The effect of quercetin on the growth of primary bovine cells and analysis of its ability to modulate the level of transcription from the bovine papillomavirus type 4 long control region

Connolly, Julie-Anne Catherine

January 1997

No description available.

572.8

Cancer research; Viral genes

The expression of integrated viral genes in adenovirus transformed cells

Maarschalkerweerd, Marianne Wilhelmina van,

January 1900

Thesis (doctoral)--Rijksuniversiteit te Utrecht.

Host Gene Expression Profiling of Japanese Encephalitis Virus Infected cells : Identification of Novel Pro- and Anti-viral Genes

Bhandari, Prakash

January 2013

Japanese encephalitis virus (JEV), a mosquito-borne flavivirus is the causative agent of Japanese encephalitis (JE). The disease affects mostly children and around 30000– 50000 cases of JE and up to 15000 deaths are reported annually. No anti-viral drugs have been discovered against JE so far, but advances in our knowledge of the molecular biology of flaviviruses is propelling flaviviral drug research at an expeditious pace. Since JEV has a small genome which encodes for only ten proteins, there is dearth of potential drug targets. Researchers are now focusing on cellular interactomes, a complex and dynamic molecular biosystem which identifies host proteins which interact with either viral proteins or viral genomes, leading to the generation of an astronomical number of potential drug targets involving common cellular pathways that are required for the life cycle of different viruses. Such studies can pave way for the development of ‘broad-spectrum’, ‘silver-bullet’ anti-viral drugs for the treatment of multiple viral diseases. The cellular interactomes can be studied by Genomics tools such as microarray. Systematic profiling of genes involved in virus infection by RNAi, transcriptome sequencing, microRNA profiling and yeast two-hybrid system has allowed us to assess global gene expression changes providing an unprecedented view on the host-side of the virus–host interactions. Advent of these tools has led to identification of plethora anti-viral genes. For example, over expression of IFN-stimulated gene15 (ISG15) results in inhibition of JEV leading to significant reduction of viral titers. Chemokine profiling of JEV-infected cells by microarray can provide possible therapeutic modalities that can mitigate the morbidity associated with JEV infection. Functional classification of interferon-stimulated genes (ISG) identified using innovative methods have been the stepping stone for identification of many anti-viral genes, among them are few Broadly acting effectors like IRF1, C6orf150, HPSE, RIG-I, MDA5 and IFITM3 and some more targeted antiviral specific like DDX60, IFI44L, IFI6, IFITM2, MAP3K14, MOV10, NAMPT, OASL, RTP4, TREX1 and UNC84B. In this study, we have identified a B16F10 murine melanoma cell line that is resistant to JEV infection. DNA microarray analysis of JEV-susceptible and resistant B16F10 cell lines gave us interesting insights into JEV-induced host gene expression changes. Real time PCR validation of microarray data indicates that a number of virus and interferon inducible genes are expressed constitutively at high levels in this JEV-resistant cell line. Further, several of the mouse genes induced by JEV in B16F10 cell line were also upregulated in JEV-infected mouse brain. To understand the significance of these host gene expression changes, we attempted to generate stable murine cell lines constitutively expressing select JEV-inducible genes and study the JEV infection pattern in these cell lines. One of the JEV-inducible genes encoding thymidylate kinase (Tyki), a mitochondrial protein involved in the sysnthesis of nucleoside diphosphates, when overexpressed in NIH3T3 cells confers resistance to JEV infection as evident from reduced JEV-induced cytopathic effects and significant reduction in viral titer. Since TYKI has two distinct domains: the N-terminal domain with unknown function and the C-terminal domain with the nucleoside monophosphate kinase function, suggest that TYKI may be a bifunctional protein with other biological functions in addition to its UMP-CMP kinase activity. In order to examine whether N-terminal domain is responsible for antiviral activity of the protein, a stable cell line constitutively expressing N-terminal domain of gene was made, but the overexpression of N-terminal domain didn't confer any antiviral immunity. Thus signifying importance of kinase activity in confering antiviral immunity. Our studies indicate for the first time that Tyki may have a role in host resistance to JEV and understanding the mechanism of action Tyki may pave way for novel anti-JEV therapy. Stable cell lines constitutively expressing other JEV-inducible genes (Atf3, Gimap3, Rtp4, Glipr2, Tmem140 and Garg49) couldn't be generated. Therefore, to study the effect of overexpression of these genes on JEV infection, expression vectors encoding these genes were transfected individually to human 293T cells by nucleofection, then infected with JEV and viral titres were examined by plaque assay. Nucleofection was opted as a method of choice since it is the only non-viral method, which transfects DNA directly enter the nucleus. In contrast, other commonly used non-viral transfection methods rely on cell division for the transfer of DNA into the nucleus. Nucleofection of vectors encoding different JEV-inducible genes followed by JEV infection and assay of viral titer led to identification of one more anti-viral gene and three pro-viral genes. Garg49, an interferon and JEV inducible mitochondrial gene was identified as antiviral gene. Further studies led to the identification of GARG49 as a mitochondrial protein. Three genes, Atf3, encoding a cAMP responsive element binding protein family transcription factor, Glipr2, encoding a Glioma related pathogenesis protein and Gimap3, encoding an outer mitochondrial membrane GTPase were identified as pro viral genes. Overexpression of Tmem140, encoding a transmembrane protein and Rtp4, encoding a golgi chaperone did not significantly affect JEV titer. Conclusions: . A JEV-resistant B16F10 murine melanoma cell line was identified and several JEV-inducible genes were found to be expressed constitutively at high levels in this cell line. .We demonstrate for the first time that Tyki/Ump-Cmpk2 encoding a mitochondrial nucleoside monophosphate kinase has an anti-JEV function and the C-terminal domain is essential for anti-viral activity. .Garg49/Ifit3 encodes an interferon and JEV-inducible mitochondrial protein and it has an anti-JEV function. . Activating transcription factor 3 (ATF3), GTPase, IMAP family member 3 (GIMAP3) and GLI pathogenesis-related 2 (GLIPR2) are pro-viral proteins which facilitate virus multiplication resulting in enhanced JEV titer.

