Subtype B avian metapneumovirus resembles subtype A more closely than subtype C or human metapneumovirus with respect to the phosphoprotein,and second matrix and small hydrophobic proteins

Avian metapneumovirus (aMPV) subtype B (aMPV/B) nucleotide sequences were obtained for the phosphoprotein (P), second matrix protein (M2), and small hydrophobic protein (SH) genes. By comparison with sequences from other metapneumoviruses, aMPV/B was most similar to subtype A aMPV (aMPV/A) relative to the US subtype C isolates (aMPV/C) and human metapneumovirus (hMPV). Strictly conserved residues common to all members of the Pneumovirinae were identified in the predicted amino acid sequences of the P and M2 protein-predicted amino acid sequences. The Cys(3)-His(1) motif, thought to be important for binding zinc, was also present in the aMPV M2 predicted protein sequences. For both the P and M2-1 protein-predicted amino acid sequences, aMPV/B was most similar to aMPV/A (72 and 89% identity, respectively), having only approximately 52 and 70% identity, respectively, relative to aMPV/C and hMPV. Differences were more marked in the M2-2 proteins, subtype B having 64% identity with subtype A but < or = 25% identity with subtype C and hMPV. The A and B subtypes of aMPV had predicted amino acid sequence identities for the SH protein of 47%, and less than 20% with that of hMPV. An SH gene was not detected in the aMPV/C. Phylogenetically, aMPV/B clustered with aMPV/A, while aMPV/C grouped with hMPV.     

Genetic heterogeneity of G and F protein genes from Argentinean human metapneumovirus strains

Human metapneumovirus (hMPV) is a newly identified paramixovirus, associated with respiratory illnesses in all age groups. Two genetic groups of hMPV have been described. The nucleotide sequences of the G and F genes from 11 Argentinean hMPV strains (1998-2003) were determined by RT-PCR and direct sequencing. Phylogenetic analysis showed that hMPV strains clustered into two main genetic lineages, A and B. Strains clustered into A group were split into two sublineages, A1 and A2. All strains belonging to group B clustered with representative strains from sublineage B1. No Argentinean strains belonged to sublineage B2. F sequences showed high percentage identities at nucleotide and amino acid levels. In contrast, G sequences showed high diversity between A and B groups. Most changes observed in the deduced G protein sequence were amino acid substitutions in the extracellular domain, and changes in stop codon usage leading to different lengths in the G proteins. High content of serine and threonine residues were also shown, suggesting that this protein would be highly glycosylated. The potential sites for N- and O-glycosylation seem to have a different conservation pattern between the two main groups. This is the first report on the genetic variability of the G and F protein genes of hMPV strains in South America. Two main genetic groups and at least three subgroups were revealed among Argentinean hMPV strains. The F protein seems to be highly conserved, whereas the G protein showed extensive diversity between groups A and B.     

Analysis of the genomic sequence of a human metapneumovirus

We recently described the isolation of a novel paramyxovirus from children with respiratory tract disease in The Netherlands. Based on biological properties and limited sequence information the virus was provisionally classified as the first nonavian member of the Metapneumovirus genus and named human metapneumovirus (hMPV). This report describes the analysis of the sequences of all hMPV open reading frames (ORFs) and intergenic sequences as well as partial sequences of the genomic termini. The overall percentage of amino acid sequence identity between APV and hMPV N, P, M, F, M2-1, M2-2, and L ORFs was 56 to 88%. Some nucleotide sequence identity was also found between the noncoding regions of the APV and hMPV genomes. Although no discernible amino acid sequence identity was found between two of the ORFs of hMPV and ORFs of other paramyxoviruses, the amino acid content, hydrophilicity profiles, and location of these ORFs in the viral genome suggest that they represent SH and G proteins. The high percentage of sequence identity between APV and hMPV, their similar genomic organization (3'-N-P-M-F-M2-SH-G-L-5'), and phylogenetic analyses provide evidence for the proposed classification of hMPV as the first mammalian metapneumovirus.     

