A nucleotide sequence rearrangement distinguishes two isolates of satellite tobacco ringspot virus RNA

Several strains of tobacco ringspot virus (TobRV) support the replication and encapsidation of satellite tobacco ringspot virus RNA (STobRV RNA). We have compared the nucleotide sequences of four STobRV RNAs, each initially associated with a different isolate of TobRV. A STobRV RNA from a geranium isolate of TobRV and STobRV RNA from the previously analyzed budblight isolate (J.M. Buzayan, W.L. Gerlach, G. Bruening, P. Keese, and A.R. Gould, 1986, Virology 151, 186-199) differed by a single nucleotide residue substitution. STobRV RNAs from TobRV isolates 62L and NC-87 have the same 360-residue nucleotide sequence. This sequence differs from that of the 359-nucleotide residue budblight STobRV RNA principally at locations 100 through 140. The differences between the two sequences in this region are consistent with a rearrangement of blocks of nucleotide residues. The two sequences can be folded with similar patterns of base pairing. All four STobRV RNAs share a sequence of eighty 5'-terminal and of twenty 3'-terminal residues, including the 5' hydroxyl group and 2':3'-cyclic phosphodiester group.     

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.     

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.     

Cherry leafroll virus infections are affected by a satellite RNA that the virus does not support

Previous research showed that tobacco ringspot virus (TobRV), a member of the nepovirus group, acts as a supporting virus for the 359-nucleotide residue satellite tobacco ringspot virus RNA (STobRV RNA), resulting in STobRV RNA replication and its encapsidation in TobRV coat protein. In some hosts STobRV RNA decreases the yield of TobRV and the severity of TobRV-induced symptoms. We report here that inclusion of STobRV RNA in an inoculum of cherry leafroll virus (CLRV), another nepovirus, prevented the accumulation of CLRV in the inoculated leaves of cowpea (Vigna unguiculata) and caused the symptoms to be less severe than those induced when CLRV was inoculated alone. CLRV spread to, and increased in, uninoculated, developing leaves whether or not it was coinoculated with STobRV RNA. STobRV RNA was not detected in CLRV particles or in extracts of infected tissue from the coinoculated plants, indicating that CLRV does not support STobRV RNA. STobRV RNA strongly interfered with the in vitro translation of the RNAs of CLRV and of cowpea mosaic virus (CPMV). Coinoculation of STobRV RNA and CPMV had no detected effect on infections by CPMV, so inhibition of translation in vitro and of replication in vivo were correlated only for CLRV. Results from a new in vitro assay for proteolytic processing of CLRV polyproteins gave no indication of an effect of STobRV RNA on this reaction.     

The nucleotide sequence of the gene encoding the F protein of canine distemper virus: a comparison of the deduced amino acid sequence with other paramyxoviruses

The nucleotide sequence of the gene encoding the fusion protein of canine distemper virus was determined from cDNA clones derived from virus genome RNA and poly(A)+ RNA extracted from infected cells. The mRNA encoding the F protein is about 2300 nucleotides in length including the 3' poly(A) tail. There is a large open reading frame from nucleotides 86 to 2071 which begins at the first AUG codon in the F mRNA. This reading frame encodes a protein of 662 amino acid residues with a calculated mol. wt. of 73001. The first major hydrophobic domain in the amino acid sequence of the deduced protein (residues 104 to 130) may represent all or part of a signal sequence for cleavage of the N terminal part of the F2 protein. There are four potential N glycosylation sites in the F protein located within the F2 part of the molecule or the putative signal sequence, and one in the F1 portion. A second hydrophobic region corresponds to the proteolytic cleavage site which generates the F2 and F1 subunits. This stretches from residue 225 to 262 and the N terminal part of the F1 protein shows sequence conservation with the other paramyxoviruses. A third major hydrophobic domain near the C terminus of the F protein probably represents the membrane anchor for the F protein (residues 602 to 630). The F1 proteins of six paramyxoviruses are compared and shown to have substantial conservation of those residues important in the maintenance of tertiary structure of this protein.     