Japanese Encephalitis Virus (JEV)

Virus-Host Interaction

Japanese Encephalitis Virus

Tyki

Garg49

JEV Resistant Murine Melanoma Cells

Flaviviruses

JEV-induced Host-Gene Expression

Pro-Viral Genes

Anti-Viral Genes

JEV Inducible Mouse Genes

Biochemistry

Caracterização da nucleoproteína e da fosfoproteína do vírus respiratório sincicial humano quanto a suas propriedades imunogênicas e de interação com proteínas celulares. / Characterization of Human Respiratory Syncytial Virus nucleoprotein and phosphoprotein immunogenic properties and interactions with cell proteins.

Oliveira, Andressa Peres de

13 November 2013

O Vírus Respiratório Sincicial Humano (HRSV) é um dos patógenos mais importantes do trato respiratório. Analisamos as interações das proteínas virais nucleoproteína (N), fosfoproteína (P) e matriz (M) em células HEK-293T. N interage com as proteínas celulares Hsp70, PRMT5 e WDR77; P com Hsp70 e Tropomiosina; e M com Nucleofosmina e Tropomiosina. Cada gene celular foi co-expresso em bactérias com um gene viral possibilitando a co-precipitação das proteínas. Analisamos a interação entre Hsp70 e N ou P, confirmando sua ocorrência em bactérias. Com um conjunto de proteínas mutantes, definimos que as interações são através dos amino terminais de N e P, ou do carboxi terminal de P, e do domínio amino terminal de Hsp70. Superexpressão de Hsp70 por transfecção provocou efeito de estímulo sobre a replicação de HRSV. Imunizações em camundongos com vacinas de DNA para N e P mostraram a indução de resposta celular e humoral. Ensaios de desafio resultaram em redução da carga viral após imunização com N, indicando potencial para sua aplicação em formulação vacinal. / Human respiratory syncytial virus (HRSV) is one of the most important pathogens of the respiratory tract. We analyzed the interactions of viral nucleoprotein (N), phosphoprotein (P) and matrix (M) in HEK-293T. N interacts with the cellular proteins Hsp70, PRMT5 and WDR77; P interacts with Hsp70 and Tropomyosin; and M with Nucleophosmin and Tropomyosin. Each cellular gene was co-expressed with a viral gene in bacteria allowing co-precipitation of proteins. Hsp70 co-expression with N or P proteins confirmed that these interactions also occur in bacteria. Using a set of mutants we found that the N and P amino terminus, P carboxy terminus, and Hsp70 amino terminal domain participate in the interactions. The overexpression of Hsp70 by transfection resulted in stimulation of HRSV replication. Mice immunization with N and P showed that DNA vaccines were capable of inducing humoral and cellular response. In challenge assays it was possible to detect significant virus titer reduction in animals immunized with N, indicating its potential for a vaccine formulation.