Comparison of the full-length genome sequence of avian metapneumovirus subtype C with other paramyxoviruses

We determined the nucleotide (nt) sequence of the small hydrophobic (SH), attachment glycoprotein (G), and RNA polymerase (L) genes, plus the leader and trailer regions of the Colorado strain of Avian metapneumovirus subtype C (aMPV/C) in order to complete the genome sequencing. The complete genome comprised of 13,134 nucleotides, with a 40 nt leader at its 3' end and a 45 nt trailer at its 5' end. The aMPV/C L gene was the largest with 6173 nt and consisting of a single open reading frame encoding a 2005 amino acids (aa) protein. Comparison of the aMPV/C SH, G, and L nt and predicted aa sequences with those of Human metapneumoviruses (hMPV) revealed higher nt and aa sequence identities than the sequence identities between the aMPV subtypes A, B, C, and D, supporting earlier finding that aMPV/C was closer evolutionary to hMPV than the other aMPV subtypes.     

Genetic variability of the G glycoprotein gene of human metapneumovirus

Human metapneumovirus (hMPV) has been associated with respiratory illnesses like those caused by human respiratory syncytial virus (HRSV) infection. Similar to other pneumoviruses, genetic diversity has been reported for hMPV. Little information is currently available on the genetic variability of the G glycoprotein (G), which is the most variable gene in RSV and avian pneumovirus. The complete nucleotide sequences of the G open reading frame (ORF) of 24 Canadian hMPV isolates were determined. Phylogenetic analysis showed the existence of two major groups or clusters (1 and 2). All but one of the hMPV isolates that we examined belonged to cluster 1. Additional genetic variability was observed in cluster 1, which separated into two genetic subclusters. Within cluster 1 the nucleotide sequence identity for the G ORF was 74.2 to 100%, and the identity for the predicted amino acid sequence was 61.4 to 100%. The G genes of cluster 1 isolates were more divergent from the cluster 2 isolates, with 45.6 to 50.5% and 34.2 to 37.2% identity levels for the nucleotide and amino acid sequences, respectively. Sequence analysis also revealed changes in stop codon usage, resulting in G proteins of different lengths (217, 219, 228, and 236 residues). Western blot analysis with the use of hMPV-specific polyclonal antisera to each hMPV cluster showed significant antigenic divergence between the G proteins of clusters 1 and 2. These results suggest that the G protein of hMPV is continuously evolving and that the genetic diversity observed for the hMPV genes is reflected in the antigenic variability, similar to HRSV.     

Nucleotide and predicted amino acid sequence-based analysis of the avian metapneumovirus type C cell attachment glycoprotein gene: phylogenetic analysis and molecular epidemiology of U.S. pneumoviruses

A serologically distinct avian metapneumovirus (aMPV) was isolated in the United States after an outbreak of turkey rhinotracheitis (TRT) in February 1997. The newly recognized U.S. virus was subsequently demonstrated to be genetically distinct from European subtypes and was designated aMPV serotype C (aMPV/C). We have determined the nucleotide sequence of the gene encoding the cell attachment glycoprotein (G) of aMPV/C (Colorado strain and three Minnesota isolates) and predicted amino acid sequence by sequencing cloned cDNAs synthesized from intracellular RNA of aMPV/C-infected cells. The nucleotide sequence comprised 1,321 nucleotides with only one predicted open reading frame encoding a protein of 435 amino acids, with a predicted M(r) of 48,840. The structural characteristics of the predicted G protein of aMPV/C were similar to those of the human respiratory syncytial virus (hRSV) attachment G protein, including two mucin-like regions (heparin-binding domains) flanking both sides of a CX3C chemokine motif present in a conserved hydrophobic pocket. Comparison of the deduced G-protein amino acid sequence of aMPV/C with those of aMPV serotypes A, B, and D, as well as hRSV revealed overall predicted amino acid sequence identities ranging from 4 to 16.5%, suggesting a distant relationship. However, G-protein sequence identities ranged from 72 to 97% when aMPV/C was compared to other members within the aMPV/C subtype or 21% for the recently identified human MPV (hMPV) G protein. Ratios of nonsynonymous to synonymous nucleotide changes were greater than one in the G gene when comparing the more recent Minnesota isolates to the original Colorado isolate. Epidemiologically, this indicates positive selection among U.S. isolates since the first outbreak of TRT in the United States.     