Nucleotide sequence and in vitro expression of the capsid protein gene of tobacco ringspot virus

The nucleotide sequence of the 3' terminal 2022 nucleotides (nt) of tobacco ringspot virus (TobRV) RNA 2 has been determined. Protein microsequence analysis of the amino-terminal residues of purified capsid protein localized the capsid protein gene between nt 2014 and 583 (from the 3' terminus) of this sequence. The proteolytic cleavage site that is processed to liberate the capsid protein from the RNA 2-encoded polyprotein was identified as Cys-Ala. The predicted translation product from the gene is a 477 amino acid long polypeptide with a calculated MW of 53 kDa. The gene was modified at the 5' end to facilitate sub-cloning, and to provide it with a methionine initiation codon. The modified gene was sub-cloned, transcribed in vitro and expressed in a rabbit reticulocyte lysate translation system, where it directed the synthesis of a 53 kDa polypeptide. Garnier-Osguthorpe-Robson analyses of the secondary structure of the capsid protein predicted the presence of three beta sheet domains, which suggests that this nepovirus capsid may be structurally analogous to those of the como- and picornaviruses. These and other results from computer analyses of the nucleic acid and amino acid sequences, and comparisons with the capsid proteins of nepoviruses and other related viruses are discussed.     

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.     

The complete nucleotide sequence of RNA2 of blackcurrant reversion nepovirus

The complete nucleotide sequence of blackcurrant reversion nepovirus (BRV) RNA2 was determined from cDNA clones. RNA2 was 6400 nucleotides (nt) in length excluding the 3' poly(A)-tail. It contained a single open reading frame of 4878 nts encoding a polypeptide of 1626 amino acids with a calculated M(r) of 178? omitted?860. The genome organization of BRV RNA2 was similar to that of other nepoviruses, especially those with a large RNA2. The coat protein (CP) was located in the C-terminal region of the large polyprotein and contained amino acid motifs conserved among nepovirus CPs. Sequence comparisons revealed a proline (P) residue surrounded by hydrophobic amino acid residues located upstream of the CP. This P motif is conserved among the putative movement proteins of nepo-, como-, caulimo- and capilloviruses. An N-terminal domain of 350 amino acids of RNA2-encoded polyprotein shared 34 and 35% sequence identity with the N-terminal domains of tomato ringspot nepovirus RNA1- and RNA2-encoded polyproteins, respectively. Sequence identities between the N-terminal domains of BRV RNA2 and other nepoviral RNA2s were less than 20%; no common N-terminal motif was found.     

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.     

Nucleotide sequences of the 3' leader and 5' trailer regions of human respiratory syncytial virus genomic RNA.

The nucleotide sequences of the 3' extracistronic (leader) and 5' extracistronic (trailer) regions were determined for genomic RNA (vRNA) of human respiratory syncytial virus (RSV) strain A2. To sequence the 3' leader region, vRNA was extracted from purified virions, size-selected, polyadenylated, copied into cDNA, amplified by the polymerase chain reaction, cloned, and sequenced. The 3' leader sequence is 44 nt, which is somewhat shorter than its counterparts (50 to 70 nt) in other nonsegmented negative-strand viruses sequenced to date. The 5' trailer region was mapped and sequenced in part directly by dideoxynucleotide sequencing of vRNA. The sequence was confirmed and completed by analysis of cDNA clones derived from vRNA. The 5' trailer sequence is 155 nt in length, which is substantially longer than its counterparts (40 to 70 nt) in other nonsegmented negative-strand viruses. Ten of the 11 terminal nt of the 3' leader and 5' trailer regions were complementary. Among the other paramyxoviruses, the terminal 5 to 16 nt of the leader and trailer regions are highly conserved, but the corresponding RSV sequences were identical to the others only for the terminal 2 nt of each end. Surprisingly, the termini of the RSV leader and trailer regions were in somewhat better agreement with those of the rhabdoviruses vesicular stomatitis virus and rabies virus, sharing identity for the first 3 or 4 nt.     

