The M RNA of impatiens necrotic spot Tospovirus (Bunyaviridae) has an ambisense genomic organization.

The nucleotide sequence of Impatiens necrotic spot virus (INSV) M RNA was determined from cDNA clones. The INSV M RNA was 4972 nucleotides in length with two open reading frames (ORFs) in an ambisense genomic organization. The larger ORF near the 3' end of the viral RNA, coding for a protein with a predicted molecular weight of 124.9 kDa, was in the viral complementary sense and produced the G2 and G1 proteins. A smaller ORF in the viral sense was capable of coding for a 34.1-kDa polypeptide, designated the NSm protein. Two subgenomic RNA species were detected in INSV-infected tissue that corresponded to the predicted sizes (3.3 and 1.0 kb) of the G2-G1 and NSm mRNAs. The ORFs were separated by a 478 nucleotide A-U-rich intergenic region similar to the regions found in other viral RNAs with ambisense ORFs. The intergenic region was predicted to form a stable stem-loop structure (-81.2 kcal/mole). The ambisense genomic organization is characteristic of the S RNA for members of the Phlebovirus, Uukuvirus, and Tospovirus genera in the Bunyaviridae family. This is the first report of an ambisense Bunyaviridae M RNA.     

Sequence analysis of the medium RNA segment of three Simbu serogroup viruses,Akabane, Aino,and Peaton viruses

The sequence analysis was carried out for the medium (M) RNA segment of the Akabane virus (AKAV), Aino virus (AINV), and Peaton virus (PEAV) of the Simbu serogroup of the genus Orthobunyavirus of the family Bunyaviridae. The complementary sequences of the M RNA segments of AKAV, AINV, and PEAV contain a single large open reading frame (ORF), like other orthobunyaviruses. The ORFs potentially encode 1401 amino acids (aa), 1404 aa, and 1400 aa polypeptides, respectively. The identity of the M segment among these viruses is remarkably low, although previous researchers reported that the small RNA segments are highly conserved. Because the M segment codes for the viral surface glycoproteins G1 and G2, the variability of the M segment may affect the antigenicity of these viruses. Phylogenetic studies based on the M and S segment sequences suggested that genetic reassortment has been occurring among ancestral viruses of the three Simbu serogroup viruses throughout their evolution.     

Nucleotide sequence and deduced amino acid sequence of the medium RNA segment of Oropouche, a Simbu serogroup virus: comparison with the middle RNA of Bunyamwera and California serogroup viruses

The Bunyavirus genus of the family Bunyaviridae contains 18 serogroups. To date nucleotide sequence data has been obtained for three serogroups, Bunyamwera, California and Simbu, based on analysis of the small (S) RNA segment. In comparison, there is only nucleotide sequence data for the large and medium (M) RNA segments for members of the Bunyamwera and California serogroups. In this paper we report the nucleotide sequence of the M RNA of Oropouche (ORO) virus, a member of the Simbu serogroup. The M RNA was 4396 nucleotides in length with G1, G2 and NSm proteins similar in size to those reported for members of the Bunyamwera and California serogroups. However, there was limited nucleotide (50-52%) and amino acid (30-32%) homology between ORO virus M RNA and those of published members of the other two serogroups. The Bunyamwera and California serogroups are more closely related to each other than the Simbu serogroup virus Oropouche. These data were consistent with that previously reported for the S RNA (Saeed et al., 2000. J. Gen. Virol. 81, 743-748). It has been noted previously that three of four potential N-linked glycosylation sites of the Bunayamwera and California serogroups are conserved in G1 and G2 proteins. In contrast, ORO virus was found to have only three potential N-linked glycosylation sites of which only one, in G1, was conserved with members of the other two serogroups. Comparison of M RNA sequences of different strains of ORO virus revealed genetic variation consistent with that reported previously for the S RNA.     

