Sequence comparison of pigeon circoviruses

The genome sequences of eight pigeon circoviruses (PiCV) were determined and compared with four previously published sequences. The viruses compared were from the USA, five European countries, China and Australia and included PiCVs from racing, feral, ornamental and meat pigeons and a Senegal dove (Streptopelia senegalensis). The 12 PiCV genomes, ranging from 2032 to 2040 nucleotides in length, displayed similar organizations. Pairwise comparisons showed that the genome nucleotide sequence identities ranged from 85.1% to 97.8% and that the amino acid identities of the putative replication associated (Rep) and putative capsid (Cap) proteins displayed ranges of 91.5-99.1% and 73.0-99.3%, respectively. Comparative analyses identified conserved nucleotide sequences within the Rep gene and 3' intergenic regions, which would be suitable for diagnostic PCR primers, and variable amino acid sequences within the capsid proteins, which should be considered when selecting virus isolates for vaccine development.     

Genetic analysis of feline caliciviruses associated with a hemorrhagic-like disease.

Feline calicivirus (FCV) is 1 of the most common causes of upper respiratory tract disease in cats. Other disease syndromes associated with FCV infection have been reported. Recently, calicivirus infection associated with a hemorrhagic-like disease leading to significant mortality in cats has been reported. The clinical signs are similar to those observed with the calicivirus of rabbit hemorrhagic disease. This study characterized 2 FCV isolates associated with hemorrhagic-like disease. Nucleotide sequencing of the complete genome has been done for these 2 isolates as well as for 4 additional isolates representing other disease syndromes. Previously reported sequence data for the entire genome of classical FCV (6 isolates) and a portion of the capsid gene for hemorrhagic-like FCV (3 isolates), isolated in different regions of United States were used in the genetic analysis. Sequence data were used to determine relationships among the isolates and any correlation with phenotype. Nucleotide sequence comparisons of the entire genome and individual open reading frames revealed high homology among all isolates. Data suggest that the virulence may have genetic determinants on the basis of phylogenetic clustering of the isolates associated with hemorrhagic-like disease.     

Genetic characterization of 2 novel feline caliciviruses isolated from cats with idiopathic lower urinary tract disease

Feline caliciviruses (FCVs) are potential etiologic agents in feline idiopathic lower urinary tract disease (I-LUTD). By means of a modified virus isolation method, we examined urine obtained from 28 male and female cats with nonobstructive I-LUTD, 12 male cats with obstructive I-LUTD, and 18 clinically healthy male and female cats. All cats had been routinely vaccinated for FCV. Two FCVs were isolated; I (FCV-U1) from a female cat with nonobstructive I-LUTD, and another (FCV-U2) from a male cat with obstructive I-LUTD. To determine the genetic relationship of FCV-U1 and FCV-U2 to other FCVs. capsid protein gene RNA was reverse transcribed into cDNA, amplified, and sequenced. Multiple amino acid sequence alignments and phylogenetic trees were constructed for the entire capsid protein, hypervariable region E, and the more conserved (nonhypervariable) regions A, B, D, and F. When compared to 23 other FCV isolates with known biotypes, the overall amino acid sequence identity of the capsid protein of FCV-U1 and FCV-U2 ranged from 83 to 96%; identity of hypervariable regions C and E ranged from 58 to 85%. Phylogenetically, FCV-U1 clearly separated from other FCV strains in phenograms based on nonhypervariable regions. In contrast, FCV-U2 consistently segregated with the Urbana strain in all phenograms. Clustering of isolates by geographic origin was most apparent in phenograms based on nonhypervariable regions. No clustering of isolates by biotype was apparent in any phenograms. Our results indicate that FCV-UI and FCV-U2 are genetically distinct from other known vaccine and field strains of FCV.     

Sequence variation within the capsid protein of Australian isolates of feline calicivirus.

The capsid protein of Australian feline calicivirus (FCV) isolates is demonstrably different from the prototype strain F9. Five Australian isolates of FCV, dating from 1970 to 1989, were analysed by western blotting and immunoprecipitation. Varying reactivity to a panel of F9 specific monoclonal antibodies (MAbs) was observed. DNA sequencing of RT-PCR generated clones supported the observation of variation between capsid proteins. Predicted amino acid sequences varied by 11 to 17.5% across the whole capsid when compared to the published F9 sequence. Differences in amino acid sequence were most apparent in previously described hypervariable regions (C and E). Within hypervariable region E differences of 22 to 34% were observed compared to F9. The observed lack of reactivity to F9 MAbs correlated with amino acid changes within previously characterized binding sites within region E.     

