Nucleotide sequence analysis of VP7 gene of Indian isolates of bluetongue virus vis-à-vis other serotypes from different parts of the world.

Bluetongue virus (BTV), a member of genus Orbivirus, a family Reoviridae, is a non-enveloped with double shelled structure and ten segmented double stranded (ds) RNA genome. The RNA segment S7 encodes an inner capsid serogroup specific viral protein VP7. To amplify coding region of VP7 gene of BTV, new primers, forward primer (18-38 bp) and reverse primer (1156-1136 bp), were designed using VP7 gene sequences available in GenBank. This primer pair successfully amplified cell culture adapted Indian isolates of BTV belonging to two different serotypes 1 and 18. The coding sequences of two Indian isolates of BTV (BTV-1H and BTV-18B) were cloned into pPCR Script-Amp SK (+) plasmid vector and transformed into XL10-Gold Kan ultracompetent E. coli cells. The positive clones selected by blue-white screening and colony touch PCR were sequenced. The sequence analysis revealed that there was 93-97% nucleotide sequence identity in VP7 gene of three different Indian serotypes of BTV. The VP7 gene sequences of Indian isolates have comparatively less sequence homology (< 80%) with American (US), and French isolates compared to South African (SA), Australian (AUS) and Chinese (PRC) isolates. In silico restriction enzyme profile analysis of VP7 gene sequences revealed that Indian isolates of BTV-1 can be differentiated from other BTV-1 isolates reported from SA, AUS and PRC using TaqI. Similarly the Indian isolates of BTV belonging to three different serotypes can be differentiated using EcoRI, Hae III and TaqI restriction enzymes.     

VP2 gene based phylogenetic relationship of Indian isolates of Bluetongue virus serotype 1 and other serotypes from different parts of the world.

Bluetongue virus (BTV), a member of genus Orbivirus, family Reoviridae, is non-enveloped with double shelled structure and 10 segmented double stranded RNA genome. The RNA segment L2 encodes an outer capsid serotype specific viral protein VP2. BTV serotype 1 (BTV-1) specific novel primer pair, forward primer (1240-1271 bp) and reverse primer (1844-1813 bp), was designed using VP2 gene sequences available in GenBank to amplify 1240-1844 bp region because two hypervariable and three conserved regions have been reported within these 604 nucleotides. This primer pair successfully amplified cell culture adapted six Indian isolates of BTV-1. The 604 bp PCR product of VP2 gene of BTV-1 Avikanagar (A), Chennai (C) and Sirsa 3 (S3) Indian isolates were cloned in pPCR-Script Amp SK (+) vector and transformed into XL10-Gold Kan ultracompetent Epicurian coli cells. The positive clones selected by blue-white screening and colony touch PCR were sequenced. BTV-1A, C and S3 isolates revealed 99% nucleotide sequence identity within 1304-1844 bp region of VP2 gene. The partial VP2 gene sequences (1240-1844 bp region) revealed that BTV-1 Indian isolates were 89% identical with Australian (AUS) BTV-1 isolates while the identity with South African (SA) BTV-1 isolate was 75%. Phylogenetically, three BTV-1 Indian isolates formed one group which is closely related to BTV-1AUS isolates followed by BTV-1SA, BTV-2, 9, 23, 13, 17, 10 and 11 isolates from different parts of world. Based on partial VP2 gene sequences, it is concluded that Indian isolates of BTV-1 are closely related to BTV-1AUS isolates than BTV-1SA and other serotypes.     

