16 resultados para Reoviridae
Resumo:
Full-length and partial genome sequences of four members of the genus Aquareovirus, family Reoviridae (Golden shiner reovirus, Grass carp reovirus, Striped bass reovirus and golden ide reovirus) were characterized. Based on sequence comparison, the unclassified Grass carp reovirus was shown to be a member of the species Aquareovirus C The status of golden ide reovirus, another unclassified aquareovirus, was also examined. Sequence analysis showed that it did not belong to the species Aquareovirus A or C, but assessment of its relationship to the species Aquareovirus B, D, E and F was hampered by the absence of genetic data from these species. In agreement with previous reports of ultrastructural resemblance between aquareoviruses and orthoreoviruses, genetic analysis revealed homology in the genes of the two groups. This homology concerned eight of the 11 segments of the aquareovirus genome (amino acid identity 17-42%), and similar genetic organization was observed in two other segments. The conserved terminal sequences in the genomes of members of the two groups were also similar. These data are undoubtedly an indication of the common evolutionary origin of these viruses. This clear genetic relatedness between members of distinct genera is unique within the family Reoviridae. Such a genetic relationship is usually observed between members of a single genus. However, the current taxonomic classification of aquareoviruses and orthoreoviruses in two different genera is supported by a number of characteristics, including their distinct G+C contents, unequal numbers of genome segments, absence of an antigenic relationship, different cytopathic effects and specific econiches.
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The genome segments 1, 2, and 3 of the grass carp reovirus (GCRV), a tentative species assigned to genus Aquareouirus, family Reouiridae, were sequenced. The respective segments 1, 2, and 3 were 3949, 3877, and 3702 nucleotides long. Conserved moths 5' (GUUAUUU) and 3' (UUCAUC) were found at the ends of each segment. Each segment contains a single ORF and the negative strand does not permit identification of consistent ORFs. Sequence analysis revealed that VP2 is the viral polymerase, while VPI might represent the viral guanyly/methyl transferase (involved in the capping process of RNA transcripts) and VP3 the NTPase/helicase (involved in the transcription and capping of viral RNAs), The highest amino acid identities (26-41%) were found with orthoreovirus proteins. Further genomic characterization should provide insight about the genetic relationships between GCRV, aquareoviruses, and orthoreoviruses, It should also permit to precise the taxonomic status of these different viruses. (C) 2000 Academic Press.
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The complete nucleotide sequence of genome segment S4 of rice ragged stunt oryzavirus (RRSV, Thai-isolate) was determined. The 3823 bp sequence contains two large open reading frames (ORFs). ORF1, spanning nucleotides 12 to 3776, is capable of encoding a protein of M(r) 141,380 (P4a). The P4a amino acid sequence predicted from the nucleotide sequence contains sequence motifs conserved in RNA-dependent RNA polymerases (RDRPs). When compared for evolutionary relationships with RDRPs of other reoviruses using the amino acid sequences around the conserved GDD motif, P4a was shown to be more related to Nilaparvata lugens reovirus and reovirus serotype 3 than to rice dwarf phytoreovirus, bovine rotavirus or bluetongue virus. The ORF2, spanning nucleotides 491 to 1468, is out of frame with ORF1 and is capable of encoding a protein of 36, 920 (P4b). Coupled in vitro transcription-translation from cloned ORF2 in wheat germ extract confirmed the existence of ORF2 but in vivo production and possible function of P4b is yet to be determined.
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The nucleotide sequences of genome segments S7 and S10 of a Thai-isolate of rice ragged stunt virus (RRSV) were determined. The 1938 bp S7 sequence contains a single large open reading frame (ORF) spanning nucleotides 20 to 1 843 that is predicted to encode a protein of M(r) 68 025. The 1 162 bp S10 sequence has a major ORF spanning nucleotides 142 to 1 032 that is predicted to encode a protein of M(r) 32364. This S10 ORF is preceded by a small ORF (nt 20-55) which is probably a minicistron. Coupled in vitro transcription-translation from the two major ORFs gave protein products of the expected sizes. However, no protein was visualised from S10 when the small ORF sequence was included. Proteins were expressed in Escherichia coli from the full length ORF of S7 (P7) and from a segment of the S10 ORF (P10) fused to the ORF of glutathione S-transferase (GST). Neither fusion protein was recognised by polyclonal antibodies raised against RRSV particles. Furthermore, polyclonal antibodies raised against GST-P7 fusion protein did not recognise any virion structural polypeptides. These data strongly suggest that the proteins P7 and P10 do not form part of RRSV particle. This is further supported by observed sequence homology (though very weak) of predicted.
