Complete genomic RNA sequence of the Polish <Emphasis Type="Italic">Pepino mosaic virus</Emphasis> isolate belonging to the US2 strain

We have determined the complete nucleotide and amino acid sequences of the Polish Pepino mosaic virus (PepMV) isolate marked as PepMV-PK. The PepMV-PK genome consists of a single positive-sense RNA strand of 6412-nucleotide-long that contains five open reading frames (ORFs). ORF1 encodes the putative viral polymerase (RdRp), ORFs 2–4 the triple gene block (TGB 1–3), and ORF5-coat protein CP. Two short untranslated regions flank the coding ones and there is a poly (A) tail at the 3′ end of the genomic RNA. Thus, the genome organization of PepMV-PK is that of a typical member of the genus Potexvirus. Phylogenetic analysis based on full-length genomes of PepMV sequences showed that PepMV-PK was most closely related to the Ch2 isolate from Chile. Comparison of PepMV-PK and Ch2 showed the following nucleotide identities: 98% for the RdRp, 99% for the CP genes, and 98, 99, and 98% for the TGB1, TGB2, and TBG3, respectively. This high level of nucleotide sequence identity between the Chilean and Polish PepMV-PK isolates suggest their common origin.     

Molecular Characterization of Foot-and-mouth Disease Virus in Hong Kong During 2001–2002

Most of the molecular epidemiological studies of foot-and-mouth disease virus (FMDV) are based on comparison of VP1 gene sequence. In this report, The nucleotide sequences of the VP1 coding region of FMDV type O strains O/HKN/3/01, O/HKN/5/01, O/HKN/12/01, O/HKN/7/02 and O/HKN/10/02, isolated from the disease outbreak that occurred in Hong Kong Special Administrative Region (Hong Kong SAR) of China during 2001–2002, were determined and compared with the sequences of other FMDVs. The results revealed that the VP1 gene of the five isolates had the same nucleotide (nt) sequences (639 nt), coding for 213 amino acids, and no changes were found either at the critical amino acid sites 144 (Val), 148 (Leu), 154 (Lys) and 208 (Pro) within the VP1 protein epitope (amino acids 140–160, 200–213), or in the amino acids 145–147 comprising the arginine–glycine–aspartic acid (RGD) sequence that is involved in the adsorption of virus to host cell. Analysis of the VP1 gene nucleotide sequence revealed that the five isolates examined were most closely related to FMDVs found in Hong Kong from 1991 to 1999 and Taiwan in 1997. Furthermore, although the critical amino acids on the antigen epitope of the prevalent Hong Kong isolates and the serotype O vaccine strain, O1/Manisa/Turkey/69, showed relative conservativeness, they were distantly related genetically, which showed that there existed variation between the prevalent Hong Kong FMDV strains and the vaccine strain.     

A组轮状病毒广州地方株VP7基因序列的比较分析

目的 了解我国轮状病毒G1型广州地方株与标准株及北京G1型地方株VP7基因序列的差异，为我国轮状病毒疫苗的研制提供资料。方法 通过逆转录—聚合酶链反应(RT—PCR)获得了轮状病毒广州地方株R97—196 VP7全基因的cDNA片段，将其克隆入T—A克隆质粒pUCm—T中，构建成重组质粒pUCmT—VP7，对克隆的VP7基因进行序列测定。结果 该地方株的基因核苷酸全长为1062nt，读码框架和以往的研究一致，和北京G1型地方株173的VP7氨基酸序列具有高度同源性(98％)，而与不同血清型标准株间则变异较大(73％—81％)，氨基酸序列中存在的一些高变区和保守功能区与已报道的研究结果一致。从进化角度分析，与轮状病毒标准株Wa株，相距较远。结论 轮状病毒广州地方株R97—196 VP7基因片段属G1型，轮状病毒VP7基因的变异与地域有一定关系。     

Sequence variability of the human cytomegalovirus UL141 Open Reading Frame in clinical strains

Summary. Human cytomegalovirus (HCMV) displays genetic polymorphisms. HCMV disease and tissue tropism may be related to specific genomic variability among strains. This work analyzed the genetic polymorphism of UL141 open reading frame (ORF), one of the genes in HCMV UL/b′ region, from 21 clinical strains. 8 previously published UL141 sequences in the GenBank were used for sequence comparison. Detailed sequence analysis showed that the UL141 gene was highly conserved at both the nucleotide and amino acid level. The coding regions were identical in size. The nucleotide and amino acid sequence identities among all strains were 96.9–100% and 97.6–100%, respectively.     