Analysis of the N-terminal polypeptide of the capsid precursor protein and the ORF3 product of feline calicivirus.

The N-terminal unique polypeptide region of the capsid precursor protein of feline calicivirus (FCV) and the protein encoded by ORF3 of FCV were expressed as fusion proteins with glutathione S-transferase to analyze the expressed products in FCV-infected cells. Immunoblot analysis using a serum from a cat experimentally infected with FCV indicated relatively high immunogenicity of the N-terminal polypeptide in FCV-infected cats, as compared with the ORF3 protein. Specific antisera were prepared by immunization to mice with the fused proteins and used in immunoblot analysis. A 14 kD product corresponding to the N-terminal polypeptide and a 10 kD polypeptide of the ORF3 product were identified in the FCV-infected cells but not detected in the purified particles. No neutralization activity against FCV was detected in these antisera. The proteins identified as polypeptides of 14 kD and 10 kD in this study may have functions as non-structural proteins.     

Genogrouping of Vaccine Breakdown Strains (VBS) of Feline Calicivirus in Japan

Although prevention of feline calcivirus (FCV) infection by vaccination has been attempted, and isolation of FCV, development of the disease, and a few fatal cases in vaccinated cats have been reported. Fifteen FCV strains isolated from cats that had been vaccinated with commercially available FCV vaccines (F9, FCV-255, and FC-7) were genogrouped. Molecular analysis of viral genomes involved the construction of a phylogenetic tree of capsid genes using the NJ method. Cat anti-F9 serum and rabbit anti-FCV-255 serum were used for virus neutralization tests. Molecular phylogenetic analysis of the amino acid sequences of 15 virus isolates and those of the previously published and GenBank-deposited 9 global and 14 Japanese strains showed that 8 (53%) of the 15 virus isolates as well as the vaccine strains F9 and FCV-255 belonged to genogroup I (G_AI), and 7 (47%) belonged to genogroup II (G_AII). Of the 8 G_AI strains, 2 were isolated from cats that had been vaccinated with an F9 strain live vaccine, 5 from cats vaccinated with an FCV-255-derived vaccine, and 1 from a cat vaccinated with an FC-7-derived vaccine. Of the 7 G_AII strains, 5 were isolated from cats that had been vaccinated with the F9 strain live vaccine, 1 from a cat vaccinated with the FCV-255-derived vaccine, and 1 from a cat vaccinated with the FC-7-derived vaccine. These results indicate that more vaccine breakdown strains isolated from the cats vaccinated with the F9 strain-derived vaccine belong to G_AII than to G_AI, whereas more vaccine breakdown strains isolated from the cats vaccinated with the FCV-255 strain-derived vaccine belong to G_AI than to G_AII, and that when the FC-7 strain-derived vaccine is used, the vaccine breakdown strains belong almost equally to G_AI and G_AII. Thus, the genogroups of virus isolates varied with the vaccine strain used (p < 0.05). On the other hand, the neutralizing titres of feline anti-F9 serum and rabbit anti-FCV-255 serum against the 15 isolates were very low, showing no relationships between neutralizing antibody titres and genogroups. The DNA sequence identities between the virus isolates and the vaccine strains were low, at 70.6–82.9%, and no strains were found to have sequences derived from the vaccine strains. Alignment of amino acid sequences showed that the G_AI or G_AII virus isolates from the F9-vaccinated cats differed at position 428 of the 5’ hypervariable region (HVR) of capsid region of the F9 strain, whereas those from the FCV-255-vaccinated cats differed at positions 438, 453, and 460 of the 5’HVR of capsid region E of the F9 strain. We speculate that these differences influence genogrouping. The amino acid changes within the F9 linear epitopes common to G _A I and G _A II were noted at positions 450, 451, 457 of 5’HVR of the capsid region E in the isolates from F9-derived vaccine-treated cats, and 449, 450, and 451 of 5’HVR of capsid region E in the isolates from FCV-255-derived vaccine-treated cats, suggesting that these amino acid changes are involved in escapes. These results suggest that alternate vaccination with the F9 and FCV-255 strains or the use of a polyvalent vaccine containing G_AII strains serves to inhibit development.     