Restriction analysis of conserved and variable regions of VP2 gene of Indian isolates of bluetongue virus serotype 1

Bluetongue virus (BTV) is a member of Orbivirus genus in family Reoviridae. The virus genome is composed of 10 double-stranded RNA segments. The RNA segment L2 encodes an outer capsid viral protein VP2, which is the main determinant of neutralization and serotype-specific immune response. BTV serotype 1 (BTV-1) specific novel primer pair was designed using VP2 gene sequences available in GenBank to amplify 1240-1844 bp region because two hypervariable and three conserved regions have been reported within these 604 nucleotides. This primer pair successfully amplified cell culture adapted six Indian isolates of BTV-1 from different geographical regions of the country. The 604 bp PCR product of VP2 gene of all six BTV-1 yielded two fragments of 273 and 331 bp when digested with Taq1 restriction enzyme. This indicated that there is only one TaqI site at 1513 bp (within 1240-1844 bp region) of VP2 gene of BTV-1 Indian isolates. The in silico restriction analysis revealed that in BTV-1 South African isolate (BTV-1SA) there is no TaqI site while in BTV-1 Australian isolates (BTV-1AUS), there are two TaqI sites (at 1513 and 1567 bp) within 1240-1844 bp region of VP2 gene. The earlier reported VP2 gene based primer pair for BTV-1 was used in the present study to amplify 2242-2933 bp region of six BTV-1 Indian isolates as three conserved regions have been reported within these 691 nucleotides. The digestion of 691 bp PCR products with XmnI yielded three fragments of 364, 173 and 154 bp with all the six Indian isolates of BTV-1 suggesting that there are two XmnI sites within 2242-2933 bp region of VP2 gene. A single XmnI site was observed in silico in BTV-1AUS and BTV-1SA isolates at different positions within this region. The in vitro and in silico restriction profile analyses of partial VP2 gene sequences using TaqI and XmnI restriction enzymes indicated a close relationship of Indian isolates of BTV-1 with BTV-1AUS isolates but not with BTV-1SA isolate.     

Preliminary crystallographic study of bluetongue virus capsid protein, VP7.

Bluetongue virus serotype 10 (BTV-10) VP7, expressed by insect cells infected with the recombinant baculovirus, has been purified and crystallized. Two crystal forms suitable for X-ray analysis have been obtained. Type I crystals belong to space group P6(3)22 with a = b = 95.2 A, c = 181.0 A, alpha = beta = 90 degrees gamma = 120.0 degrees, and contain a single subunit in the crystallographic asymmetric unit. They diffract to dmin = 3.0 A. Type II crystals belong to space group P2(1) with a = 69.4 A, b = 97.1 A, c = 71.4 A, beta = 109.0 degrees, and contain a trimer in the crystallographic asymmetric unit. They diffract to dmin = 2.1 A. These results, together with solution studies, show that the molecule is a trimer.     

Crystal structure of the top domain of African horse sickness virus VP7: comparisons with bluetongue virus VP7.

The baculovirus-expressed core protein VP7 of African horse sickness virus serotype 4 (AHSV-4) has been purified to homogeneity and crystallized in the presence of 2.8 M urea. The X-ray structure has been solved to a 2.3-Angstroms (1 Angstrom = 0.1 nm) resolution with an Rfactor of 19.8%. The structure of AHSV VP7 reveals that during crystallization, the two-domain protein is cleaved and only the top domain remains. A similar problem was encountered previously with bluetongue virus (BTV) VP7 (whose structure has been reported), showing that the connections between the top and the bottom domains are rather weak for these two distinct orbiviruses. The top domains of both BTV and AHSV VP7 are trimeric and structurally very similar. The electron density maps show that they both possess an extra electron density feature along their molecular threefold axes, which is most likely due to an unidentified ion. The characteristics of the molecular surface of BTV and AHSV VP7 suggest why AHSV VP7 is much less soluble than BTV VP7 and indicate the possibility of attachment to the cell via attachment of an Arg-Gly-Asp (RGD) motif in the top domain of VP7 to a cellular integrin for both of these orbiviruses.     