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The nucleotide sequence of DNA complementary to rice ragged stunt oryzavirus (RRSV) genome segment 8 (S8) of an isolate from Thailand was determined. RRSV S8 is 1 914 bp in size and contains a single large open reading frame (ORF) spanning nucleotides 23 to 1 810 which is capable of encoding a protein of M(r) 67 348. The N-terminal amino acid sequence of a ~43K virion polypeptide matched to that inferred for an internal region of the S8 coding sequence. These data suggest that the 43K protein is encoded by S8 and is derived by a proteolytic cleavage. Predicted polypeptide sizes from this possible cleavage of S8 protein are 26K and 42K. Polyclonal antibodies raised against a maltose binding protein (MBP)-S8 fusion polypeptide (expressed in Escherichia coli) recognised four RRSV particle associated polypeptides of M(r) 67K, 46K, 43K and 26K and all except the 26K polypeptide were also highly immunoreactive to polyclonal antibodies raised against purified RRSV particles. Cleavage of the MBP-S8 fusion polypeptide with protease Factor X produced the expected 40K MBP and two polypeptides of apparent M(r) 46K and 26K. Antibodies to purified RRSV particles reacted strongly with the intact fusion protein and the 46K cleavage product but weakly to the 26K product. Furthermore, in vitro transcription and translation of the S8 coding region revealed a post-translational self cleavage of the 67K polypeptide to 46K and 26K products. These data indicate that S8 encodes a structural polypeptide, the majority of which is auto- catalytically cleaved to 26K and 46K proteins. The data also suggest that the 26K protein is the self cleaving protease and that the 46K product is further processed or undergoes stable conformational changes to a ~43K major capsid protein.
Resumo:
The complete nucleotide sequence of the genome segment 5 (S5) of a Thai isolate of rice ragged stunt virus (RRSV) was determined. The 2682 nucleotide sequence contains a single long open reading frame capable of encoding a polypeptide with a molecular mass of ~91 kDa. Polypeptides encoded by various truncated cDNAs of S5 were expressed using the pGEX fusion protein vector and the highest level of fusion protein was obtained from a construct encoding a hydrophilic region of S5 protein. Antibodies raised against this fusion protein recognized a minor polypeptide, with a molecular mass of ~ 91 kDa, that was present in purified preparations of RRSV particles, infected insect vectors and infected rice plants. This indicates that RRSV S5 encodes a minor structural protein. Comparing the RRSV S5 sequence with sequences of other reo-viruses did not reveal any significant sequence similarities.
Resumo:
Fiji leaf gall, caused the Fiji disease virus (genus Fijivirus, family Reoviridae, FDV), is a serious disease of sugarcane, Saccharum officinarum L., in Australia and several other Asia-Pacific countries. In Australia FDV is transmitted only by the planthopper Perkinsiella saccharicida Kirkaldy (Hemiptera: Delphacidae), in a propagative manner. Successful transmission of FDV by single planthoppers confined to individual virus free plants is highly variable, even under controlled conditions. The research reported here addresses two possible sources of this variation: 1) gender, wing form, and life stage of the planthopper; and 2) genotype of the source plant. The acquisition of FDV by macropterous males, macropterous females, brachypterous females, and nymphs of P. saccharicida from infected plants was investigated using reverse transcription-polymerase chain reaction to diagnose FDV infection in the vector. The proportion of individuals infected with FDV was not statistically related to life stage, gender, or adult wing form of the vector. The acquisition of FDV by P. saccharicida from four cultivars of sugarcane was compared to assess the influence of plant genotype on acquisition. Those planthopper populations reared on diseased 'NCo310' plants had twice as many infected planthoppers as those reared on 'Q110', 'WD1', and 'WD2'. Therefore, variation in FDV acquisition in this system is not the result of variation in the gender, wing form and life stage of the P. saccharicida vectors. The cultivar used as the source plant to rear vector populations does affect the proportion of infected planthoppers in a population.