A universal polymerase chain reaction for the detection of psittacine beak and feather disease virus.

A universal PCR assay was designed that consistently detected psittacine beak and feather disease virus (BFDV) in psittacine birds affected with psittacine beak and feather disease (PBFD) from different geographic regions across Australia. Primers within open reading frame 1 (ORF1) of the BFDV genome consistently amplified a 717 bp product from blood and/or feathers of 32 birds with PBFD lesions. The PCR did not amplify a product from the feathers or blood from 7 clinically normal psittacine birds. Primers based on regions outside of ORF1 did not consistently produce a PCR product, suggesting there was some genomic variation outside ORF1. The amplified ORF1 PCR products of 10 BFDV isolates, from different psittacine species and from various regions around Australia, were cloned and comparative DNA sequence analysis demonstrated 88-99% of the ORF1 fragments. The derived amino acid sequences of the amplified ORF1 fragments demonstrated similar identity between all 10 isolates. Within ORF1, there was complete conservation of the putative nucleotide binding site and marked conservation of 2 other motifs previously identified as essential components of the replication-associated proteins of other circoviruses and geminiviruses.     

1株猫杯状病毒的分离鉴定及其ORF2序列的遗传演化分析

为了解猫杯状病毒形态特征及遗传演化情况,采用F81细胞从患病宠物猫的鼻拭子样品中分离获得1株猫杯状病毒(feline calicivirus,FCV),命名为SH1。经电镜观察,病毒粒子呈球形,无囊膜,符合FCV的形态特征。采用RT-PCR方法扩增了该毒株的全基因组,并进行了序列测定和衣壳蛋白基因(ORF2)序列的分析。结果显示:分离株与国内外参考株的ORF2序列的核苷酸和氨基酸同源性分别为74.1%~79.7%和84.5%~90.9%;ORF2基因的遗传演化分析显示,30株FCV毒株形成两大分支,即基因群Ⅰ和Ⅱ,分离株属于基因群Ⅰ;进一步分析发现,基因群Ⅰ和Ⅱ主要在377、539和557氨基酸位点存在差异,基因群Ⅰ和Ⅱ分别为N、A、G和K、V、S。研究结果为FCV感染的防控提供科学依据。     

Detection of Feline calicivirus (FCV) from Vaccinated Cats and Phylogenetic Analysis of its Capsid Genes

We analysed genogroups of four feline calcivirus (FCV) isolates (FCV-S, H10, Ao198-1 and ML89) obtained from cats that experienced FCV infection after having been vaccinated against FCV. New PCR primer sets (8F/8R, Ao-S/Ao-A, cp-S/cp-A) were also designed, since the conventional Seal primer failed to amplify the target sequences in two samples. The genogroups of the four isolates as well as eight global and 17 domestic strains were determined by phylogenetic analysis of their amino acid sequences. One out of the four strains (25%) isolated in this study, H10, was grouped into genogroup I, along with the vaccine strains F9 and FCV-255. The other three isolates (75%) belonged to genogroup II. Thus, there were more isolates in genogroup II than in genogroup I. However, the antibody values of the four isolates against cat anti-F9 antisera were significantly decreased. There may be no relationship between the neutralizing antibody titre and genogroup. Amino acid sequence alignment of the four isolates showed that only a single amino acid in region C, which is involved in neutralization epitopes, was different in ML89 strain from that of F9. The other three strains, H10, Ao198-1 and FCV-B, shared the same amino acid sequence with F9. Alignment of amino acids for linear epitopes in the F9 strain, which are located at regions D and E, showed variations in 5' hypervariable region (HVR) of E, whereas D and conE had only synonymous substitutions i.e. no change in the amino acid sequence. This mutation in 5' HVR of region E suggested a vaccine breakdown, as the region is known to be essential for antigenicity. The genogroup II FCV is likely to be the cause of the FCV infection in this study, while the vaccine strains belong to genogroup I. Thus, the existing vaccine may need reevaluation for its effectiveness.     