Cellular interactions

DNA viral

Genes virais

Immunization

Imunização

Interações celulares

Vacinas virais

Viral DNA

Viral genes

Viral vaccines

Variabilidade genética da proteína G do HRSV de amostras com o genótipo BA. / Genetic variability of the G protein of HRSV samples with BA genotype.

Nascimento, Cesar Augusto do

25 March 2011

Para estudar a epidemiologia e evolução do novo genótipo HRSVB denominado BA, caracterizado pela duplicação de 60 nt na proteína G, analisamos 4274 amostras clínicas coletadas de crianças hospitalizadas no Hospital Universitário/USP e Hospital da Santa Casa de Misericórdia, cidade de São Paulo entre os anos de 2001 e 2009. As amostras foram submetidas a RT-PCR seguido do sequenciamento da região G2 do gene G. A duplicação de 60 nt foi detectada em 104 (28.3%) das 367 amostras analisadas. De 2001 a 2004 a circulação do genótipo BA foi baixa, seguido de 85.4% (2005), 57.6% (2006), sem circulação (2007), 10% (2008) e 75% (2009) do total de amostras sequenciadas. As sequências foram comparadas com outras BA de diversos países do mundo. A análise filogenética preliminar dividiu as amostras brasileiras em 5 grupos (BA-I, BAII, BAIII, BAIV e BAVI), sendo que a maioria das amostras de 2005 a 2009 agruparam juntas na linhagem BA-IV, estabelecendo um grupo temporal e geográfico. / In order to study the epidemiology and evolution of the new genotype of HRSVB named BA characterized with a 60-nt duplication in the G protein we analyzed 4274 clinical samples collected from children hospitalized in University Hospital/USP and Santa Casa de Misericórdia Hospital, in São Paulo city, during 2001 to 2009. The samples were subject to RT-PCR followed by sequencing of the G2 region of the G gene. The 60 nt-duplication were detected in 104 (28.3%) of 367 sequencing samples. From 2001 to 2004 the circulation of the BA genotype was low, followed by 85.4% (2005), 57.6% (2006), no circulation (2007), 10% (2008) and 75% (2009) of total sequencing samples. Sequences were compared with G sequences with the 60 nt-duplication globally sampled. Preliminary phylogenetic analysis divided Brazilian samples into five clusters (BA-I, BAII, BAIII and BAVI and BAIV), and almost all samples from 2005 to 2009 were clustered together in BA-IV lineage, establishing temporal and geographical cluster.

Evolução fenotípica

Genes virais

Genetic sequencing

Genetic variation

Genótipos

Genotypes

Phenotypic evolution

Sequenciamento genético

Variação genética

Viral genes

Estudo genético da variante do vírus da raiva mantida por populações do morcego hematófago Desmodus rotundus. / Genetic study from Rabies vírus variant maintained by hematophagous bats Desmodus rotundus population.