The genome structure of turnip crinkle virus

The nucleotide sequence of turnip crinkle virus (TCV) genomic RNA has been determined from cDNA clones representing most of the genome. Segments were confirmed using dideoxynucleotide sequencing directly from viral RNA, and the 3' terminal sequence was confirmed by chemical sequencing of end-labeled genomic RNA. Three open reading frames (ORFs) have been identified by examination of the deduced amino acid sequences and by comparison with the ORFs found in the genome of carnation mottle virus. ORF 1 initiates near the 5' terminus of the genome and is punctuated by an amber termination codon. Translation of ORF 1 would yield a 28-kDa protein and an 88-kDa read-through product. The read-through domain possesses amino acid sequence similarities with putative viral RNA polymerases. ORFs 2 and 3 encode products of 38 (coat protein) and 8 kDa, respectively, which are expressed from subgenomic mRNAs. The organization of the TCV genome suggests that TCV is closely related to carnation mottle virus and distinct from members classified in other small RNA virus groups, such as the tombus- and sobemoviruses.     

Nucleotide sequence of the Lassa virus (Josiah strain) S genome RNA and amino acid sequence comparison of the N and GPC proteins to other arenaviruses

The complete nucleotide sequence of the S genome RNA of the Josiah strain of Lassa virus was determined from cloned cDNA. The S RNA is 3402 nucleotides long with a calculated molecular weight of 1.09 x 10(6) Da. The nucleotide base composition is 26.84% adenine, 21.40% guanine, 22.75% cytosine, and 29.01% uridine. The 5' and 3' terminal nucleotide sequences are conserved and complimentary for 19 nucleotides, the nucleoprotein and glycoprotein genes are arranged in ambisense coding strategy, and the intergenic region contains an inverted complimentary sequence, as do all other arenavirus S RNAs characterized to date. Amino acid sequence comparisons between the nucleoproteins and glycoproteins of the Josiah and Nigerian (N sequences only) strains of Lassa virus, the WE and ARM strains of lymphocytic choriomeningitis virus (LCMV), Tacaribe, and Pichinde viruses are presented. These findings reveal that the G2 envelope glycoprotein is more conserved among different arenaviruses than the internal nucleoprotein.     

Complete sequence of RNA1 of grapevine Anatolian ringspot virus

The nucleotide sequence of RNA1 of grapevine Anatolian ringspot virus (GARSV), a nepovirus of subgroup B, was determined from cDNA clones. It is 7,288 nucleotides in length excluding the 3′ terminal poly(A) tail and contains a large open reading frame (ORF), extending from nucleotides 272 to 7001, encoding a polypeptide of 2,243 amino acids with a predicted molecular mass of 250 kDa. The primary structure of the polyprotein, compared with that of other viral polyproteins, revealed the presence of all the characteristic domains of members of the order Picornavirales, i.e., the NTP-binding protein (1B^Hel), the viral genome-linked protein (1C^VPg), the proteinase (1D^Prot), the RNA-dependent RNA polymerase (1E^Pol), and of the protease cofactor (1A^Pro-cof) shared by members of the subfamily Comovirinae within the family Secoviridae. The cleavage sites predicted within the polyprotein were found to be in agreement with those previously reported for nepoviruses of subgroup B, processing from 1A to 1E proteins of 67, 64, 3, 23 and 92 kDa, respectively. The RNA1-encoded polyprotein (p1) shared the highest amino acid sequence identity (66 %) with tomato black ring virus (TBRV) and beet ringspot virus (BRSV). The 5′- and 3′-noncoding regions (NCRs) of GARSV-RNA1 shared 89 % and 95 % nucleotide sequence identity respectively with the corresponding regions in RNA2. Phylogenetic analysis confirmed the close relationship of GARSV to members of subgroup B of the genus Nepovirus.