Mapping neutralizing and non-neutralizing epitopes on the capsid protein of feline calicivirus

Neutralizing epitopes on feline calicivirus (FCV) capsid protein were mapped using chimeric capsid proteins recombinant between two FCV isolates that do not show any cross-neutralization. The three chimeric proteins examined were expressed in murine L929 cells employing an MVA/T7 vaccinia virus expression system and inoculated into major histocompatibility complex haplotype-matched C3/HN mice. Based on the neutralizing antibody titre the neutralizing epitope(s) could be mapped to the 5' hypervariable region of the E region or potentially to the C region. The epitopes of some non-neutralizing antibodies were mapped with the same chimeric proteins to the regions B or D and F of the FCV capsid protein.     

Mapping Neutralizing and Non‐Neutralizing Epitopes on the Capsid Protein of Feline Calicivirus

Neutralizing epitopes on feline calicivirus (FCV) capsid protein were mapped using chimeric capsid proteins recombinant between two FCV isolates that do not show any cross‐neutralization. The three chimeric proteins examined were expressed in murine L929 cells employing an MVA/T7 vaccinia virus expression system and inoculated into major histocompatibility complex haplotype‐matched C3/HN mice. Based on the neutralizing antibody titre the neutralizing epitope(s) could be mapped to the 5′ hypervariable region of the E region or potentially to the C region. The epitopes of some non‐neutralizing antibodies were mapped with the same chimeric proteins to the regions B or D and F of the FCV capsid protein.     

Genetic and immunobiological diversities of porcine reproductive and respiratory syndrome genotype I strains

Genetic diversity of porcine reproductive and respiratory syndrome virus (PRRSV) has been based on ORF5/GP5 and ORF7/N protein variations. Complete viral genome studies are limited and focused on a single or a few set of strains. Moreover, there is a general tendency to extrapolate results obtained from a single isolate to the overall PRRSV population. In the present study, six genotype-I isolates of PRRSV were sequenced from ORF1a to ORF7. Phylogenetic comparisons and the variability degree of known linear B-epitopes were done considering other available full-length genotype-I sequences. Cytokine induction of all strains was also evaluated in different cellular systems. Non structural protein 2 (nsp2) was the most variable part of the virus with 2 out of 6 strains harboring a 74 aa deletion. Deletions were also found in ORF3 and ORF4. Phylogenetic analyses showed that isolates could be grouped differently depending on the ORF examined and the highest similarity with the full genome cluster was found for the nsp9. Interestingly, most of predicted linear B-epitopes in the literature, particularly in nsp2 and GP4 regions, were found deleted or varied in some of our isolates. Moreover, 4 strains, those with deletions in nsp2, induced TNF-α and 3 induced IL-10. These results underline the high genetic diversity of PRRSV mainly in nsp1, nsp2 and ORFs 3 and 4. This variability also affects most of the known linear B-epitopes of the virus. Accordingly, different PRRSV strains might have substantially different immunobiological properties. These data can contribute to the understanding of PRRSV complexity.     

Genetic analysis and phylogenetic comparison of Black queen cell virus genotypes

Phylogenetic analysis of 22 Black queen cell virus (BQCV) genotypes collected from honeybee colonies in Poland, Austria and Hungary was performed on a partial helicase enzyme coding region (ORF1) and on a partial structural polypeptide coding region (ORF2). While the phylogeny based on the ORF2 region showed – with the exception of one strain from Poland – clustering of the genotypes corresponding to their geographic origin, the ORF1-based tree exhibited a completely different distribution of the Polish strains: three of them clustered within a branch clearly separated from all other central European BQCVs, while four other Polish strains remained well within the central European BQCV genotypes. In order to investigate this discrepancy in more detail, the nearly complete genome sequences of the three differing Polish strains were determined, together with one Hungarian sample. The sequences were aligned to each other and to the reference strain from South-Africa. Comparison of the different genome regions revealed that the 5′-UTR and the intergenic regions of the BQCV genome are highly conserved with longer homologous sections. ORF1 (non-structural protein coding region) was found more variable compared to ORF2 (structural protein coding region). The 5′-proximal third of ORF1 was particularly variable and contained several deletions/insertions. The sudden changes in the similarity levels of BQCV strains in different genomic regions are indicative of preceding recombination events.     

Genetic variation of the nucleocapsid genes of waterfowl parvovirus.

