely related parasite Perkinsus marinus, and in ciliates, the nearest free-living organisms with complete genome sequences available. Conclusions Animal and plant sources of epigenetic machinery provide new insights into the evolution of parasitism in apicomplexans. Along with the horizontal transfer of cytoadhesive domains, O-linked glycosylation and key transcription factors, the acquisition of SET domain methyltransferases marks a key transitional event in the evolution to parasitism in this important protozoan lineage