Sequence analysis of the N,P, M and F genes of Canadian human metapneumovirus strains

The complete nucleotide sequences of the nucleoprotein (N), phosphoprotein (P), matrix protein (M), and fusion protein (F) genes of 15 Canadian human metapneumovirus (hMPV) isolates were determined. Phylogenetic analysis revealed two distinct genetic clusters, or groups for each gene with additional sequence variability within the individual groups. Comparison of the deduced amino acid sequences for the N, M and F genes of the different isolates revealed that all three genes were well conserved with 94.1-97.6% identity between the two distinct clusters The P gene showed more diversity with 81.6-85.7% amino acid identity for isolates between the two clusters, and 94.6-100% for isolates within the same cluster.     

人偏肺病毒广州分离株全基因组序列测定及分析

目的 探讨广州地区儿童感染的偏肺病毒基因组分子结构特点和基因型类型.方法 参考GenBank上的偏肺病毒00-1株(AF371337)基因组设计分段扩增引物,进行RT-PCR分段扩增偏肺病毒基因组,克隆于T载体上,序列测定,用Clustal W/X、DNASTAR、MEGA4.1等软件分析基因组序列.结果 偏肺病毒hMPVgz01全基因组为13 327 bp,提交到GenBank上的序列号为GQ153651,有8个开放阅读框(open reading frames,ORFs),基因组结构为:3-N-P-M-F-M2-SH-G-L-5;将hMPVgz01株全基因组核苷酸序列与GenBank上的偏肺病毒全基因组序列进行Clustal W比较,发现与偏肺病毒的A组相似性较高,为92%～97%,与A2b组的BJ1887相似性为最高,而与B组相似性为81%,与C组的禽偏肺病毒为71%.将hMPVgz01株的N、F、G基因与偏肺病毒的A1、A2、B1、B2的相对应基因进行相似性比较,同样也是与A2b型的相似性为最高,因此确认广州地区的hMPVgz01株为A2b型.结论 广州地区儿童感染的偏肺病毒hMPVgz01株全基因组序列为13 327 bp,GenBank 序列号为GQ153651,hMPVgz01与偏肺病毒的A2b型相似性最高,确认hMPVgz01株属于偏肺病毒A2b型.     

Expression of recombinant small hydrophobic protein for serospecific detection of avian pneumovirus subgroup C

The small hydrophobic (SH) gene of the avian pneumovirus (APV) Colorado isolate (CO), which belongs to subgroup C (APV/C), was expressed with a baculovirus vector. The recombinant SH protein was evaluated as a potential subgroup-specific diagnostic reagent in order to differentiate infections resulting from APV/C from those induced by APV/A, APV/B, and human metapneumovirus (hMPV). When the recombinant baculovirus was used to infect insect cells, a 31- to 38-kDa glycosylated form of the SH protein was produced and subsequently tested for reactivity with antibodies specific for APV/A, APV/B, APV/C, and hMPV. Western blot analysis showed that the expressed recombinant SH protein could only be recognized by APV/C-specific antibodies. This result was consistent with sequence analysis of the APV/C SH protein, which had very low (24%) amino acid identity with the corresponding protein of hMPV and no discernible identity with the SH protein of APV/A or APV/B. A recombinant SH protein-based enzyme-linked immunosorbent assay (ELISA) was developed, and it further confirmed the lack of reactivity of this protein with antisera raised to APV/A, APV/B, and hMPV and supported its designation as a subgroup-specific antigen. This finding indicated that the recombinant SH protein was a suitable antigen for ELISA-based detection of subgroup-specific antibodies in turkeys and could be used for serologically based differential diagnosis of APV and hMPV infections.     

