The sequence and model structure analysis of three Polish peanut stunt virus strains

Peanut stunt virus (PSV) belongs to the Cucumovirus genus of the family Bromoviridae and is widely distributed worldwide, also in Poland. PSV is a common pathogen of a wide range of economically important plants. Its coat protein (CP), similarly as in other viruses, plays an important role in many processes during viral life cycle and has great impact on the infectivity. In this study, we present the results of sequence–structure analysis of CP derived from three Polish strains of PSV: PSV Ag, G, and P. Sequences were determined using RT-PCR amplification followed by sequencing and compared with each other and also with CP from other known PSV viruses. We analyzed their phylogenetic relationship, based on CP sequence, using bioinformatic tools as well as their spatial model using homology-modeling approach with combination of ROSETTA algorithm for de novo modeling. We compared our model with those recently obtained for other cucumoviruses including PSV-Er. Our results have shown that all Polish strains probably belong to the first subgroup of PSV viruses. Homology level between strains Ag and G proved very high. Using theoretical modeling approach we obtained a model very similar to the one resolved previously with the differences caused by slightly different amino acid sequence. We have also undertaken an attempt to analyze its distant regions; however, results are not unequivocal. Analysis of symptoms and their correlation with specific amino acid position was also performed on the basis of results published elsewhere. The definite interpretation is impeded by the presence of satellite RNAs in Ag and P strains modulating symptoms’ severity, though. The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers: EF693944 for PSV-Ag, EF535261 for PSV-G, and EF535260 for PSV-P strain.     

Molecular characterization of an atypical Old World strain of Peanut stunt virus

Summary.  Northern blot analyses of RNAs from an Iranian strain of Peanut stunt virus (PSV-I Cucumovirus) using cloned cDNA probes to the genomic RNAs from two PSV strains, PSV-ER (subgroup I) and PSV-W (subgroup II), indicated that PSV-I RNA-3 is derived from a subgroup II strain. No hybridization signals, however, were detected with PSV-I RNAs 1 and 2 suggesting they are distinct from both subgroups I and II. Nucleotide (nt) sequence analysis of cloned cDNA fragments (1–1.5 kbp in size) representing PSV-I RNAs 1 and 2 showed that PSV-I is more closely related to subgroup II strains than to any other sequenced cucumovirus. The percent nt identity between RNA-1 sequences from PSV-I and PSV-ER or between PSV-I and PSV-W were 79.1% and 88.8%, respectively. The corresponding values for RNA-2 were 77.5% and 86.7%. Sequence comparison analyses of deduced amino acid sequence of cloned partial sequences of PSV-I RNAs 1 and 2 indicated that PSV-I 1a and 2a proteins are most closely related to those of subgroup II strains (93% identity). PSV-I supported the replication and encapsidation of PSV G-satellite RNA (G-satRNA), but not cucumber mosaic virus WL1-satRNA. PSV-I may be perceived as an Old World derivative of subgroup II strains, or it may represent a natural reassortment between a subgroup II (RNA-3) and an as yet uncharacterized subgroup of PSV strains (RNAs 1 and 2). Received November 11, 1998 Accepted March 15, 1999     

Nucleotide sequence analyses of genomic RNAs of Peanut stunt virus Mi,the type strain representative of a novel PSV subgroup from China

Summary. The complete nucleotide sequence of Peanut stunt virus strain Mi (PSV-Mi) from China was determined and compared to other viruses of the genus Cucumovirus. The tripartite genome of PSV-Mi encoded five open reading frames (ORFs) typical of cucumoviruses. Distance analyses of four ORFs indicated that PSV-Mi differed sufficiently in nucleotide sequence from other PSV strains of subgroups I and II to warrant establishment of a third subgroup of PSV.     