Sequence Comparison of Avian Infectious Bronchitis Virus S1 Glycoproteins of the Florida Serotype and Five Variant Isolates from Georgia and California

The infectious bronchitis virus (IBV) spike glycoprotein S1 subunit is required to initiate infection and contains virus-neutralizing and serotype-specific epitope(s). Reported are the S1 gene nucleotide and predicted amino acid sequences for the Florida 18288 strain and isolates GA-92, CV-56b, CV-9437, CV-1686, and 1013. These sequences were compared with previously published gene sequences of IBV strains, and phylogenetic relationships are reported. The S1 amino acid sequence of Florida 18288 was 94.9% similar to the Connecticut strain, and GA-92 was 92.8% similar to the Arkansas 99 strain. S1 amino acid sequences of the California variants, CV-56b, CV-9437, and CV-1686, were 97.6–99.3% similar to one another and only 76.6%–76.8% similar to the Arkansas-type strains. Isolate 1013, also from California, was 84.0% similar to Ark DPI and 77.9% similar to CV-56b. When comparing 19 viruses isolated from the United States, sequence variations were observed between amino acids 55–96, 115–149, 255–309, and 378–395. Similar regions are reported to be involved in virus-neutralizing and/or serotype-specific epitopes. These data demonstrate that variant IBV strains continue to emerge, and unique variants may circulate among poultry in geographically isolated areas. This revised version was published online in July 2006 with corrections to the Cover Date.     

Identification of genetic diversity of porcine Norovirus and Sapovirus in Korea

It is well known that Norovirus (NoV) and Sapovirus (SaV) identified in humans and pigs have heterogeneous genome sequences. In this study, a total of three strains of NoV and 37 strains of SaV were detected in 567 porcine fecal samples by RT-PCR, corresponding detection rates of 0.5 and 6.5%, respectively. Phylogenetic analyses were conducted using amino acid sequences of the partial RNA-dependent RNA polymerase (RdRp) and complete capsid proteins of both viruses to determine their genogroups. Analysis with the RdRp sequences indicated that all three NoV strains HW41, DG32, and DO35 detected in this study were classified into genogroup II (GII). A further analysis with the complete capsid sequence demonstrated that the DO35 strain belonged to subgenotype b in GII-21 (GII-21b) along with the SW918 strain. A total of 26 strains out of 27 strains that were selected from the 37 porcine SaVs were classified into genogroup III when they were analyzed with the RdRp sequences. The remaining strain (DO19) was not clustered with any of the previously classified SaV strains, thereby suggesting the advent of a new genogroup virus. Additional analyses with the amino acid sequence of the capsid and the nucleotide sequence of the RdRp and capsid junction region supported the notion that the DO19 strain belonged to a novel genogroup of SaV. To the best of our knowledge, this is the first report to describe a novel porcine SaV belonging to an unknown genogroup in Korea.     

Contributions of genetic drift and negative selection on the evolution of three strains of wheat streak mosaic tritimovirus

Summary.  Genome sequences of three Wheat streak mosaic virus (WSMV) strains were compared. The Type and Sidney 81 strains of WSMV from the American Great Plains were closely related, with sequence identities of 97.6% (nucleotide) and 98.7% (amino acid). In contrast, the El Batán 3 strain from central Mexico was divergent, and shared only 79.2–79.3% (nucleotide) and 90.3–90.5% (amino acid) sequence identity with Type and Sidney 81. All three WSMV strains were serologically related, however the El Batán 3 capsid protein (CP) had 15 fewer amino acid residues. Phylogenetic analysis of the CP cistron indicated that Type, Sidney 81, and nine other American isolates of WSMV were closely related and distinct from the El Batán 3 sequence. Nucleotide substitutions among the WSMV strains were not randomly distributed across the genome with more variation within P1, HC-Pro, and CP, and less within P3. One 400-nucleotide region of the genome, corresponding to the 3′-end of P3, was strikingly deficient in silent substitutions. Nonetheless, the ratio of synonymous to non-synonymous substitutions throughout the genome was essentially the same for all three WSMV strains. Collectively, our data indicate that both genetic drift and negative selection have contributed to the evolution of WSMV strains. Received April 10, 2000 Accepted August 2, 2000     