High-resolution phylogenetic analysis of hepatitis C virus adaptation and its relationship to disease progression

Hepatitis C virus (HCV) persists in the majority of those infected despite host immune responses. Evidence has accrued that selectively fixed mutations in the envelope genes (E1 and E2) are associated with viral persistence, particularly those that occur within the first hypervariable region of E2 (HVR1). However, the individual amino acid residues under selection have not been identified, nor have their selection pressures been measured, despite the importance of this information for understanding disease pathogenesis and for vaccine design. We performed a high-resolution analysis of published gene sequence data from individuals undergoing acute HCV infection, employing two phylogenetic methods to determine site-specific selection pressures. Strikingly, we found a statistically significant association between the number of sites selected and disease outcome, with the fewest selected sites in fulminant HCV cases and the greatest number of selected sites in rapid progressors, reflecting the duration and intensity of the arms race between host and virus. Moreover, sites outside the HVR1 appear to play a major role in viral evolution and pathogenesis, although there was no association between viral persistence and specific mutations in E1 and E2. Our analysis therefore allows fine dissection of immune selection pressures, which may be more diverse than previously thought. Such analyses could play a similarly informative role in studies of other persistent virus infections, such as human immunodeficiency virus.     

RGD tripeptide of bluetongue virus VP7 protein is responsible for core attachment to Culicoides cells

Bluetongue virus (BTV) is an arthropod-borne virus transmitted by Culicoides species to vertebrate hosts. The double-capsid virion is infectious for Culicoides vector and mammalian cells, while the inner core is infectious for only Culicoides-derived cells. The recently determined crystal structure of the BTV core has revealed an accessible RGD motif between amino acids 168 to 170 of the outer core protein VP7, whose structure and position would be consistent with a role in cell entry. To delineate the biological role of the RGD sequence within VP7, we have introduced point mutations in the RGD tripeptide and generated three recombinant baculoviruses, each expressing a mutant derivative of VP7 (VP7-AGD, VP7-ADL, and VP7-AGQ). Each expressed mutant protein was purified, and the oligomeric nature and secondary structure of each was compared with those of the wild-type (wt) VP7 molecule. Each mutant VP7 protein was used to generate empty core-like particles (CLPs) and were shown to be biochemically and morphologically identical to those of wt CLPs. However, when mutant CLPs were used in an in vitro cell binding assay, each showed reduced binding to Culicoides cells compared to wt CLPs. Twelve monoclonal antibodies (MAbs) was generated using purified VP7 or CLPs as a source of antigen and were utilized for epitope mapping with available chimeric VP7 molecules and the RGD mutants. Several MAbs bound to the RGD motif on the core, as shown by immunogold labeling and cryoelectron microscopy. RGD-specific MAb H1.5, but not those directed to other regions of the core, inhibited the binding activity of CLPs to the Culicoides cell surface. Together, these data indicate that the RGD motif present on BTV VP7 is responsible for Culicoides cell binding activity.     

Genomic sequences of Australian bluetongue virus prototype serotypes reveal global relationships and possible routes of entry into Australia

Bluetongue virus (BTV) is transmitted by biting midges (Culicoides spp.). It causes disease mainly in sheep and occasionally in cattle and other species. BTV has spread into northern Europe, causing disease in sheep and cattle. The introduction of new serotypes, changes in vector species, and climate change have contributed to these changes. Ten BTV serotypes have been isolated in Australia without apparent associated disease. Simplified methods for preferential isolation of double-stranded RNA (dsRNA) and template preparation enabled high-throughput sequencing of the 10 genome segments of all Australian BTV prototype serotypes. Phylogenetic analysis reinforced the Western and Eastern topotypes previously characterized but revealed unique features of several Australian BTVs. Many of the Australian BTV genome segments (Seg-) were closely related, clustering together within the Eastern topotypes. A novel Australian topotype for Seg-5 (NS1) was identified, with taxa spread across several serotypes and over time. Seg-1, -2, -3, -4, -6, -7, -9, and -10 of BTV_2_AUS_2008 were most closely related to the cognate segments of viruses from Taiwan and Asia and not other Australian viruses, supporting the conclusion that BTV_2 entered Australia recently. The Australian BTV_15_AUS_1982 prototype was revealed to be unusual among the Australian BTV isolates, with Seg-3 and -8 distantly related to other BTV sequences from all serotypes.     