Complete nucleotide sequence of the M RNA segment of Rift Valley fever virus

The entire M RNA segment of the phlebovirus Rift Valley fever virus (RVFV) has been molecularly cloned and the complete nucleotide sequence determined. The RNA is 3884 nucleotides in length, corresponding to a molecular weight of 1.38 X 10(6), having a base composition of 27.3% A, 25.4% G, 27.2% U, and 20.1% C. Sequences present at the 3' and 5' termini of the molecule are largely complementary for some 51 residues and can form a stable duplex structure when the potential secondary structure of the entire molecule is considered. A single major open reading frame, capable of encoding 1206 amino acids (131,845 Da), was found in the viral-complementary sequence ("positive" polarity). Amino-terminal amino acid sequencing of the purified viral glycoproteins G1 and G2 allowed for the positioning of the coding sequences for these polypeptides within this major open reading frame in the following orientation with respect to the genomic M RNA: 3'-G2-G1-5'. From the predicted amino acid composition of the two mature viral glycoproteins, both were found to have a high cysteine content (G2, 6%; G1, 5%). Sequences within the open reading frame capable of encoding up to 23,000 Da of polypeptide were found in addition to those required for the viral glycoproteins. The potential contribution of these sequences to the coding capacity of the M RNA, viral protein processing, and intracellular protein distribution is discussed.     

Primary structure of the large (L) RNA segment of nephropathia epidemica virus strain H?lln?s B1 coding for the viral RNA polymerase

The L RNA segment of the nephropathia epidemica virus (NEV) strain H?lln?s B1 was characterized by molecular cloning of the corresponding cDNA and subsequent determination of the DNA nucleotide sequence. The L RNA segment is 6550 nucleotides long with complementarity of 20 bases at the 3' and 5' termini. The viral messenger sense RNA contains one major open reading frame (ORF) with a coding capacity of 2156 amino acid residues encoding a protein with a calculated molecular weight of 246 kDa and an IEP of pH 7.4. Comparison of the deduced amino acid sequences from NEV hantavirus and Bunyamwera virus (BWV) L segment messenger sense RNAs, revealed a high degree of diversity (overall amino acid identity, 17%). However, three clusters of 30-40% amino acid identity were detected. One of these domains, containing an Asp-Asp motif found in many RNA polymerases, also shares amino acid sequence homology with the PB1 polymerase component of influenza type A. These results indicate that the L RNA segment of the NEV codes for the viral RNA-dependent RNA polymerase. The data presented here complete our previous studies on the characterization of the NEV genome by cDNA sequencing of the viral M and S RNA segments.     

Organization of the middle RNA segment of snowshoe hare Bunyavirus

The genetic organization of the M RNA segment of snowshoe hare (SSH) virus, a member of the Bunyavirus genus of the family Bunyaviridae, has been determined. The middle (M) RNA segment has a single open reading frame (ORF) of 1441 amino acids. We have used amino- and carboxy-terminus sequencing and synthetic peptides to map proteins within the ORF. The order of the proteins translated from the single large open reading frame is G2, NSm, G1. The G2 protein extends from amino acids 14 to 299. The molecule is 286 residues long, with a computed nonglycosylated molecular weight of 31,973 Da. It is preceded by a cleaved 13 amino acid signal sequence. G2 includes a long highly hydrophobic sequence and contains three potential N-linked glycosylation sites. The G1 protein occupies the C-terminal end of the open reading frame from amino acids 474 to 1441 (968 amino acid residues) and has a computed nonglycosylated, molecular weight of 108,981 kDa. It has two potential N-linked glycosylation sites, and a potential transmembrane region followed by a potential cytoplasmic domain at the C-terminal end. If membrane associated it has an orientation of N-terminus outer, C-terminus inner. Limited trypsin digestion removes a 33-kDa fragment from the N-terminal end, leaving a virion-associated truncated G1 molecule (amino acids 762 to 1441) with a single N-linked glycosylation site. Between the G2 and G1 molecules there are 174 amino acids, sufficient to code for 19 kDa of protein. Some antibodies raised against peptides within this region react with proteins of 11 kDa (NSm) and 10 kDa present in infected cell lysates, but the exact relationship of these proteins to the open reading frame remains to be determined.     

Nucleotide sequence analysis of the large (L) genomic RNA segment of Bunyamwera virus, the prototype of the family Bunyaviridae

The complete nucleotide sequence of the large (L) genome segment of Bunyamwera virus has been determined from overlapping cDNA clones. The segment is 6875 nucleotides long and has a base composition of 29.8% A, 17.9% C, 15.4% G, and 36.9% U. Eighteen of the terminal 19 nucleotides at the 3' and 5' ends are complementary. In the viral-complementary (+ sense) RNA there is a single long open reading frame (ORF) from AUG at bases 51-53 to a UAG stop codon at bases 6765-6767; this ORF encodes a polypeptide of 2238 amino acids (MW 259,000), corresponding to the L protein which has been mapped to the L RNA segment by analysis of reassortants of Bunyamwera, Batai, and Maguari viruses. The amino-terminal 46 amino acids of the L protein show strong homology (63% identity) with the amino-termini of ORFs predicted from limited sequence analysis of the L segments of La Crosse and snowshoe hare bunyaviruses. Comparison with the polymerase proteins encoded by other negative-strand viruses showed weak homology with part of the influenza virus PB1 protein, but no homology was detected with the other influenza virus polymerase proteins nor with the L proteins of arenaviruses, paramyxoviruses, and rhabdoviruses. At the 5' end of genomic (- sense) RNA there is an AUG-initiated ORF potentially encoding a protein of 14,700; the significance of this ORF is unknown at present.     