Classification of duck hepatitis virus into three genotypes based on molecular evolutionary analysis

The nucleotide sequences of the complete VP1, VP0, VP3, and partial 3D regions of seven duck hepatitis virus (DHV) serotype 1 (DHV-1) strains isolated in China between 2001 and 2007 and one DHV-1 strain originally obtained from ATCC were determined and compared with previously available DHV sequences in GenBank. Phylogenetic analysis on the basis of VP1 sequences demonstrated three distinct genetic groups. There was an excellent concordance among the genetic groups assigned based on the complete VP0, VP3, and the partial 3D regions. In view of the growing importance of molecular techniques in diagnosis, we propose that the three genetic groups should be termed DHV types A, B, and C. All DHV-1 strains grouped in genotype A, whereas the new serotype strains isolated in Taiwan and the new serotype strains isolated in South Korea clustered into genotypes B and C, respectively, suggesting a potential genetic correlates of serotype. In pairwise comparisons of complete VP1, VP0, and VP3 nucleotide and amino acid sequences and the partial 3D nucleotide sequence, DHVs of the same genotype were clearly distinguished from those of heterologous genotypes. Analysis of the amino acid sequences of the three capsid proteins demonstrated the presence of conserved elements that form the eight-stranded beta-barrel structures, as well as intervening domains that vary in sequence between strains of different genotypes as seen in other picorna viruses.     

Cloning and nucleotide analysis of the vp2 gene of a very virulent infectious bursal disease virus isolate from Iran

An Iranian field isolate (IR01) of Infectious bursal disease virus (IBDV) was characterized by sequence analysis of its VP2 gene and protein. Comparison of the obtained sequences with those of IBDV isolates from other countries revealed that IR01 was similar to very virulent IBDV (vvIBDV) strains with the identities at nucleotide and amino acid levels reaching 98.198.9% and 99.199.3%, respectively. On the other hand, it was less similar to non-vvIBDV strains; with nucleotide and amino acid identities of 95.295.7% and 96.097.3%, respectively. Out of nine unique nucleotide differences found between IR01 and some other serotype 1 strains only two resulted in amino acid substitutions (Ile296Val and Thr359Lys). In phylogenetic analysis, IR01 was closely related to Asian and European vvIBDV strains. Based on these results, IR01 obviously belongs to vvIBDV strains.     

Identification of new genetic subtypes of bovine viral diarrhea virus genotype 1 isolated in Japan

A part of the nucleotide sequence of the 5′ untranslated region (5′UTR) and E^rns region, and the genomic regions encoding for N^pro, Core, and E2 of So-like isolates and IS25CP/01 strain which belong to bovine viral diarrhea virus genotype 1 (BVDV-1) were determined and genetic comparisons were made with sequences of other BVDV subgenotypes. Phylogenetic analysis using the 5′UTR and N^pro revealed that So-like isolates and IS25CP/01 branched into independent phylogenetic branch. So-like isolates were clustered with Korean BVDV strains taken from DDBL/EMBL/GenBank in the 5′UTR. An additional two amino acid residues were found at the C terminal of the Core region of IS25CP/01. The similarity of amino acid sequence of E2 of So-like isolates and IS25CP/01 to the BVDV-1 reference strain NADL were 78.0–78.5 and 79.0, respectively. Cross-neutralization tests showed significant antigenic differences between So-like isolates and the others (Antigenic similarity (R) value: 2.2–8.8), and IS25CP/01 and the others (R value: 1.6–8.8). So-like viruses and IS25CP/01 differed from the thirteenth subgenotypes (1a-1m) reported by Jackova et al. (2007) and were classified as new genetic subtypes, BVDV-1n (So-like) and 1o (IS25CP/01). The nucleotide sequence data reported in this article have been submitted to the DDBJ/EMBL/GenBank nucleotide sequence database and assigned the accession numbers AB359923–AB359944.     