Campos, Angélica Cristine de Almeida

27 April 2011

Dados da Organização Mundial da Saúde (OMS) mostram que a raiva é um problema de saúde pública podendo acarretar sérios prejuízos ambientais e econômicos, a despeito da existência de vacinas eficazes de uso humano e veterinário. Segundo seu último informe, estima-se que no mundo em torno de 55.000 pessoas por ano morrem de raiva. O cão permanece como principal transmissor da raiva para o homem e também como principal vítima da doença. Nos países que conseguiram controlar a raiva em animais domésticos, o vírus se mantém circulante na natureza por meio dos animais silvestres, sendo os morcegos apontados como a segunda espécie transmissora da raiva a humanos. Os Lyssavirus têm sido detectados em morcegos, em diversos continentes, sendo identificados como transmissor em dez das onze espécies de Lyssavirus. Fósseis de morcego mostram sua presença há 50 milhões de anos. Mas somente em 1911, Carini relacionou pela primeira vez a raiva aos morcegos, levantando a hipótese destes serem os transmissores da doença a outros animais. Há registros de que o vírus da raiva foi isolado em pelo menos 41 das 167 espécies de morcegos brasileiras, sendo que a maioria dessas espécies está relacionada a atividades humanas com a presença destes animais próximos ao local de trabalho e moradia das pessoas. Os morcegos hematófagos Desmodus rotundus são encontrados do norte do México até a costa norte do Chile, região central da Argentina e costa do Uruguai e com exceção do Chile. Esta espécie de morcego tem sido apontada como reservatório natural do vírus da raiva nesta região. Alguns pesquisadores observaram que a raiva em morcegos não hematófagos precede a raiva bovina e em animais de estimação, sugerindo que os morcegos não hematófagos podem ser o elo entre a raiva silvestre e a raiva urbana e o fato de se detectar a variante mantida por morcegos hematófagos Desmodus rotundus em cães e gatos mostra que o papel deste morcego no ciclo da raiva não está limitado à raiva silvestre. As características dos Lyssavirus adaptados a morcegos têm mostrado diferenças quando comparadas à raiva relacionada aos carnívoros, confirmando a necessidade do desenvolvimento de metodologias que permitam estudos complementares mais precisos a respeito da biologia e epidemiologia da raiva em quirópteros. A escassez de dados na literatura, até o momento, a respeito do genoma completo da variante do vírus da raiva mantida por populações de morcegos hematófagos Desmodus rotundus, deixa uma lacuna no entendimento da epidemiologia molecular deste vírus. A importância epidemiológica desta espécie na transmissão da raiva é inquestionável. Neste estudo foi sequenciado e analisado, o genoma da variante do vírus da raiva mantido por populações de morcego hematófago Desmodus rotundus isolado de um morcego hematófago Desmodus rotundus. A amostra, procedente de área endêmica no Estado de São Paulo, foi filogeneticamente comparada com o genoma da amostra padrão para a espécie viral 1 - Rabies virus e outras amostras pertencentes ao ciclo aéreo ou terrestre de transmissão, disponíveis no GenBank, identificando possíveis padrões de diferenciação, próprios do ciclo aéreo, e em alguns casos relacionados somente à variante estudada. / Data from the World Health Organization (WHO) show that rabies is a public health problem which can cause serious environmental and economic damage, despite the existence of effective vaccines for human and veterinary use. According to WHO latest report, estimated that worldwide around 55,000 people per year died of rabies. The dog remains the main transmitter of rabies to humans as well as the main victim of the disease. In countries that were successful in controlling rabies in domestic animals, the virus is still circulating in nature by wild animals and the bats are seen as the second species transmitting rabies to humans. The Lyssavirus have been detected in bats in several continents and is identified as a transmitter in ten of eleven species of Lyssavirus. Bat fossils show their presence for 50 million years. But only in 1911, in the first time Carini related to rabies at bats, raising the possibility of these being the transmitters of the disease to other animals. Reports show that the Rabies virus was isolated in at least 41 of the 167 species of bats in Brazil, with the majority of these species is related to human activities with the animals living near the local job and houses of people. The vampire bat Desmodus rotundus is found from northern Mexico to northern Chile coast, central coast of Argentina and Uruguay and with the exception of Chile. This bat species has been identified as a natural reservoir of the Rabies virus in this region. Some researchers observed that rabies into non-hematophagous bats precedes the bovine rabies and in pets, suggesting that the non-hematophagous bats may be the link between wildlife rabies and urban rabies and the fact that detect the variant maintained by vampire bats Desmodus rotundus in dogs and cats shows that the role of bat rabies in the cycle is not limited to wildlife rabies. The characteristics of Lyssavirus bat adapted have been shown differences when compared to rabies related to the carnivores, confirming the need to develop methods that enable more accurate follow-up studies about the biology and epidemiology of rabies in bats. The paucity of data in the literature to date about the complete genome of the Rabies virus variant maintained by populations of vampire bats Desmodus rotundus leaves a gap in understanding the molecular epidemiology of this virus and the epidemiological importance of this species in the transmission of Rabies virus is unquestionable. In this study we sequenced and analyzed the genome of the Rabies virus variant maintained by populations of bat Desmodus rotundus isolated from a bat Desmodus rotundus. The sample, coming from an endemic area in São Paulo, was phylogenetically compared with the genome of the standard sample for spcies 1 - Rabies virus and other samples belonging to the Terrestrial and Aerial cycles of transmission, available in GenBank, to identify possible patterns of differentiating themselves Aerial cycle and in some cases linked only to variant studied.