The glycoprotein gene of Chrysanthemum stem necrosis virus and <Emphasis Type="Italic">Zucchini lethal chlorosis virus</Emphasis> and molecular relationship with other tospoviruses

Two tospoviruses, Chrysanthemum stem necrosis virus (CSNV) and Zucchini lethal chlorosis virus (ZLCV), cause economical losses in several ornamental and vegetable crops in Brazil. The nucleocapsid gene and movement protein sequences had already been reported for both viruses, though the glycoprotein precursor gene sequence was not available. In this study, cDNA fragments (ca. 4 kb) of the M RNA 3' portion of CSNV (isolate Chry-1) and ZLCV (isolate 1038), including the complete glycoprotein precursor gene, partial NSm gene, and the entire intergenic and 3' untranslated regions, were cloned and sequenced. The sequences were assembled with the corresponding 5' region sequence (NSm gene and 5'UTR) of the same isolates to build up the complete sequence of the M RNA segment of both species. The M RNA of CSNV was 4,828 nucleotide-long, while of ZLCV 4,836 nucleotides. Both M RNA molecules comprised two ORFs in an ambisense arrangement. The vcRNA coded for the viral glycoprotein (Gn/Gc) precursor gene of CSNV and ZLCV (both with 127.5 kDa). Comparison of deduced amino acids of the CSNV and ZLCV glycoprotein precursor genes with those of other tospoviruses showed the highest identity with that of Tomato spotted wilt virus (86%) and with that of CSNV (82%), respectively. However, the nucleotide sequence of the intergenic and 3' untranslated regions of CSNV and ZLCV shared lower identities with other tospoviruses. The glycoprotein precursor gene is thought to be a good candidate as additional classification parameter for Tospovirus taxonomy. The presence of the RGD motif in both Gc proteins indicated that they are typical American tospoviruses, which was confirmed by phylogenetic analysis. The membrane topology of both glycoproteins is discussed.     

Hantaan virus M RNA: coding strategy, nucleotide sequence, and gene order

The M genome segment of Hantaan virus was molecularly cloned and the nucleotide sequence of cDNA was determined. The virion RNA is 3616 bases long with 3'- and 5'-terminal nucleotide sequences complementary for 18 bases. A single long open reading frame in the viral complementary-sense RNA had the potential to encode 1135 amino acids or a polypeptide of 126,000 Da. Amino-terminal sequences of isolated G1 and G2 envelope glycoproteins were determined, revealing a gene order with respect to message sense RNA of 5'-G1-G2-3'. Mature G1 begins 18 amino acids beyond the first AUG of the open reading frame, preceded by a short, hydrophobic leader sequence. G2 begins at the 649th amino acid of the open reading frame and also follows a hydrophobic sequence. Carboxy termini of G1 and G2 were localized and gene order was verified by immune precipitation of Hantaan proteins with antisera to synthetic peptides generated by using amino acid sequences derived from the cDNA sequence. The antipeptide sera were also reactive by immunoblotting with SDS-denatured G1 and G2. Molecular weights of 64,000 and 53,700 were calculated for the G1 and G2 glycoproteins, respectively, from their predicted amino acid sequences. Five potential asparagine-linked glycosylation sites were contained within the G1 amino acid sequence and two within the G2 sequence. These data are consistent with our previous estimates of the molecular weights and extent of glycosylation of the Hantaan envelope glycoproteins.     