Full genomic analysis and possible origin of a porcine G12 rotavirus strain RU172

Human group A rotavirus (GAR) G12 strains are regarded as potentially important pathogens for acute gastroenteritis. On the other hand, to date, the only report of detection of G12 in animals was that of a porcine G12P[7] strain RU172. Strain RU172 formed a separate G12 lineage, distinct from human G12 strains, and by analyses of deduced amino acid sequences, had a VP4, VP6, NSP4-5 of porcine origin. In the present study, we determined the full-length nucleotide sequences of VP1, VP3, and NSP1-3 genes and nearly full-length nucleotide sequence of VP2 gene of RU172. By nucleotide sequence identities and phylogenetic analyses, the VP7-VP4-VP6-VP1-VP2-VP3-NSP1-NSP2-NSP3-NSP4-NSP5 genes of RU172 were assigned to G12-P[7]-I5-R1-C1-M1-A1-N1-T1-E1-H1 genotypes, respectively. Within their respective genotypes, (i) VP1 gene of RU172 exhibited higher genetic relatedness to Wa-like human G12 GARs than porcine strains, (ii) VP2-3 and NSP2 genes clustered separately from the Wa-like human (including G12) and porcine clusters, while (iii) the VP6, NSP1 and NSP3-5 genes clustered with porcine and porcine-like human strains. These observations suggested that (i) the porcine G12 strain might have originated from porcine–human reassortment events, or alternatively, (ii) the Wa-like human and porcine G12 strains might have originated from a common ancestor, and eventually evolved (by genetic drift and shift) with time. Our findings provided important insights into the possible patterns of evolution of the porcine G12 strain.     

Molecular characterization of infectious bursal disease virus isolates from Nepal based on hypervariable region of VP2 gene

Two Infectious bursal disease virus (IBDV) isolates, NP1SSH and NP2K were obtained from a severe infectious bursal disease (IBD) outbreak in Nepal in 2002. The hypervariable (HV) region of VP2 gene (1326 bp) of the isolates was generated by RT-PCR and sequenced. The obtained nucleotide sequences were compared with those of twenty other IBDV isolates/strains. Phylogenetic analysis based on this comparison revealed that NP1SSH and NP2K clustered with very virulent (vv) IBDV strains of serotype 1. In contrast, classical, Australian classical and attenuated strains of serotype 1 and avirulent IBDV strains of serotype 2 formed a different cluster. The deduced amino acid sequences of the two isolates showed a 98.3% identity with each other and 97.1% and 98.3% identities, respectively with very virulent IBDV (vvIBDV) isolates/strains. Three amino acids substitutions at positions 300 (E-->A), 308 (I-->F) and 334 (A-->P) within the HV region were common for both the isolates. The amino acids substitutions at positions 27 (S-->T), 28 (I-->T), 31 (D-->A), 36 (H-->Y), 135 (E-->G), 223 (G-->S), 225 (V-->I), 351 (L-->I), 352 (V-->E) and 399 (I-->S) for NP1SSH and at position 438 (I-->S) for NP2K were unique and differed from other IBDV isolates/strains. NP1SSH and NP2K showed highest similarity (97.8%) with the BD399 strain from Bangladesh as compared with other vvIBDV isolates/strains. We conclude that the NP1SSH and NP2K isolates of IBDV from Nepal represent vvIBDV of serotype 1.     

Sequence analysis of porcine kobuvirus VP1 region detected in pigs in Japan and Thailand

Porcine kobuvirus is a new candidate species of the genus Kobuvirus in the family Picornaviridae, and information is still limited. The identification of porcine kobuvirus has been performed by the sequence analyses of the 3D region of the viruses. Therefore, the purpose of this study was to characterize the molecular properties of VP1 nucleotide sequences of the porcine kobuviruses isolated from porcine stool samples in Japan during 2009 and Thailand between 2006 and 2008. In addition, previous identification of a unique porcine kobuvirus; Japanese H023/2009/JP, which is a bovine kobuvirus-like strain based on sequence analysis of the 3D region, was also included in this study. All of the strains were amplified by the VP1-specific primer pair: the amplicons were subjected to direct sequencing and compared with the VP1 nucleotide sequences of reference strains. The VP1 sequences of strains from the GenBank database revealed high nucleotide sequence identity at 84.3–100%. On the other hand, the nucleotide identities among the 15 porcine kobuvirus strains analyzed in this study ranged from 78.8 to 99.8%. The results revealed that diversity of the strains in this study were higher than those of the strains in previous studies. Furthermore, it was found that the VP1 region of the bovine kobuvirus-like strain, H023/2009/JP, clustered with nine porcine kobuvirus strains that were isolated in Thailand and Japan. Since this strain was previously found to be closely related to bovine kobuviruses in the 3D gene region, it may be a natural recombinant.     