Detection of polymorphism and sequence characterization of toll-like receptor 7 gene of Indian goat revealing close relationship between ruminant species

In this study, approximately 3.4?kb nucleotide sequence of caprine TLR7 (Toll-like receptor 7) gene was generated from twelve different Indian goat breeds belonging to different geographical regions. Goat TLR7 gene ORF (Open Reading Frame) was found to be 3141 nucleotides long coding for 1046?amino acids similar to sheep. The sequence analysis at nucleotide level revealed goat TLR7 having 99.5% homology with sheep, followed by other livestock species. Simple Modular Architecture Research Tool (SMART) was used for the structural analysis of goat TLR7 that showed the presence of 22 leucine rich repeats (LRRs) along with single Toll/interleukin-1 receptor (TIR) domains. TIR domain, when compared, was found to be similar in ruminant species, goat, sheep, cattle, and buffalo. The phylogenetic analysis also revealed grouping of all ruminant species together, goat being closer to sheep followed by cattle and buffalo. A total of 22 polymorphic sites were observed in TLR7 gene of 24 goats representing 12 different breeds, out of which 19 were present within the coding region and three in 3'UTR. Out of the seven nonsynonymous SNPs, two were in ectodomains and one in TIR domain. Overall our results indicate substantial variation within goat TLR7 gene, which could be exploited for association with disease susceptibility.     

羊轮状病毒NT株VP1基因的测序和分子进化分析

摘要：【目的】为了研究羊轮状病毒NT株VP1基因的遗传进化规律,【方法】根据GenBank中相关VP1基因的保守序列,设计合成引物,扩增NT株VP1基因并进行克隆测序和序列分析。【结果】 氨基酸序列比较表明NT株与其他毒株VP1基因的相似性为77.3%～98.4%,且氨基酸突变多发生在VP1蛋白的非功能区。VP1蛋白进化树表明NT株与牛轮状病毒处于同一进化分支,有较近的亲缘关系。结合26株具有代表性的轮状病毒,计算毒株间VP1基因的核苷酸和氨基酸进化距离,并对核苷酸的同义突变率（dS）和非同义突变率（dN）进行研究,发现dN/dS的比值小于1,说明同义替代是VP1基因在进化过程中的主要变异。【结论】本文首次对羊轮状病毒NT株进行了VP1基因的测序,并对VP1基因的进化距离和进化规律进行深入探讨。     

Sequence analysis of the respiratory syncytial virus phosphoprotein gene.

A recombinant cDNA plasmid (pRSA3) containing an almost full-length copy of the mRNA encoding respiratory syncytial virus phosphoprotein was identified in a cDNA library prepared with mRNA from respiratory syncytial virus-infected cells. The cDNA insert was sequenced, and a protein of 27,150 daltons was deduced from the DNA sequence. The protein is relatively acidic, containing two clusters of acidic amino acids, one in the middle of the molecule and the other at the C-terminus. It is devoid of both cysteine and tryptophan. There was no other potential reading frame within the phosphoprotein gene of respiratory syncytial virus. This situation is unlike that with Sendai virus, a paramyxovirus, which has a nonstructural C protein encoded by a second overlapping reading frame near the 5' end of the mRNA for phosphoprotein.     

A single point mutation in the VP7 major core protein of bluetongue virus prevents the formation of core-like particles.

To understand the assembly process of bluetongue virus (BTV), we have established a functional assay which allows us to produce and manipulate BTV core-like particles (CLPs) composed of the viral VP7 and VP3 proteins. A cDNA clone encoding the 349-amino-acid VP7 protein has been manipulated to generate deletion, extension, and site-specific mutants. Each mutant was coexpressed with the BTV VP3 protein to generate CLPs. Deletion and extension mutants involving the VP7 carboxy terminus prevented CLP formation, while an extension mutant involving an 11-amino-acid rabies virus sequence added to the amino terminus of VP7 allowed CLP formation. Substitution of either of two cysteine residues of VP7 (Cys-15 or Cys-65) by serine also did not prevent CLP formation; however, substitution of the single lysine residue of VP7 (Lys-255) by leucine abrogated CLP formation, indicating a critical role for this lysine.     