RNAs 4A and 5 are present in tomato aspermy virusand both subgroups of cucumber mosaic virus

Summary.  Primer extension analysis was used to determine the presence of RNAs 4A and 5 in tomato aspermy virus (TAV) and both subgroups of cucumber mosaic virus (CMV). RNAs 4A and 5 were detected in TAV and all CMV strains (representative of both subgroups) that were analysed, except for one subgroup I CMV strain which lacked detectable RNA 5. In subgroup II CMV strains the RNA 5 population was found to consist of two sequence variants. Comparison of the RNA 5 sequences from TAV and CMV indicated that TAV and subgroup II CMV RNA 5 share a much greater degree of sequence similarity than either has with subgroup I RNA 5. RNA 4A and the encoded 2b protein appear to be unique to the cucumovirus genus of the tripartite viruses, which share an otherwise common genome structure, and may have played a role in the evolutionary origin of this genus. Accepted November 15, 1996 Received May 27, 1996     

Molecular characterization of a strain of cucumber mosaic virus based on coat protein and movement protein genes

Cucumber mosaic virus (CMV) A strain (CMV-A) isolated from Amaranthus tricolor was partially characterized at molecular level. Complete coat protein (CP) and movement protein (MP) ORFs were cloned and sequenced. The 657 bp region of CP gene and the 840 bp region of MP gene encode 218 and 276 amino acids, respectively. CP, at nucleotide level, showed 90-98% sequence identity with the CMV subgroup I and less than 80% with the CMV subgroup II, it showed at amino acid level 92-96% identity with the subgroup I and 74-87% with the subgroup II. The nucleotide and amino acid sequence identities of MP ranged in 91-94% and 92-96%, respectively with the subgroup I but in 81-83% with the subgroup II. Phylogenetic trees generated from nucleotide and amino acid sequences of both CP and MP genes identified the virus strain as a member of the subgroup IB. CMV-A CP also displayed a remarkably higher homology with Indian strains of CMV than with other CMV strains and formed a separate cluster within the subgroup IB.     

Analysis of the biological and molecular variability of Watermelon mosaic virus isolates from Iran

Watermelon mosaic virus (WMV) is one of the most important viruses that causes different symptoms in Cucurbitaceae. WMV is a potyvirus with a worldwide distribution, but occurs most commonly in temperate and Mediterranean regions. Cucurbit species grown in Yazd, Esfahan, West Azerbaijan, Hormozgan, and Kerman provinces were surveyed for the relative incidence of WMV in 2004–2005. A total of 757 symptomatic cucurbit and 31 weed species were collected and assayed for infection with WMV. Of 788 leaf samples from cucurbit and weed plants, 190 samples were positive by double antibody sandwich ELISA (DAS-ELISA) using specific polyclonal antibody. Among the weed species tested only colocynth (Citrullus colocynthis) was found to be infected with WMV. The coat protein (CP) gene from 18 representative isolates was PCR amplified, cloned, sequenced, and compared with the sequences available in GeneBank. Phylogenetic analysis using 778 nucleotide long sequences of the coat protein gene showed that these isolates fell into two; groups I and II. Only one isolates (KER.JI.1) was classified in the group II. This isolate had a wider host range and infected Nicotiana debneyii and Datura metel. None of the other 17 isolates could infect these two species. Members of group I were divided into three subgroups; A, B, and C. The subgroup I_B appears to be a new subgroup comprising only of the Iranian isolates. Phylogenetic analysis based on 200 nucleotides coding for the N-terminal segment of the CP showed that all Iranian isolates except KER.JI.1 clustered with the previously reported WMV strains. All Iranian isolates had a DAG amino acid triplet which is involved in aphid transmissibility. This is the first report on sequence analysis of the nearly full-length CP cDNA clones of WMV isolates from Iran.     

High diversity of ankA sequences of Anaplasma phagocytophilum among Ixodes ricinus ticks in Germany

In Germany humans with acute granulocytic ehrlichiosis have not yet been described. Here, we characterized three different genes of Anaplasma phagocytophilum strains infecting German Ixodes ricinus ticks in order to test whether they differ from strains in other European countries and the United States. A total of 1,022 I. ricinus ticks were investigated for infection with A. phagocytophilum by nested PCR and sequence analysis. Forty-two (4.1%) ticks were infected. For all positive ticks, parts of the 16S rRNA and groESL genes were sequenced. The complete coding sequence of the ankA gene could be determined in 24 samples. The 16S rRNA and groESL gene sequences were as much as 100% identical to known sequences. Fifteen ankA sequences were >/=99.37% identical to sequences derived from humans with granulocytic ehrlichiosis in Europe and from a horse with granulocytic ehrlichiosis in Germany. Thus, German I. ricinus ticks most likely harbor A. phagocytophilum strains that can cause disease in humans. Nine additional sequences were clearly different from known ankA sequences. Because these newly described sequences have never been obtained from diseased humans or animals, their biological significance is currently unknown. Based on this unexpected sequence heterogeneity, we propose to use the ankA gene for further phylogenetic analyses of A. phagocytophilum and to investigate the biology and pathogenicity of strains that differ in the ankA gene.     