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En génétique dite « classique », l’examen d’un phénotype conduit à l’étude des gènes impliqués dans son obtention. La génétique inverse est une méthode expérimentale très puissante dans laquelle, au contraire, le matériel génétique est modifié et utilisé pour reconstruire un organisme complet, afin de déterminer le résultat de ces modifications. Cette approche est spécialement bien adaptée à l'étude des virus, compte tenu de la relative simplicité et de la petite taille de leurs génomes; l’obstacle principal demeure de récupérer des virus infectieux à partir de génomes viraux clonés. Au cours des années, cet exploit a été accompli pour des représentants de presque toutes les familles de virus de mammifères. Jusqu’à récemment, les Reoviridae, virus à génome d'ARN bicaténaire segmenté, faisaient toutefois exception. Dans cette revue, les progrès réalisés vers la mise au point de la génétique inverse pour l'étude du réovirus seront discutés. La génétique inverse pourrait avoir un impact majeur dans l'optimisation de nouvelles souches de réovirus pour leur utilisation en thérapie comme agents oncolytiques et pour le développement de vaccins dans le cas des rotavirus et des orbivirus. Les travaux actuels font toutefois ressortir les limites de l'approche, la nécessité d’une analyse prudente des résultats obtenus, ainsi que le besoin de développer des systèmes plus efficaces et polyvalents.
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Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)
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No Brasil, estima-se que os rotavírus causem 3.352.053 episódios de diarreia, 655.853 ambulatoriais, 92.453 hospitalizações e 850 mortes envolvendo crianças menores de 5 anos de idade. Os rotavírus pertencem à família Reoviridae, gênero Rotavirus. A partícula viral é constituída por três camadas proteicas concêntricas e pelo genoma viral reunindo 11 segmentos de RNA com dupla fita. Reconhecem-se 23 genótipos G e 31 genótipos P. Dentre os genótipos G detectados até o momento, o G2 atua como um dos mais importantes, estando geralmente associado ao genótipo P[4]. Nos últimos três anos se tem observado em larga escala global a reemergência do genótipo G2, sendo um dos mais detectados nos anos que sucederam a implantação da vacina contra rotavírus, particularmente no Brasil. Este estudo teve como objetivo a caracterização molecular de amostras do tipo G2 obtidas de crianças participantes de estudos em gastroenterites virais na região amazônica, Brasil, no período de 1992 a 2008. Foram selecionadas 53 amostras positivas para rotavírus genótipo G2 que foram sequenciadas para VP7 e 38 para VP4. Inicialmente, as amostras foram genotipadas por RT-PCR e seus produtos purificados, quantificados e sequenciados. As amostras também foram testadas quanto ao perfil de migração dos segmentos de RNA. As sequências obtidas dos genes VP4 e VP7 foram alinhadas e editadas no programa Bioedit (v.6.05) e comparadas a outras sequências de RV registradas no banco de genes utilizando o programa BLAST. A árvore filogenética foi feita utilizando o programa Mega 2.1. Do total de 53 amostras sequenciadas para o gene VP7, a análise filogenética revelou a existência de duas linhagens (II e III) e três sublinhagens (IIa, IIc, IId) que circularam em períodos diferentes na população. Amostras das sub-linhagem IIa e IIc apresentaram mutação na posição no aminoácido da posição 96 (Asp/ Asn) . Essa modificação pode resultar em uma alteração conformacional dos epítopos reconhecidos por anticorpos neutralizantes. As linhagens de G2 que circularam em Belém foram idênticas àquelas de outros Estados da região amazônica envolvidos no estudo. O gene VP[4] foi sequenciado na região da VP8*, sendo 36 pertencentes do genótipo P[4] e 3 ao P[6]. No genótipo P[4] foi identificada a circulação de duas linhagens, P[4]-4 ocorrendo nos anos de 1998-2000, e P[4]-5 que circulou nos períodos de 1993-1994 e 2006-2008. Nossos resultados reforçam dados de ocorrência continental que evidenciam a reemergência do genótipo G2 com a variante gênica IIc, a qual se estabeleceu na população em associação com o genótipo P[4]-5. A grande homologia entre as cepas de G2 que circularam entre os diferentes estados envolvidos no estudo sugere que as mutações registradas ultrapassaram barreiras geográficas e temporais.