Rabies virus

Bats

Filogenia análise

Gene sequencing

Genes virais

Genomas

Genomes

Morcegos

Phylogenetic analysis

Sequenciamento genético

Viral genes

Vírus da raiva

Caracterização da nucleoproteína e da fosfoproteína do vírus respiratório sincicial humano quanto a suas propriedades imunogênicas e de interação com proteínas celulares. / Characterization of Human Respiratory Syncytial Virus nucleoprotein and phosphoprotein immunogenic properties and interactions with cell proteins.

Andressa Peres de Oliveira

13 November 2013

O Vírus Respiratório Sincicial Humano (HRSV) é um dos patógenos mais importantes do trato respiratório. Analisamos as interações das proteínas virais nucleoproteína (N), fosfoproteína (P) e matriz (M) em células HEK-293T. N interage com as proteínas celulares Hsp70, PRMT5 e WDR77; P com Hsp70 e Tropomiosina; e M com Nucleofosmina e Tropomiosina. Cada gene celular foi co-expresso em bactérias com um gene viral possibilitando a co-precipitação das proteínas. Analisamos a interação entre Hsp70 e N ou P, confirmando sua ocorrência em bactérias. Com um conjunto de proteínas mutantes, definimos que as interações são através dos amino terminais de N e P, ou do carboxi terminal de P, e do domínio amino terminal de Hsp70. Superexpressão de Hsp70 por transfecção provocou efeito de estímulo sobre a replicação de HRSV. Imunizações em camundongos com vacinas de DNA para N e P mostraram a indução de resposta celular e humoral. Ensaios de desafio resultaram em redução da carga viral após imunização com N, indicando potencial para sua aplicação em formulação vacinal. / Human respiratory syncytial virus (HRSV) is one of the most important pathogens of the respiratory tract. We analyzed the interactions of viral nucleoprotein (N), phosphoprotein (P) and matrix (M) in HEK-293T. N interacts with the cellular proteins Hsp70, PRMT5 and WDR77; P interacts with Hsp70 and Tropomyosin; and M with Nucleophosmin and Tropomyosin. Each cellular gene was co-expressed with a viral gene in bacteria allowing co-precipitation of proteins. Hsp70 co-expression with N or P proteins confirmed that these interactions also occur in bacteria. Using a set of mutants we found that the N and P amino terminus, P carboxy terminus, and Hsp70 amino terminal domain participate in the interactions. The overexpression of Hsp70 by transfection resulted in stimulation of HRSV replication. Mice immunization with N and P showed that DNA vaccines were capable of inducing humoral and cellular response. In challenge assays it was possible to detect significant virus titer reduction in animals immunized with N, indicating its potential for a vaccine formulation.

DNA viral

Genes virais

Imunização

Interações celulares

Vacinas virais

Cellular interactions

Immunization

Viral DNA

Viral genes

Viral vaccines

Variabilidade genética da proteína G do HRSV de amostras com o genótipo BA. / Genetic variability of the G protein of HRSV samples with BA genotype.