Molecular Evidence for the Existence of Two Distinct Subgroups in Cucumber Mosaic Cucumovirus

Infectious full-length cDNA clones from the genomic RNAs of a subgroup II cucumber mosaic cucumovirus strain (Trk7) were obtained. Sequence analysis of the whole genome revealed strong homology (99%) to the genome of Q-CMV, the only subgroup II strain whose entire genomic nucleotide sequence had been available in the database, and an overall 75% homology to those of subgroup I strains. We provide sequence comparisons of different parts of 1a, 2a and 2b proteins of Cucumovirus species, and propose phylogenetic trees based on these protein sequences.     

Leader (L) and L* proteins of Theiler's murine encephalomyelitis virus (TMEV) and their regulation of the virus' biological activities

Theiler's murine encephalomyelitis virus (TMEV) is divided into two subgroups on the basis of their different biological activities. GDVII subgroup strains produce fatal poliomyelitis in mice without virus persistence or demyelination. In contrast, TO subgroup strains induce demyelinating disease with virus persistence in the spinal cords of weanling mice. Two proteins, whose open reading frames are located in the N-terminus of the polyprotein, recently have been reported to be important for TMEV biological activities. One is leader (L) protein and is processed from the most N-terminus of the polyprotein; its function is still unknown. Although the homology of capsid proteins between DA (a representative strain of TO subgroup) and GDVII strains is over 94% at the amino acid level, that of L shows only 85%. Therefore, L is thought to be a key protein for the subgroup-specific biological activities of TMEV. Various studies have demonstrated that L plays important roles in the escape of virus from host immune defenses in the early stage of infection. The second protein is a 17–18 kDa protein, L*, which is synthesized out-of-frame with the polyprotein. Only TO subgroup strains produce L* since GDVII subgroup strains have an ACG rather than AUG at the initiation site and therefore do not synthesize L*. 'Loss and gain of function' experiments demonstrate that L* is essential for virus growth in macrophages, a target cell for TMEV persistence. L* also has been demonstrated to be necessary for TMEV persistence and demyelination. Further analysis of L and L* will help elucidate the pathomechanism(s) of TMEV-induced demyelinating disease.     

Nucleotide sequence of dengue 2 RNA and comparison of the encoded proteins with those of other flaviviruses

We have determined the complete sequence of the RNA of dengue 2 virus (S1 candidate vaccine strain derived from the PR-159 isolate) with the exception of about 15 nucleotides at the 5' end. The genome organization is the same as that deduced earlier for other flaviviruses and the amino acid sequences of the encoded dengue 2 proteins show striking homology to those of other flaviviruses. The overall amino acid sequence similarity between dengue 2 and yellow fever virus is 44.7%, whereas that between dengue 2 and West Nile virus is 50.7%. These viruses represent three different serological subgroups of mosquito-borne flaviviruses. Comparison of the amino acid sequences shows that amino acid sequence homology is not uniformly distributed among the proteins; highest homology is found in some domains of nonstructural protein NS5 and lowest homology in the hydrophobic polypeptides ns2a and 2b. In general the structural proteins are less well conserved than the nonstructural proteins. Hydrophobicity profiles, however, are remarkably similar throughout the translated region. Comparison of the dengue 2 PR-159 sequence to partial sequence data from dengue 4 and another strain of dengue 2 virus reveals amino acid sequence homologies of about 64 and 96%, respectively, in the structural protein region. Thus as a general rule for flaviviruses examined to date, members of different serological subgroups demonstrate 50% or less amino acid sequence homology, members of the same subgroup average 65-75% homology, and strains of the same virus demonstrate greater than 95% amino acid sequence similarity.     

Nucleotide sequence analysis of peanut stunt virus Rp strain suggests the role of homologous recombination in cucumovirus evolution

The complete nucleotide (nt) sequence of peanut stunt virus Robinia strain (PSV-Rp) was determined and compared to other PSV strains and to representatives of the genus Cucumovirus. Nt sequence comparison showed 74.1-84.6% identity with the known PSV strains. Phylogenetic analysis revealed the different origin of the two genes encoded by RNA3. While the 3a gene clustered with PSV-W, the coat protein gene clustered with PSV-Mi. Recombination breakpoint analysis revealed two recombination points on RNA3. Based on these results, the establishment of a fourth PSV subgroup is proposed. This work revealed that homologous recombination occurred during the evolution of PSV.     