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O rotavírus (RV) é o principal agente viral associado às gastrenterites, ocasionando em média 39% dos casos diarreicos que culminam em hospitalizações, sendo responsável por cerca de 520.000 óbitos entre crianças menores de cinco anos de idade a cada ano. Pertencem à família Reoviridae, gênero Rotavirus, possui RNA de dupla fita (dsRNA) com 11 segmentos codificando 12 proteínas, sendo seis estruturais (VPs) e seis não estruturais (NSPs). A proteína VP4, juntamente com a VP7, compõem a camada externa do RV, designando os genótipos P e G, respectivamente. Até o momento foram descritos 23 tipos G e 31 tipos P. O genótipo G9 emergiu em escala global e é possivelmente associado a manifestação clínica mais grave, estando geralmente acompanhado do genótipo P[8]. O genótipo G9 possui 6 linhagens distintas e o P[8] 4 linhagens. Este estudo objetivou caracterizar os genes VP7 e VP4 de RV do genótipo G9, circulantes na região metropolitana de Belém, Pará, no período de 1999 a 2007. O dsRNA viral de 38 amostras selecionadas foi extraído a partir das suspensões fecais e submetido à eletroforese em gel de poliacrilamida para determinação dos eletroferotipos, seguido da reação de seqüenciamento. Na presente investigação, foi possível a análise de 32 amostras selecionadas, sendo todas genótipo G9P[8] associadas ao eletroferotipo longo. A análise filogenética do gene VP7 demonstrou que as amostras G9 agruparam na linhagem 3 com elevados índices de similaridade, apresentando 8 substituições nucleotídicas. Contudo, apenas três modificações aminoacídicas foram observadas nas posições 43 (I→V), 66 (A→V) e 73 (Q→R), sendo estes resíduos 43 e 73 exclusivos das amostras do ano de 2007. A análise do gene VP4 demonstrou que as amostras P[8] agruparam na linhagem 3, identificando-se 15 substituições nucleotídicas, as quais ocasionaram quatro modificações aminoacídicas nos resíduos 108 (V→I), 172 (R→K), 173 (I→V) e 275 (K→R). As modificações nos resíduos 172 e 275 são exclusivos das amostras dos anos de 1999 a 2002. As amostras do presente estudo apresentaram elevada similaridade ao longo do tempo estudado. As amostras de 2007 foram as mais divergentes, tanto para o gene VP4 quanto para o gene VP7. É importante se proceder ao contínuo monitoramento do genótipo G9 na região metropolitana de Belém, a fim de detectar possíveis variantes emergentes que possam representar um desafio as estratégias de imunização atuais.