Cesar Augusto do Nascimento

25 March 2011

Para estudar a epidemiologia e evolução do novo genótipo HRSVB denominado BA, caracterizado pela duplicação de 60 nt na proteína G, analisamos 4274 amostras clínicas coletadas de crianças hospitalizadas no Hospital Universitário/USP e Hospital da Santa Casa de Misericórdia, cidade de São Paulo entre os anos de 2001 e 2009. As amostras foram submetidas a RT-PCR seguido do sequenciamento da região G2 do gene G. A duplicação de 60 nt foi detectada em 104 (28.3%) das 367 amostras analisadas. De 2001 a 2004 a circulação do genótipo BA foi baixa, seguido de 85.4% (2005), 57.6% (2006), sem circulação (2007), 10% (2008) e 75% (2009) do total de amostras sequenciadas. As sequências foram comparadas com outras BA de diversos países do mundo. A análise filogenética preliminar dividiu as amostras brasileiras em 5 grupos (BA-I, BAII, BAIII, BAIV e BAVI), sendo que a maioria das amostras de 2005 a 2009 agruparam juntas na linhagem BA-IV, estabelecendo um grupo temporal e geográfico. / In order to study the epidemiology and evolution of the new genotype of HRSVB named BA characterized with a 60-nt duplication in the G protein we analyzed 4274 clinical samples collected from children hospitalized in University Hospital/USP and Santa Casa de Misericórdia Hospital, in São Paulo city, during 2001 to 2009. The samples were subject to RT-PCR followed by sequencing of the G2 region of the G gene. The 60 nt-duplication were detected in 104 (28.3%) of 367 sequencing samples. From 2001 to 2004 the circulation of the BA genotype was low, followed by 85.4% (2005), 57.6% (2006), no circulation (2007), 10% (2008) and 75% (2009) of total sequencing samples. Sequences were compared with G sequences with the 60 nt-duplication globally sampled. Preliminary phylogenetic analysis divided Brazilian samples into five clusters (BA-I, BAII, BAIII and BAVI and BAIV), and almost all samples from 2005 to 2009 were clustered together in BA-IV lineage, establishing temporal and geographical cluster.

Evolução fenotípica

Genes virais

Genótipos

Sequenciamento genético

Variação genética

Genetic sequencing

Genetic variation

Genotypes

Phenotypic evolution

Viral genes

Estudo genético da variante do vírus da raiva mantida por populações do morcego hematófago Desmodus rotundus. / Genetic study from Rabies vírus variant maintained by hematophagous bats Desmodus rotundus population.