Molecular characterization of Sunflower chlorotic mottle virus: a member of a distinct species in the genus Potyvirus

The complete nucleotide (nt) and deduced amino acid (aa) sequences of the C (common) and CRS (chlorotic ringspot) Argentine strains of SuCMoV have been determined. The SuCMoV-C RNA genome consists of 9,965 nt, whereas indels within the P1 coding region of SuCMoV-CRS make its genomic length 15 nt shorter. Nucleotide and aa sequence identities between the polyproteins of the C and CRS strains of SuCMoV were 92.3 and 95.6%, respectively. Pairwise comparisons between the polyproteins of the C and CRS strains of SuCMoV and the viruses of the Potato virus Y (PVY) subgroup revealed identities of 66.5–66.9% at the nt level and 69.7–69.8% at the aa level. These results and phylogenetic analyses show that although SuCMoV strains cluster together with the potyviruses belonging to the PVY subgroup, SuCMoV should be considered a member of a distinct species in the genus Potyvirus.     

Sequence Comparison of the Large Genomic RNA Segments of Two Strains of Lymphocytic Choriomeningitis Virus Differing in Pathogenic Potential for Guinea Pigs

Two strains of lymphocytic choriomeningitis virus (LCMV) differ in their ability to cause a lethal disease in outbred guinea pigs: the Armstrong (ARM) strain is not lethal at high doses (10⁶ PFU), whereas the WE strain is lethal at less than 10 PFU inoculated intraperitoneally. The high pathogenic potential of LCMV WE has been mapped to the larger (L) of the two genomic RNA segments by genetic reassortment analysis (Riviere, Y., Ahmed, R., Southern, P.J., Buchmeier, M. J. and Oldstone, M. B. A., J. Virol. 55, 704–709, 1985). Here we describe the completed sequence of the LCMV WE L RNA, and its comparison to the L RNA of the non-virulent strain, LCMV ARM. Similar to the L RNA of LCMV ARM, the L RNA of WE is 7.2 kb long and contains two open reading frames (ORFs): the 5′ ORF encodes a small RING finger (zinc-binding) protein, p11 Z, and the 3′ ORF encodes the putative RNA-dependent RNA polymerase (RdRp or L protein). Comparison of nucleotide sequences for both viruses revealed 84% L RNA homology. At the amino acid level similarity between the two strains is 87% in the Z ORF, and 88% in the RdRp ORF. The most divergent regions are found in the N-terminal parts of the RdRp and Z proteins and are most likely to account for differences in pathogenic potential. This revised version was published online in July 2006 with corrections to the Cover Date.     

Evidence for inter- and intra-genotypic variations in dengue serotype 4 viruses representing predominant and non-predominant genotypes co-circulating in Thailand from 1977 to 2001

In order to characterize viral genetic variation among predominant and non-predominant genotypes of Thai dengue serotype 4 viruses (DENV-4) and follow mutations that occur during virus evolution, we performed a comparative analysis of the complete genomic sequences of six DENV-4 isolates representing three genotypes (I, IIA, and III) co-circulating in Thailand over a 24-year period. The results revealed [1] remarkable genetic variation in the viral genome between predominant and non-predominant genotypes; [2] inter-genotype-specific amino acid and nucleotide mutations in most regions of the viral genome; [3] more amino acid and nucleotide substitutions in later as compared to earlier isolates for predominant genotype I strains; [4] a single nucleotide substitution at nucleotide position 77 of the 5-′NTR of two non-predominant genotype III strains that disrupted a small conserved 3′stem–loop (SL) in the cyclization sequence required for virus replication; [5] a high degree of conservation of PrM/M and NS2B proteins, and the 5′-NTR in predominant genotype I strains with no mutations observed over the 24-year period of observation; and [6] no molecular markers that appeared to correlate with disease severity. Several mutations identified in this study might have a significant impact on the persistence of virus in the population, including one in the 5′-NTR that disrupted a small, highly conserved 3′SL2 structure at the terminus of the cyclized 5′–3′ RNA sequences in two genotype III strains, and three amino acid (aa) charge change mutations in the E and NS5 proteins of genotype I strains. The conserved 3′-SL structure may be a target for antiviral drug development.     