Expression of Recombinant Small Hydrophobic Protein for Serospecific Detection of Avian Pneumovirus Subgroup C

The small hydrophobic (SH) gene of the avian pneumovirus (APV) Colorado isolate (CO), which belongs to subgroup C (APV/C), was expressed with a baculovirus vector. The recombinant SH protein was evaluated as a potential subgroup-specific diagnostic reagent in order to differentiate infections resulting from APV/C from those induced by APV/A, APV/B, and human metapneumovirus (hMPV). When the recombinant baculovirus was used to infect insect cells, a 31- to 38-kDa glycosylated form of the SH protein was produced and subsequently tested for reactivity with antibodies specific for APV/A, APV/B, APV/C, and hMPV. Western blot analysis showed that the expressed recombinant SH protein could only be recognized by APV/C-specific antibodies. This result was consistent with sequence analysis of the APV/C SH protein, which had very low (24%) amino acid identity with the corresponding protein of hMPV and no discernible identity with the SH protein of APV/A or APV/B. A recombinant SH protein-based enzyme-linked immunosorbent assay (ELISA) was developed, and it further confirmed the lack of reactivity of this protein with antisera raised to APV/A, APV/B, and hMPV and supported its designation as a subgroup-specific antigen. This finding indicated that the recombinant SH protein was a suitable antigen for ELISA-based detection of subgroup-specific antibodies in turkeys and could be used for serologically based differential diagnosis of APV and hMPV infections.     

Capsid protein sequence diversity of chicken astrovirus

The complete capsid gene sequences of 24 chicken astroviruses (CAstVs), collected in the UK, Germany, the Netherlands and South Africa from the 1980s to 2008, were determined and compared with that of a US CAstV (UGA-2006). Pairwise comparisons and phylogenetic analysis demonstrated the existence of two major capsid groups, designated A and B, which shared 38 to 40% amino acid identity. CAstVs from groups A and B shared capsid protein identities ranging from 26 to 38% with other avian astroviruses. The group A CAstVs comprised three subgroups, which displayed inter-subgroup identities ranging from 77 to 82%, while group B comprised two clearly separated subgroups, Bi and Bii, which displayed intra-subgroup identities of 97 to 99% and 94 to 99%, respectively, and shared inter-subgroup identities of 84 to 85%. Phylogenetic analyses performed with contiguous open reading frame 1b (polymerase) and open reading frame 2 (capsid) CAstV sequences showed that CAstVs from capsid subgroup Bi had polymerase genes that differed from those possessed by CAstVs belonging to group A and subgroup Bii. The N-terminal capsid regions (residues 1 to 415) were more conserved than the C-terminal regions, with the C-terminal regions of the subgroup Bi and Bii CAstVs sharing 76 to 78% amino acid identity, while the C-terminal regions of the A subgroups displayed identities less than 75%. CAstVs representative of both capsid groups and more than one subgroup were detected within the same broiler flock. The high level of capsid sequence diversity observed in this study has important implications for both the control and diagnosis of CAstV infections.     

Nucleotide sequence of the envelope protein genes of a highly virulent, neurotropic strain of Newcastle disease virus

The envelope glycoproteins of Newcastle disease virus (NDV), hemagglutinin-neuraminidase (HN) and fusion (F) proteins, play important roles in determining the host immune response and the virulence of that particular virus strain. The complete nucleotide sequence of the HN and F genes of a highly neurovirulent strain of NDV (Texas G. B., 1948) was determined in an effort to study the molecular basis of this strain's neurotropic properties. Comparison of the predicted amino acid sequences for the HN and F among the American NDV strains revealed that the Texas G. B. and Beaudette C envelope genes are closely related to each other and are less closely related to the avirulent B1 Hitchner strain. We have found 11 amino acid changes in the predicted HN protein between the Beaudette C and Texas G. B. strain but only 2 conservative amino acid changes (amino acids 11 and 197) in the F protein between these two strains. Although the virulence of NDV strains has been related to sequences at the cleavage site of F0, the property of neurovirulence cannot depend solely upon these sequences because there are no sequence differences between the Beaudette C and Texas G. B. strains. We suggest that the neurovirulence phenotype could be due to the molecular properties of the HN protein; however, we cannot exclude the possibility that the two conservative amino acid differences between the two F proteins could also play a role in determining the phenotypic differences between these two virus strains.     