Duck parvovirus (DPV) and Goose parvovirus (GPV) isolated from infected waterfowls with Derzsy's disease in the year 1999 were identified by polymerase chain reaction and sequencing. The nucleotide sequences of their viral capsid proteins (VPs) show that they share 77% similarity at the DNA, and 84.6% at the protein level. The most variable region between DPV and GPV resides in the N-terminal of VP2 before the initiation codon of VP3 with 35% (19/54) amino acids divergence. Viral capsid protein sequences diverge 4.1 to 4.4% among 1990-99 isolated strains. Variant amino acids cluster in the common regions of VP3 at residues 203-266 and 482-534 which overlaps with the regions proposed to expose on the outer surfaces of parvoviral particles, implying that selective pressure from host immune system might play a part. These data provide useful information for antigenic epitope prediction. This study also reveal the presence of conserved strain-specific residues in VPs and these residues seldom vary among different viral isolates, suggesting that they might be functionally important and worth further investigation.     

Genetic variation and phylogenetic analyses of the ORF5 gene of acute porcine reproductive and respiratory syndrome virus isolates

Swine herds in the US have experienced recent outbreaks of a severe form of porcine reproductive and respiratory syndrome (designated acute or atypical PRRS) characterized by abortion and high mortality in pregnant sows. Most of the affected herds had been vaccinated with modified live-vaccines (MLVs) against PRRS. To explore the possible mechanism of the emergence of acute PRRS, the open reading frame 5 (ORF5) gene encoding the major envelope protein (GP5) of acute PRRSV isolates was characterized. The complete ORF5 gene of eight acute PRRSV isolates from herds experiencing acute PRRS outbreaks in Iowa and North Carolina was amplified and sequenced. Sequence analyses revealed that these acute PRRSV isolates shared 88-95% nucleotide and 88-96% amino acid sequence identities to each other, 87-97% nucleotide and 84-96% amino acid sequence identities with other North American PRRSV isolates and the MLVs. Most of the amino acid substitutions locate in the putative signal sequence and two short hypervariable regions at the amino terminus. The ORF5 gene sequence of the acute PRRSV isolate 98-37120-2 from a non-vaccinated swine herd in Iowa is very closely related to that of the RespPRRS MLV, with 97% nucleotide and 96% amino acid sequence identities. Phylogenetic analysis revealed that all eight acute PRRSV isolates are clustered within the North American genotype. Several minor branches that are not associated with geographic origins were also identified within the North American genotype. One acute PRRSV isolate (98-37120-2) is clustered with the RespPRRS MLV and several Danish isolates that were confirmed to be derived from the RespPRRS MLV. The ORF5 gene sequences of other seven acute isolates are more related to those of several earlier PRRSV isolates and the PrimePac MLV than to that of the RespPRRS MLV. Our results showed that the acute PRRSV isolates analyzed in this study differed from each other in ORF5 genes, although they all clustered within the North American genotype. The data from this study do not fully support the hypothesis that the emergence of acute PRRS is due to reversion of MLVs to a pathogenic phenotype, as only one of the eight acute isolates was shown to be very closely related to the RespPRRS MLV.     

Complete genome sequence analysis of chicken astrovirus isolate from India

Objective

Chicken astroviruses have been known to cause severe disease in chickens leading to increased mortality and “white chicks” condition. Here we aim to characterize the causative agent of visceral gout suspected for astrovirus infection in broiler breeder chickens.

Methods

Total RNA isolated from allantoic fluid of SPF embryo passaged with infected chicken sample was sequenced by whole genome shotgun sequencing using ion-torrent PGM platform. The sequence was analysed for the presence of coding and non-coding features, its similarity with reported isolates and epitope analysis of capsid structural protein.