Complete genomic sequence analyses of Apple stem pitting virus isolates from China

The complete genomic sequences of a Chinese ASPV isolates KL1 and KL9 were determined from ten overlapping cDNA clones. The genomes of both isolates were 9265 nucleotides excluding the poly (A) tail and contained five open reading frames (ORFs). The identities between two complete genomes were 92.5% at nt level. Multiple alignment of the amino acid sequences showed that 110 aa variations between two genomic sequences and the variable domains mainly distributed in 5′-terminal of ORF1, ORF3, and ORF5, respectively. Two complete genomic sequences shared 71.4–77.3% identities with other ASPV isolates at nt level. Phylogenetic relationship analysis of the coat protein genes revealed that ASPV isolates had high variables and formed three groups. All ASPV isolates from apples were clustered to group I, whereas pear were clustered to groups II (except NC_003462) and both KL1 and KL9 were clustered to group III. Nucleotide sequences diversity analysis showed that the between-population d _NS /d _S ratio 0.092 was similar to these for within-group (0.092–0.095); there was no geographic differentiation between ASPV isolates.     

Nucleotide sequence analysis of the serotype-specific epitope of infectious pancreatic necrosis virus

Summary The cDNA nucleotide sequences of the infectious pancreatic necrosis virus (IPNV) serotype-specific epitope of the major structural protein VP 2 were determined for a Scottish strain (Sp serotype), and an IPNV field isolate from Shetland. Comparison of the sequence data indicated that the field isolate was of the Sp serotype. The Scottish Sp strain and the field isolate showed less than 3% difference in nucleotide sequence over this region compared to the Norwegian N 1 strain, and all three European viruses differed by approximately 23% from the Canadian Jasper strain.     

Phylogenetic analysis of partial S1 and N gene sequences of infectious bronchitis virus isolates from Italy revealed genetic diversity and recombination

A total of ten infectious bronchitis virus (IBV) isolates collected from commercial chickens in Italy in 1999 were characterized by RT-PCR and sequencing of the S1 and N genes. Phylogenetic analysis based on partial S1 gene sequences showed that five field viruses clustered together with 793/B-type strains, having 91.3–98.5% nucleotide identity within the group, and one isolate had very close sequence relationship (94.6% identity) with 624/I strain. These two IBV types have been identified in Italy previously. The other three variant isolates formed novel genotype detected recently in many countries of Western Europe. For one of these variant viruses, Italy-02, which afterwards became the prototype strain, the entire S1 gene was sequenced to confirm its originality. In contrast, phylogenetic analysis of more conserved partial N gene sequences, comprising 1–300 nucleotides, revealed different clustering. Thus, three variant IBVs of novel Italy-02 genotype, which had 96.7–99.2% S1 gene nucleotide identity with each other, belonged to three separate subgroups based on N gene sequences. 624/I-type isolate Italy-06 together with Italy-03, which was undetectable using S1 gene primers, shared 97.7% and 99.3% identity, respectively, in N gene region with vaccine strain H120. Only one of the 793/B-type isolates, Italy-10, clustered with the 793/B strain sharing 99.3% partial N gene identity, whereas the other four isolates were genetically distant from them (only 87.7–89.7% identity) and formed separate homogenous subgroup. The results demonstrated that both mutations and recombination events could contribute to the genetic diversity of the Italian isolates. The nucleotide sequences reported in this paper have been submitted to the EMBL/GenBank database and have been assigned the accession numbers AJ458958, AJ457137, AJ458959, AJ491327, AJ458960–AJ458964 for the S1 gene and AM260961–AM260970 for the N gene.