Limited Inter- and Intra-patient Sequence Diversity of the Genetic Lineage A human metapneumovirus fusion gene

Human metapneumovirus (hMPV) is associated with respiratory tract illness especially in young children. Two hMPV genetic lineages, A and B, and four sublineages A1, A2 and B1, B2 have been defined. Infection with hMPV occurs through membrane fusion mediated by the hMPV fusion (F) protein. In this study, the inter- and intra-patient genetic diversity of the lineage A hMPV F gene was investigated. Ten isolates were collected from 10 hMPV infected children. Viral RNA was isolated and amplified, and approximately 10 clones from each isolate were sequenced. Altogether 108 clones were successfully sequenced. The average interpatient sequence diversity was 1.68% and 1.64% at nucleotide and amino acid levels, respectively. The samples were divisible into two groups on the basis of intrapatient sequence diversity. In group 1 (4 children) the intra-patient sequence diversity was low (nt: 0.26–0.39%, aa: 0.51–0.94%) whereas group 2 (6 children) had a higher intra-patient sequence diversity (nt: 0.85–1.98%, aa: 1.08–2.22%). Phylogenetic analyses showed that the group 1 children harboured sublineage Al only, but interestingly group 2 children harboured both sublineages Al and A2, indicating they had been infected with at least two viruses. Several independent viruses contained premature stop codons in exactly identical positions resulting in truncated fusion proteins. Possibly this is a mechanism for immune system evasion. The F protein is a major antigenic determinant, and the limited sequence diversity observed lay emphasis on the hMPV F gene as a putative target for future vaccine development.     

北京地区人偏肺病毒融合蛋白F编码基因的序列分析

目的进一步了解北京地区人偏肺病毒（hMPV）编码基因的特征。方法在原先工作的基础上，从分属于hMPV的两个不同基因进化簇（即基因型）的两份临床标本BJ1816和BJ1887中扩增F蛋白全基因，克隆至pBS-T载体中并进行测序，与GenBank中hMPV的基因序列进行比较分析和种系进化分析。结果BJ1816和BJ1887的F基因全长均为1620个核苷酸，编码539个氨基酸。BJ1816和BJ1887F蛋白基因之间的核苷酸和推导的氨基酸同源性分别为83．8％和94．4％，与同一基因簇内的hMPV有相当高的氨基酸同源性（98．3％～99．6％）。BJ1816和BJ1887的F蛋白是典型的I型糖蛋白，具有与迄今已发现的hMPV相同的裂解位点（RQSR）。BJ1816和BJ1887之间F2亚单位的氨基酸同源性高于F1亚单位的同源性（96．9％vs93．8％）；除位于羧基末端的跨膜区和胞质尾区外，F1亚单位的其余部分较保守（95．4％）；糖基化位点保守。种系进化分析显示BJ1816和BJ1887属于不同的进化簇。结论F蛋白的序列分析进一步证明BJ1816和BJ1887分属于不同的基因型，其F蛋白的基因特征与其他国外文献中所报道的hMPV相似，是病毒的膜表面糖蛋白，提示其在病毒的感染与免疫中起到重要的作用。     

Fusion protein predicted amino acid sequence of the first US avian pneumovirus isolate and lack of heterogeneity among other US isolates