Results

The consensus length of 7513 bp genome sequence of Indian isolate of chicken astrovirus was obtained after assembly of 14,121 high quality reads. The genome was comprised of 13 bp 5′-UTR, three open reading frames (ORFs) including ORF1a encoding serine protease, ORF1b encoding RNA dependent RNA polymerase (RdRp) and ORF2 encoding capsid protein, and 298 bp of 3′-UTR which harboured two corona virus stem loop II like “s2m” motifs and a poly A stretch of 19 nucleotides. The genetic analysis of CAstV/INDIA/ANAND/2016 suggested highest sequence similarity of 86.94% with the chicken astrovirus isolate CAstV/GA2011 followed by 84.76% with CAstV/4175 and 74.48%% with CAstV/Poland/G059/2014 isolates. The capsid structural protein of CAstV/INDIA/ANAND/2016 showed 84.67% similarity with chicken astrovirus isolate CAstV/GA2011, 81.06% with CAstV/4175 and 41.18% with CAstV/Poland/G059/2014 isolates. However, the capsid protein sequence showed high degree of sequence identity at nucleotide level (98.64-99.32%) and at amino acids level (97.74–98.69%) with reported sequences of Indian isolates suggesting their common origin and limited sequence divergence. The epitope analysis by SVMTriP identified two unique epitopes in our isolate, seven shared epitopes among Indian isolates and two shared epitopes among all isolates except Poland isolate which carried all distinct epitopes.

     

广东省4株PCV2型分离株全基因组进化分析

【目的】了解目前广东省猪圆环病毒2型(Porcine circovirus type 2,PCV2)分离株的基因型和进化特征,为广东省PCV2防控及疫苗株的筛选提供参考依据。【方法】运用PCR方法将4份鉴定为PCV2阳性样品进行PCV2全基因组序列扩增、测序及遗传进化分析;利用MegAlign软件对4株PCV2广东分离株ORF2氨基酸序列与国内外参考毒株进行关键位点氨基酸变异分析;应用DNAStar中Protean软件的Jameson-Wolf方法对4株PCV2广东分离株ORF2基因编码的Cap蛋白与4株疫苗株进行抗原指数预测分析。【结果】测序结果表明,4株PCV2广东分离株序列长度均为1 767 bp。遗传进化树结果表明,4株分离株均属于PCV2d基因型,且核苷酸相似性在97.7%～99.1%之间,与国内外54株参考毒株相似性在91.7%～99.8%之间,其中与PhuTho/G40312/2018株(Viet Nam,登录号：LC602996)、QZ1410株(江苏,登录号：MG732832)、GXBB1501211株(广西,登录号：MH756609)亲缘关系最为接近。关键氨基酸位点...     

New insights into the genetic diversity of European porcine reproductive and respiratory syndrome virus (PRRSV)

The complete ORF5 sequences of 66 porcine reproductive and respiratory syndrome (PRRS) field virus strains (1991-2001) and three European modified live vaccine strains were determined, as well as ORFs 6 and 7 of 19 selected strains. The variability of the deduced ORF5 amino acid sequences was analysed using statistical process control (SPC), allowing for the objective assessment of variable and conserved regions. Four variable and four conserved regions as well as five hypervariable amino acid positions were defined. The effects of genetic variability on possible structural and functional properties were discussed with emphasis on immunogenic features. Phylogenetic analysis and pairwise comparison of the nucleotide sequences revealed that the genetic distances between the strains has greatly increased over time. The data do not support an evolutionary influence of the geographical location or the time of sample collection, nor of PRRSV vaccination on strain development. In contrast to other authors who tended to concentrate on the samples from either a common geographic origin or a short sampling period, we could not confirm geographically separate PRRSV clusters nor did we find evidence of positive selective pressure as measured by the ratio of synonymous to non-synonymous substitutions in ORF5, 6 or 7. Immunological implications and vaccination strategies are discussed.     

猪圆环病毒2型广西株的分离和全基因组序列分析

从广西表现为断奶仔猪多系统衰竭综合征的猪群中分离到1株猪圆环病毒2型(PCV-2),命名为GXB株.对GXB株的全基因组进行PCR扩增,扩增产物克隆至PMD18-T载体.测序结果表明,全基因组为1 767 bp,与GenBank上已知的8株PCV-2参考株序列的同源性在95.0%～99.6%之间.序列分析表明,GXB株基因组包含11个读码框(ORF),其中ORF1和ORF2是最主要的读码框,分别编码314个和233个氨基酸,与其他PCV-2毒株的ORF1、ORF2氨基酸的同源性分别为97.8%～100%、91.5%～98.7%.对GXB株ORF2编码的Cap蛋白基因进行功能分析,表明含有1个潜在的糖基化位点,3个明显的亲水区,有较强的抗原性和亲水性,为作为主要的免疫原性蛋白基因提供了依据.