Comparison of the 5' and 3' termini of tomato ringspot virus RNA1 and RNA2: evidence for RNA recombination

The sequences of the 5' terminal 1140 and 3' terminal 1546 nt of tomato ringspot virus (TomRSV) RNA1 have been determined. These sequences share a high degree of nucleotide sequence similarity with the previously determined TomRSV RNA2 sequence. Eighty-eight percent of the 5' terminal 907 nt of TomRSV RNA1 and RNA2 contain identical nucleotide residues; the first 459 nt are identical at all positions, whereas the next 447 nt are identical at only 75.8% of the nucleotide positions. The region of similarity includes not only the 5' nontranslated leader but also sequence probably encoding polyproteins. The 3' terminal 1533 nt of TomRSV RNA1 and RNA2 are identical and are noncoding. The sequences common to RNA1 and RNA2 account for almost 35% of the total genomic sequence. It is possible that the similar sequences at both ends of TomRSV RNA1 and RNA2 are a result of recombination between these two genomic RNA components.     

Characterization of tomato zonate spot virus,a new tospovirus in China

An isolate of a new tospovirus species, causing concentric zoned ringspots on fruits and necrotic lesions on leaves of infected plants, was characterised based on particle morphology, host range and serological properties. The complete nucleotide sequences of large (L), medium (M), and small (S) RNAs of this virus were found to contain 8919, 4945, and 3279 nts respectively. The L RNA encoded the RNA-dependent RNA polymerase (RdRp) (2885 aa, 332.7 kDa). The M RNA encoded a non-structural (NSm) protein (309 aa, 34.4 kDa) and a viral glycoprotein precursor (Gn/Gc) (1122 aa, 127.4 kDa). The S RNA encoded a non-structural protein (NSs) (459 aa, 51.9 kDa) and the nucleocapsid (N) protein (278 aa, 30.6 kDa). This N protein shared amino acid identities of 80.9% with those of calla lily chlorotic spot virus. Our results suggest that the virus studied here belongs to a new tospovirus species, for which the name tomato zonate spot virus is proposed. Jia-Hong Dong and Xiao-Fei Cheng: making equal contributions to this paper. The nucleotide sequence data reported in this paper are available in the GenBank database under accession numbers: EF552433 (S RNA), EF552434 (M RNA), EF552435 (L RNA).     

Nucleotide sequence and coding capacity of the large (L) genomic RNA segment of Seoul 80-39 virus, a member of the hantavirus genus.

The nucleotide sequence of the large (L) genomic RNA segment of Seoul 80-39 virus was determined from overlapping cDNA clones. The virion L RNA segment is 6530 nucleotides long. The 3' and 5' terminal sequences are inversely complementary for 15 bases. The viral complementary-sense RNA contains a single open reading frame from an AUG codon at nucleotide position 37-39 to a UAA stop codon at nucleotide position 6490-6492. This ORF could encode a polypeptide of 2151 amino acids (246,662 kDa) which likely corresponds to the L protein detected in purified viral particles (Elliott et al., 1984) and is assumed to be an RNA-dependent RNA polymerase molecule (Schmaljohn and Dalrymple, 1983). Comparison of the L protein of the Seoul 80-39 virus with the polymerase proteins encoded by other negative-stranded RNA viruses revealed 44% similarity only with the part of the Bunyamwera virus L protein (Elliott, 1989) and a very weak homology with the PB1 protein of influenza virus.     

RNA segment 5 of broadhaven virus, a tick-borne orbivirus, shows sequence homology with segment 5 of bluetongue virus

The sequence of Broadhaven (BRD) virus segment 5, the major genetic determinant of serotype, is 1658 nucleotides in length and contains a single open reading frame (ORF) having the coding capacity for a protein of Mr 52.5K. Comparison of the ORF of segment 5 of BRD virus with published sequences of bluetongue virus (BTV) revealed 30% nucleotide homology and 31% amino acid homology with the protein encoded by segment 5 of BTV serotype 10. Significant homology was not shown with segment 2 of BTV, the major genetic determinant of the BTV serotype. The sequences at the 3' and 5' ends determined for BRD segment 5 were similar to the respective 3' and 5' regions of BTV. The sequence data provide evidence of an evolutionary relationship between two ecologically distinct groups of orbiviruses and demonstrate changes that have occurred in the functions of genetically related genomic segments.     