N-Terminal Amino Acid Sequence of Amyloid Fibril Protein AR, Prototype of a New λ-Variable Subgroup, VλV

An amyloid fibril protein AR has been further characterized as to amino acid sequence of the first 45 N-terminal residues. There are clear homologies with light chain-variable regions, particularly with λ light chains and mostly with the VλII subgroup. However, there is as much as a 55% difference from the Vλ.II subgroup and even greater differences from other subgroups. This is much more than the variation known to occur within a given light chain-variable subgroup and also a greater difference than those known to occur between the existing subgroups. For this reason protein AR appears to be the prototype for a new variable subgroup of λ chains. In agreement with the National Biomedical Research Foundation, this new subgroup is termed VλV.     

Caprine arthritis-encephalitis virus-infected goats can generate human immunodeficiency virus-gp120 cross-reactive antibodies(1)

Lentiviruses display surprisingly disparate clinical manifestations in their specific hosts, share complex genetic structures, and exhibit extensive diversity, particularly in their envelope genes. The envelope protein, gp135, of caprine arthritis-encephalitis virus (CAEV) has minimal primary sequence homology to gp120, the envelope protein of human immunodeficiency virus (HIV). Nevertheless, they bear certain similarities in that they both possess five variable regions, both are heavily glycosylated, and both share short sequence motifs. We establish a further relationship and demonstrate that some goats, infected with CAEV, possess gp135-specific antibodies which cross-react with gp120 from several HIV strains, provided the protein is expressed in insect cells. We show that, although the cross-reactivity of these immunoglobulins depends on the level of glycosylation, nevertheless, some antibodies recognize the protein epitopes on gp120, at least some of which are linear in character. Further characterization of this unexpected cross-reaction will define its potential therapeutic utility.     

Genetic diversity of avian paramyxovirus type 4 isolates from wild ducks in Korea from 2006 to 2011

Thirteen isolates of avian paramyxovirus type 4 (APMV-4) isolated from wild ducks in Korea from 2006 to 2011 were genetically characterized by sequence analysis of the N-terminal region of the APMV-4 fusion (F) protein gene. The results revealed that the amino acid sequence homology within Korean isolates was 97.5 % or greater. The homologies of the Korean isolates with the APMV-4/duck/HK/D3/75 and APMV-4/duck/BE/15129/07 strains were 86.9–88.0 and 95.5–96.1 %, respectively. All Korean isolates had sequence motifs of ¹¹⁶DIQPR↓F¹²¹ at the F0 cleavage site. Phylogenetic analysis based on the N-terminal region of the F protein gene of APMV-4 isolates revealed that all 2006–2011 Korean isolates formed a single genotypic cluster that was phylogenetically different from APMV-4/duck/HK/D3/75 or APMV-4/duck/BE/15129/07 strains. Korean APMV-4 isolates were more closely related to APMV-4/goose/ZA/N1468/10 (isolated in South Africa) than to the Belgium APMV-4 virus. Korean APMV-4 isolates were further divided into at least two subgroups (A and B) based on phylogenetic analysis. Subgroup A viruses were isolated throughout Korea, whereas subgroup B viruses were detected only in isolates from Cheju island in 2011, suggesting that Korean APMV-4 exhibits marked genetic diversity and differs from viruses currently circulating in Europe and other locations.     

Rotavirus subgroup characterisation by restriction endonuclease digestion of a cDNA fragment of the VP6 gene

Human rotavirus strains characterised with subgroup-specific monoclonal antibodies were amplified using a VP6-specific RT-PCR and amplicons of 379 bp size (nt 747-1126) were analysed by restriction fragment length polymorphism (RFLP) using the restriction endonuclease AciI. The restriction patterns were compared to the subgroups determined serologically and to VP6 genogroups determined through sequence analysis. RFLP discriminated successfully between VP6 genogroups I and II. None of the strains characterised serologically as either subgroup nonI,nonII or subgroup I+II were distinguishable from subgroup II on the basis of their restriction pattern or sequence analysis. The results obtained by RFLP correlated well with the VP6 genogrouping results, providing a more reliable method for subgrouping of rotaviruses than ELISAs using subgroup-specific antibodies.     