Angélica Cristine de Almeida Campos

27 April 2011

Dados da Organização Mundial da Saúde (OMS) mostram que a raiva é um problema de saúde pública podendo acarretar sérios prejuízos ambientais e econômicos, a despeito da existência de vacinas eficazes de uso humano e veterinário. Segundo seu último informe, estima-se que no mundo em torno de 55.000 pessoas por ano morrem de raiva. O cão permanece como principal transmissor da raiva para o homem e também como principal vítima da doença. Nos países que conseguiram controlar a raiva em animais domésticos, o vírus se mantém circulante na natureza por meio dos animais silvestres, sendo os morcegos apontados como a segunda espécie transmissora da raiva a humanos. Os Lyssavirus têm sido detectados em morcegos, em diversos continentes, sendo identificados como transmissor em dez das onze espécies de Lyssavirus. Fósseis de morcego mostram sua presença há 50 milhões de anos. Mas somente em 1911, Carini relacionou pela primeira vez a raiva aos morcegos, levantando a hipótese destes serem os transmissores da doença a outros animais. Há registros de que o vírus da raiva foi isolado em pelo menos 41 das 167 espécies de morcegos brasileiras, sendo que a maioria dessas espécies está relacionada a atividades humanas com a presença destes animais próximos ao local de trabalho e moradia das pessoas. Os morcegos hematófagos Desmodus rotundus são encontrados do norte do México até a costa norte do Chile, região central da Argentina e costa do Uruguai e com exceção do Chile. Esta espécie de morcego tem sido apontada como reservatório natural do vírus da raiva nesta região. Alguns pesquisadores observaram que a raiva em morcegos não hematófagos precede a raiva bovina e em animais de estimação, sugerindo que os morcegos não hematófagos podem ser o elo entre a raiva silvestre e a raiva urbana e o fato de se detectar a variante mantida por morcegos hematófagos Desmodus rotundus em cães e gatos mostra que o papel deste morcego no ciclo da raiva não está limitado à raiva silvestre. As características dos Lyssavirus adaptados a morcegos têm mostrado diferenças quando comparadas à raiva relacionada aos carnívoros, confirmando a necessidade do desenvolvimento de metodologias que permitam estudos complementares mais precisos a respeito da biologia e epidemiologia da raiva em quirópteros. A escassez de dados na literatura, até o momento, a respeito do genoma completo da variante do vírus da raiva mantida por populações de morcegos hematófagos Desmodus rotundus, deixa uma lacuna no entendimento da epidemiologia molecular deste vírus. A importância epidemiológica desta espécie na transmissão da raiva é inquestionável. Neste estudo foi sequenciado e analisado, o genoma da variante do vírus da raiva mantido por populações de morcego hematófago Desmodus rotundus isolado de um morcego hematófago Desmodus rotundus. A amostra, procedente de área endêmica no Estado de São Paulo, foi filogeneticamente comparada com o genoma da amostra padrão para a espécie viral 1 - Rabies virus e outras amostras pertencentes ao ciclo aéreo ou terrestre de transmissão, disponíveis no GenBank, identificando possíveis padrões de diferenciação, próprios do ciclo aéreo, e em alguns casos relacionados somente à variante estudada. / Data from the World Health Organization (WHO) show that rabies is a public health problem which can cause serious environmental and economic damage, despite the existence of effective vaccines for human and veterinary use. According to WHO latest report, estimated that worldwide around 55,000 people per year died of rabies. The dog remains the main transmitter of rabies to humans as well as the main victim of the disease. In countries that were successful in controlling rabies in domestic animals, the virus is still circulating in nature by wild animals and the bats are seen as the second species transmitting rabies to humans. The Lyssavirus have been detected in bats in several continents and is identified as a transmitter in ten of eleven species of Lyssavirus. Bat fossils show their presence for 50 million years. But only in 1911, in the first time Carini related to rabies at bats, raising the possibility of these being the transmitters of the disease to other animals. Reports show that the Rabies virus was isolated in at least 41 of the 167 species of bats in Brazil, with the majority of these species is related to human activities with the animals living near the local job and houses of people. The vampire bat Desmodus rotundus is found from northern Mexico to northern Chile coast, central coast of Argentina and Uruguay and with the exception of Chile. This bat species has been identified as a natural reservoir of the Rabies virus in this region. Some researchers observed that rabies into non-hematophagous bats precedes the bovine rabies and in pets, suggesting that the non-hematophagous bats may be the link between wildlife rabies and urban rabies and the fact that detect the variant maintained by vampire bats Desmodus rotundus in dogs and cats shows that the role of bat rabies in the cycle is not limited to wildlife rabies. The characteristics of Lyssavirus bat adapted have been shown differences when compared to rabies related to the carnivores, confirming the need to develop methods that enable more accurate follow-up studies about the biology and epidemiology of rabies in bats. The paucity of data in the literature to date about the complete genome of the Rabies virus variant maintained by populations of vampire bats Desmodus rotundus leaves a gap in understanding the molecular epidemiology of this virus and the epidemiological importance of this species in the transmission of Rabies virus is unquestionable. In this study we sequenced and analyzed the genome of the Rabies virus variant maintained by populations of bat Desmodus rotundus isolated from a bat Desmodus rotundus. The sample, coming from an endemic area in São Paulo, was phylogenetically compared with the genome of the standard sample for spcies 1 - Rabies virus and other samples belonging to the Terrestrial and Aerial cycles of transmission, available in GenBank, to identify possible patterns of differentiating themselves Aerial cycle and in some cases linked only to variant studied.

Filogenia análise

Genes virais

Genomas

Morcegos

Sequenciamento genético

Vírus da raiva

Rabies virus

Bats

Gene sequencing

Genomes

Phylogenetic analysis

Viral genes

Modulation of cellular and viral functions in Epstein-Barr virus infected cells /

Imreh, Marta P.,

January 2002

Diss. (sammanfattning) Stockholm : Karol. inst., 2002. / Härtill 5 uppsatser.