Determination of the coding capacity of the M genome segment of nephropathia epidemica virus strain H?lln?s B1 by molecular cloning and nucleotide sequence analysis

The M genome RNA segment of nephropathia epidemica virus (NEV) strain H?lln?s B1 was characterized by molecular cloning and DNA nucleotide sequencing of the corresponding cDNA clones. The size of the M RNA segment is 3682 nucleotides. The 3' and 5' terminal sequences are complementary for 21 bases and their predicted secondary structure is very stable. The viral complementary messenger RNA possesses a single long open reading frame with a coding capacity of 1148 amino acids (polypeptide of 126 kDa). A comparison of the NEV M segment to that of Hantaan virus strain 76-118 reveals 61% sequence homology at the nucleotide level and 53% at the deduced amino acid level. Four out of five potential asparagine-linked glycosylation sites of the encoded glycoproteins have been conserved between NEV and Hantaan M. The isoelectric points (IEP) are nearly identical. Furthermore it was found that 90% of all cysteine residues have been conserved. Putative NEV G1 and G2 are preceded by a short hydrophobic sequence as shown for G1 and G2 of Hantaan virus. Hydrophilicity profiles of the two segments are of striking similarity. These data indicate that NEV- and Hantaan virus M-encoded polypeptides seem to be very similar in structure and function despite the relatively low amino acid sequence homology.     

Dugbe nairovirus M RNA: Nucleotide sequence and coding strategy

The coding assignments of the medium-sized (M) RNA segment of the Dugbe (DUG) virus (Nairovirus, Bunyaviridae) were investigated. The complete nucleotide sequence of 4888 nucleotides (nt) contained one long open reading frame in the viral complementary RNA, extending from an AUG start codon at nt 48-50 to a stop codon at nt 4701-4703 (numbered from the 5' terminus of vcRNA). Comparison of the terminal sequences with the ends of the DUG S segment revealed sequence identity between the first nine nucleotides of both segments. No sequence homologies were found with the M segments of other members of the Bunyaviridae, or with their polypeptide products. Expression of portions of the DUG M open reading frame in Escherichia coli demonstrated the carboxyl terminal region of the M open reading frame codes for the G1 structural glycoprotein, which is the target for neutralising antibodies. Confirmation of this assignment was obtained by sequencing the amino terminus of the G1 protein. Two nonstructural glycoproteins which share epitopes with G1 were identified in virus-infected cells, one of which (85 kDa) is processed over a period of several hours to produce G1. The G2 coding region was located upstream of the G1 sequence. The region between the carboxyl terminus of G2 and the 5' end of the long open reading frame apparently encodes a nonstructural protein of about 70 kDa, which is a precursor of the G2 protein.     

Complete nucleotide sequence of the M RNA segment of Uukuniemi virus encoding the membrane glycoproteins G1 and G2

We have determined the complete nucleotide sequence of the virion M RNA segment of Uukuniemi virus (Uukuvirus genus, Bunyaviridae) from cloned cDNA. The RNA that encodes the two membrane glycoproteins G1 and G2 is 3231 residues long (mol wt 1.1 X 10(6)). The 5' and 3' ends of the RNA are partially complementary to each other for some 30 bp, enabling the formation of a stable panhandle structure (delta G = -40 kcal/mol) and the circularization of the molecule. The extreme 5' and 3' terminal nucleotides are identical for 10 to 13 residues to those of the M RNA of Punta Toro and Rift Valley fever viruses, two members of the Phlebovirus genus. A single open reading frame comprising 1008 amino acid residues (mol wt 113,588) was found in the mRNA-sense strand between nucleotides 18 and 3042. This probably corresponds to the previously identified 110,000-Da precursor (p110) of G1 and G2. By comparing the partial aminoterminal sequences of purified G1 and G2 with the deduced protein sequence we confirmed that the gene order is NH2-G1-G2-COOH. Both mature G1 and G2 are preceded by a stretch of 17 predominantly hydrophobic amino acids likely to represent the signal sequences. At their COOH-terminal ends, G1 and G2 have a hydrophobic stretch of amino acids, 19 and 27 residues, respectively, that probably anchors the proteins to the lipid bilayer. The sequence indicates that mature G2 is 495 amino acids long (mol wt 54,869), whereas the exact size of G1 is unclear, since the location of the COOH-terminus of G1 is not known. An upper value of 479 amino acids (mol wt 55,181) can, however, be suggested. Both G1 and G2 contain four potential glycosylation sites for Asn-linked glycans and both are unusually rich in cysteines, 6.1% in G1 and 5.4% in G2. Comparison of the amino acid sequence of the M RNA product of Uukuniemi virus with that of Punta Toro and Rift Valley fever viruses showed in both cases a weak homology that was more pronounced for the proteins located at the COOH-terminal end of the precursor. This suggests a distant evolutionary relationship between the Phlebo- and Uukuvirus genera.