Resumo:
Os rotavírus são os principais agentes virais causadores de gastrenterite aguda e responsáveis por 36% dos casos hospitalizações entre crianças menores de cinco anos, resultando em 453.000 óbitos anualmente, principalmente em países em desenvolvimento. Pertencem à família Reoviridae, gênero Rotavirus, possui RNA de dupla fita (dsRNA) com 11 segmentos codificando 12 proteínas. O genótipo G1 se apresenta geralmente com maior frequência nas investigações epidemiológicas, circulando em várias partes do mundo sob diferentes prevalências. Este estudo teve como objetivo analisar a variabilidade genética dos genes VP4, VP7 e NSP4 dos rotavírus G1 circulantes nos municípios de Belém e Marituba, Pará, Brasil, no período de 1982 a 2008. Foram selecionadas 83 amostras previamente caracterizadas como G1 e submetidas a RT-PCR. Os espécimes foram provenientes de sete estudos realizados no IEC. Foi possível a amplificação para os três genes em estudo de 63 (75,9%) espécimes. Foram detectadas as linhagens 1 (8/63, 12,7 %), 2 (29/63, 46,0%), 3 (18/63, 28,6%) e 9 (8/63, 12,7%) para o gene VP7. Co-predominaram as sublinhagens 2E e 3A concorrendo com um total de 57,1% (36/63) das amostras. Foram observadas três substituições de aminoácidos (97 [D→E], 147 [S→N] e 218 [I→V]) no gene VP7 nas regiões antigênicas (A, B e C) nas amostras das linhagens 1, 2 e 9. Todas as amostras apresentaram a especificidade P[8] para o gene VP4 e as linhagens 2 (21/63, 33,3%) e 3 (42/63, 66,7%) foram detectadas. No gene da VP4 ocorreram duas alterações (35 [I→V] e 38 [S→G]) na região antigênica em todas as amostras analisadas. Para o gene NSP4, todas as amostras pertenceram ao tipo E1. Houve mudanças de nucleotídeos nas posições 47 (C→T) e 101 (T→C), resultando em alteração aminoacídica nos resíduos 16 (S→P) e 34 (L→P) em todas as amostras analisadas e nove espécimes demonstraram alteração no sítio de toxicidade da NSP4 (aa 131). Tal análise permitiu ampliar o conhecimento da diversidade genética e da circulação de variantes de rotavírus G1, representando o primeiro estudo da epidemiologia molecular deste genótipo no Brasil e confirmar a alta heterogeneidade que este tipo apresenta.
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Grass carp reovirus (GCRV) is a member of the Aquareovirus genus of the family Reoviridae, a large family of double-stranded RNA (dsRNA) viruses infecting plants, insects, fishes and mammals. We report the first subnanometer-resolution three-dimensional structures of both GCRV core and virion by cryoelectron microscopy. These structures have allowed the delineation of interactions among the over 1000 molecules in this enormous macromolecular machine and a detailed comparison with other dsRNA viruses at the secondary-structure level. The GCRV core structure shows that the inner proteins have strong structural similarities with those of orthoreoviruses even at the level of secondary-structure elements, indicating that the structures involved in viral dsRNA interaction and transcription are highly conserved. In contrast, the level of similarity in structures decreases in the proteins situated in the outer layers of the virion. The proteins involved in host recognition and attachment exhibit the least similarities to other members of Reoviridae. Furthermore, in GCRV, the RNA-translocating turrets are in an open state and lack a counterpart for the sigma1 protein situated on top of the close turrets observed in mammalian orthoreovirus. Interestingly, the distribution and the organization of GCRV core proteins resemble those of the cytoplasmic polyhedrosis virus, a cypovirus and the structurally simplest member of the Reoviridae family. Our results suggest that GCRV occupies a unique structure niche between the simpler cypoviruses and the considerably more complex mammalian orthoreovirus, thus providing an important model for understanding the structural and functional conservation and diversity of this enormous family of dsRNA viruses.
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Cytoplasmic polyhedrosis virus (CPV) is unique within the Reoviridae family in having a turreted single-layer capsid contained within polyhedrin inclusion bodies, yet being fully capable of cell entry and endogenous RNA transcription. Biochemical data have shown that the amino-terminal 79 residues of the CPV turret protein (TP) is sufficient to bring CPV or engineered proteins into the polyhedrin matrix for micro-encapsulation. Here we report the three-dimensional structure of CPV at 3.88 A resolution using single-particle cryo-electron microscopy. Our map clearly shows the turns and deep grooves of alpha-helices, the strand separation in beta-sheets, and densities for loops and many bulky side chains; thus permitting atomic model-building effort from cryo-electron microscopy maps. We observed a helix-to-beta-hairpin conformational change between the two conformational states of the capsid shell protein in the region directly interacting with genomic RNA. We have also discovered a messenger RNA release hole coupled with the mRNA capping machinery unique to CPV. Furthermore, we have identified the polyhedrin-binding domain, a structure that has potential in nanobiotechnology applications.