Avian pneumovirus (APV) was first isolated from turkeys in the west-central US following emergence of turkey rhinotracheitis (TRT) during 1996. Subsequently, several APV isolates were obtained from the north-central US. Matrix (M) and fusion (F) protein genes of these isolates were examined for sequence heterogeneity and compared with European APV subtypes A and B. Among US isolates the M gene shared greater than 98% nucleotide sequence identity with only one nonsynonymous change occurring in a single US isolate. Although the F gene among US APV isolates shared 98% nucleotide sequence identity, nine conserved substitutions were detected in the predicted amino acid sequence. The predicted amino acid sequence of the US APV isolate's F protein had 72% sequence identity to the F protein of APV subtype A and 71% sequence identity to the F protein of APV subtype B. This compares with 83% sequence identity between the APV subtype A and B predicted amino acid sequences of the F protein. The US isolates were phylogenetically distinguishable from their European counterparts based on F gene nucleotide or predicted amino acid sequences. Lack of sequence heterogeneity among US APV subtypes indicates these viruses have maintained a relatively stable population since the first outbreak of TRT. Phylogenetic analysis of the F protein among APV isolates supports classification of US isolates as a new APV subtype C.     

Variation in the fusion glycoprotein gene of human respiratory syncytial virus subgroup A

Six different genotypes (designated lineages SHL1–6) of human respiratory syncytial (RS) virus have been defined by partial nucleotide sequence analysis of the variable SH and the hypervariable G membrane protein genes, and by restriction fragment analysis of the conserved N protein gene of viruses isolated in south Birmingham. Viruses of very similar genotype appear to be present worldwide at the present time. We have determined the nucleotide sequences of the fusion protein genes of five viruses isolated in south Birmingham in the same year, but belonging to different lineages, and have compared them with the sequences of four subgroup A viruses isolated at earlier times from diverse localities. The sequence diversity of the F genes of these five viruses, as measured by nucleotide (94.5–98.5%) and inferred amino acid (97.0–99.3%) identities, is comparable with that of the nine subgroup A viruses considered as a whole. No sequence changes occur in any of the sites of known epitopes. Comparison of the nine subgroup A sequences with the published sequences of a subgroup B strain and three bovine RS viruses confirms that the F protein sequences are most divergent in the F₂ region.     

中国湖南地区人偏肺病毒的基因分型及其膜蛋白G基因特征的分析

目的 研究中国湖南地区人偏肺病毒(hMPV)的基因分型及其膜蛋白G序列的遗传学特征,比较分析其区域性流行特点.方法收集2005年中国湖南地区232份住院儿童鼻咽抽吸物(NPA)样本进行常见呼吸道病毒筛查,并扩增hMPV阳性样本的膜蛋白G全序列,与GenBank中已知hMPV参考株及其他地区公布的相关资料进行比对、进化等分子遗传学特征分析.结果从232份临床样本中共检测得到17份(7.3%)hMPV阳性样本,与其他病毒混合感染率达35%.扩增出其中13份hMPV样本的G蛋白全序列,分属于4种亚型(A1、A2、B1、B2).核酸长度类型有4种(711,675,660,696nt),N-连接糖基化位点数目和位置、半胱氨酸残基数目等特征与已报道的同期北京地区、日本、北美等地区hMPV调查分析结果不尽一致.结论中国湖南地区与其他地区同期hMPV调查分析结果各有特点,反映出hMPV变异显著,具有明显的地区流行特征.     

Coat protein of potyviruses. 2. Amino acid sequence of the coat protein of potato virus Y

The amino acid sequence of the coat protein of potato virus Y (PVY), the type member of the potyvirus group, has been determined by protein sequencing techniques. The protein contains 267 amino acid residues with a calculated mol wt of 29,945. A comparison of the PVY coat protein sequence with those of tobacco etch virus (TEV) and pepper mottle virus (PeMV) predicted from nucleotide sequence data (R. F. Allison, J. G. Sorenson, M. E. Kelly, F. B. Armstrong, and W. G. Dougherty, Proc. Natl. Acad. Sci. USA82, 3969-3972, 1985; W. G. Dougherty, R. F. Allison, T. D. Parks, R. E. Johnston, M. J. Feild, and F. B. Armstrong, Virology 146,282-291, 1985) shows that sequence homology between the coat proteins from PVY and PeMV is 92% and that between PVY and TEV is 62%. These data suggest that PVY and PeMV are much more closely related than previously believed from serological studies.