Use of PCR and nucleotide sequence analysis of the VP7 gene for detection of bovine rotaviruses and identification of their G serotypes

A Vp7 gene fragment PCR protocol was developed to detect the bovine rotaviruses and to identify their G serotypes. The most widespread bovine rotaviruses of G serotypes (G6, G8 and G10) can be distinguished on the basis of the PCR fragment size, while other G serotypes can be differentiated through a comparative analysis of the VP7 gene fragment nuclcotide sequence. Twenty-four bovine rotavirus field isolates were detected, and their G stereotypes were determined by using the method in question. Fourteen isolates were shown to be of G6 serotype; four of them were of G8, five--of G10, and one isolate was of G11 serotype. A possibility of detecting more than one isolate by this method was shown. Finally, a feasibility of using the method for searching for rotaviruses of new bovine rotavirus G serotypes and for rotaviruses, which do not belong to a so far described G serotypes, is discussed.     

Sequence analysis of amphotropic and 10A1 murine leukemia viruses: close relationship to mink cell focus-inducing viruses.

Viral interference studies have demonstrated the existence of four distinct murine leukemia virus (MuLV) receptors on NIH 3T3 mouse cells. The four viral interference groups are ecotropic MuLV; mink cell focus inducing virus (MCF); amphotropic MuLV; and 10A1, a recombinant derivative of amphotropic MuLV that uses a unique receptor but also retains affinity for the amphotropic MuLV receptor. We report here that 10A1 infects rat and hamster cells, unlike its amphotropic parent. We isolated an infectious molecular clone of 10A1 and present here the sequences of the env genes and enhancer regions of amphotropic MuLV and 10A1. The deduced amino acid sequences of amphotropic MuLV and 10A1 gp70su are remarkably similar to those of MCF and xenotropic MuLV (for which mouse cells lack receptors), with 64% amino acids identical in the four groups. We generated a consensus from these comparisons. Further, the differences are largely localized to a few discrete regions: (i) amphotropic MuLV has two short insertions relative to MCF, at residues 87 to 92 and 163 to 169, and (ii) amphotropic MuLV and MCF are totally different in a hypervariable region, which is greater than 30% proline, at residues approximately 253 to 304. 10A1 closely resembles amphotropic MuLV in its N terminus but contains an MCF-type hypervariable region. These results suggest the possibility that receptor specificity is localized in these short variable regions and further that the unique receptor specificity of 10A1 is due to the novel combination of amphotropic MuLV and MCF sequences rather than to the presence of any novel sequences. The Env proteins of ecotropic MuLV are far more distantly related to those of the other four groups than the latter are to each other. We also found that the enhancer regions of amphotropic MuLV and 10A1 are nearly identical, although 10A1 is far more leukemogenic than amphotropic MuLV.     

Sequence analysis of 16S rRNA gene inRhinosporidium seeberi shows similarity to plant chloroplast DNA

Identity of causative agent of rhinosporidiosis (Rhinosporidium seeberi) has been controversial since the disease was described in 1900. Extensive sequence alignments and phylogenetic analyses of 16S rRNA gene detected recently by us in R. seeberi , revealed 99% similarity with 16S rDNA in chloroplasts of flowering plants. Study demonstrates R. seeberi is a pigmented prokaryote displaying some characteristics of cyanobacteria, and contains 16S rDNA present in chloroplasts of all groups of land plants. This study and our recent publication of 2006 are the first molecular studies using purified organismal DNA extracted from R. seeberi free of infected tissue. ABBREVIATIONS: RB - Round body.