Genetic diversity of Hungarian <Emphasis Type="Italic">Maize dwarf mosaic virus</Emphasis> isolates

The genetic diversity of the coat-protein (CP) region and the untranslated C-terminal region (3′UTR) of Maize dwarf mosaic virus (MDMV) was analyzed to evaluate the variability between isolates (inter-isolate sequence diversity). The results of inter-isolate sequence diversity analysis showed that the diversity of the MDMV CP gene is fairly high (p-distance: up to 0.136). During sequence analysis, a 13 amino-acid residue insertion and an 8 amino-acid residue deletion were found within the N-terminal region of the CP gene. The phylogenetic analysis showed that—unlike other potyvirus species in this subgroup—the MDMV isolates could not be distinguished on the basis of their host plants or geographic origins.     

Genetic analysis of a human rotavirus that belongs to subgroup I but has an RNA pattern typical of subgroup II human rotaviruses.

We have previously found (O. Nakagomi, T. Nakagomi, H. Oyamada, and T. Suto, J. Med. Virol. 17:29-34, 1985), during an epidemiological study in Japan, a novel human rotavirus that belongs to subgroup I but has a long RNA pattern typical of subgroup II human rotaviruses. From the stool specimen containing this virus, we successfully isolated in MA104 cells a rotavirus, designated AU-1, which possesses these novel characteristics. The possibility that strain AU-1 was a laboratory contaminant of an animal rotavirus previously adapted to tissue culture cells was ruled out, and the identity of the AU-1 strain was established. Genetic analysis by RNA-RNA hybridization revealed that the AU-1 strain is not a simple reassortant between subgroup I and II human rotaviruses but that it shares a high level of sequence homology only with the gene encoding VP7 (the major neutralization protein) of serotype 3 human rotaviruses. Weak homology of the genomic RNA segments was also observed between the AU-1 strain and animal rotavirus strains, including rhesus rotavirus strain RRV and bovine rotavirus strain NCDV. These results suggest that the AU-1 strain may be an animal rotavirus that infected a human.     

Sequence comparison of the 3′-terminal parts of the RNA of four German isolates of sugarcane mosaic potyvirus (SCMV)

Summary.  The 3′-termini of the genome of four German isolates of sugarcane mosaic potyvirus (SCMV) were cloned and sequenced. The sequence data covered the 3′ non-coding region (3′NCR), coat protein and part of the nuclear inclusion b (NIb) genes of the isolates. Comparisons of the sequences revealed that the investigated isolates are very closely related. An alignment of the predicted coat protein amino acid sequences of the German isolates with sequence data for other members of the SCMV subgroup, in particular the two SCMV strains, SCMV-SC and SCMV-MDB, showed a limited degree of homology indicating that the German isolates may represent a distinct virus. However, this is mainly due to the previously reported unexpected sequence diversity in the surface exposed N-terminal region of coat protein of SCMV isolates. Comparisons of the amino acid sequences of the core region of the coat proteins and the nucleotide sequences of the 3′ NCR clearly show that the German isolates are strains of SCMV. Received June 7, 1996 Accepted October 24, 1996     

Characterization of a flowering cherry strain of <Emphasis Type="Italic">Cherry necrotic rusty mottle virus</Emphasis>

The host range and complete nucleotide sequences of two Cherry necrotic rusty mottle virus (CNRMV) isolates (FC4 and FC5) infecting flowering cherry accessions imported from Japan are described. Of the plants tested, cherry, peach, apricot and almond became infected, but only sweet cherry cv. ‘Canindex’, Nanking cherry and apricot cv. ‘Tilton’ showed a mild foliar mottle. The genomic sequences of CNRMV-FC4 and CNRMV-FC5 are 8,430 and 8,429 nt in length, excluding the 3′ poly (A) tail. They contain seven open reading frames encoding for a putative virus replicase, “triple gene block” proteins, a coat protein and two proteins with unknown functions. The two CNRMV-FC isolates share 96% identity in the genomic sequences, and their genome organizations are virtually identical to that of a German CNRMV isolate (CNRMV-GER). However, they differ from CNRMV-GER by 14% in the overall nucleotide sequence and 2% (ORF2) to 30% (ORF5a) in the derived amino acid sequences of individual gene products.