The cloning and sequencing of the virion protein genes from a British isolate of porcine respiratory coronavirus: comparison with transmissible gastroenteritis virus genes.

Previous analysis of porcine respiratory coronavirus (PRCV) mRNA species showed that mRNAs 2 and 3 were smaller than the corresponding transmissible gastroenteritis virus (TGEV) mRNA species (Page et al. (1991) J. Gen. Virol. 72, 579-587). Sequence analysis showed that mRNA 3 was smaller due to the presence of a new putative RNA-leader binding site upstream of the PRCV ORF-3 gene. However, this observation did not explain the deletion observed in PRCV mRNA 2. Polymerase chain reaction (PCR) was used to generate cDNA from the 3' coding region of the putative polymerase gene to the poly (A) tail of PRCV for comparison to the equivalent region from TGEV. The PRCV S protein was found to consist of 1225 amino acids, which had 98% similarity to the TGEV S protein. However, the PRCV S gene contained a 672 nucleotide deletion, corresponding to 224 amino acids (residues 21 to 245 in TGEV S protein), 59 nucleotides downstream of the S gene initiation codon. The PRCV genome from the ORF-3 gene to the poly (A) tail was sequenced for comparison to TGEV in order to identify other potential differences between the two viruses. Four ORFs were identified that showed 98% similarity to the TGEV ORF-4, M, N and ORF-7 genes. No other deletions or any PRCV specific sequences were identified.     

Genomic organization and expression of the 3' end of the canine and feline enteric coronaviruses.

The genomic organization at the 3' end of canine coronavirus (CCV) and feline enteric coronavirus (FECV) was determined by sequence analysis and compared to that of feline infectious peritonitis virus (FIPV) and transmissible gastroenteritis virus (TGEV) of swine. Comparison of the latter two has previously revealed an extra open reading frame (ORF) at the 3' end of the FIPV genome, lacking in TGEV, which is currently designated ORF 6b. Both CCV and FECV possess 6b-related ORFs at the 3' ends of their genomes. The presence of ORF 6b in three of four viruses in this antigenic cluster strongly suggests that TGEV has lost this ORF by deletion. The CCV ORF 6b is collinear with that of FIPV, but the predicted amino acid sequences are only 58% identical. The FECV ORF 6b contains a large deletion compared to that of FIPV, reducing the collinear part to 60%. The sequence homologies were highest between CCV and TGEV on the one hand and between FECV and FIPV on the other. Previously, we showed that the expression product of the FIPV ORF 6b can be detected in infected cells by immunoprecipitation (Vennema et al., 1992). In the present study we have performed similar experiments with CCV and FECV. In infected cells both viruses produced proteins related to but different from the FIPV 6b protein.     

Complete genomic sequence of turkey coronavirus

Turkey coronavirus (TCoV), one of the least characterized of all known coronaviruses, was isolated from an outbreak of acute enteritis in young turkeys in Ontario, Canada, and the full-length genomic sequence was determined. The full-length genome was 27,632 nucleotides plus the 3' poly(A) tail. Two open reading frames, ORFs 1a and 1b, resided in the first two thirds of the genome, and nine additional downstream ORFs were identified. A gene for hemagglutinin-esterase was absent in TCoV. The region between the membrane (M) and nucleocapsid (N) protein genes contained three potential small ORFs: ORF-X, a previously uncharacterized ORF with an associated putative TRS within the M gene (apparently shared among all group III coronaviruses), and previously described ORFs 5a and 5b. The TCoV genome is organized as follows: 5' UTR--replicase (ORFs 1a, 1b)--spike (S) protein--ORF3 (ORFs 3a, 3b)--small envelop (E or 3c) protein--membrane (M) protein--ORF5 (ORFs X, 5a, 5b)--nucleocapsid (N) protein--3' UTR--poly(A). TCoV genome structure and sequence was most similar, but distinct from, avian infectious bronchitis virus (IBV). This is the first complete genome sequence for a TCoV and confirms that TCoV belongs to group III coronaviruses.     

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.     

A new positive-strand RNA virus with unique genome characteristics from the red imported fire ant, Solenopsis invicta

We report the discovery of a new virus with unique genome characteristics from the red imported fire ant, Solenopsis invicta. This virus represents the second identified from this ant species. It is provisionally named Solenopsis invicta virus 2 (SINV-2). The SINV-2 genome was constructed by compiling sequences from successive 5' RACE reactions, a 3' RACE reaction, and expressed sequence tag, c246 (accession number EH413675), from a fire ant expression library. The SINV-2 genome structure was monopartite, polycistronic and RNA-based. The genome consensus sequence (EF428566) was 11,303 nucleotides in length, excluding the poly(A) tail present on the 3' end. Analysis of the genome revealed 4 major open reading frames (ORFs; comprised of > or =100 codons) and 5 minor ORFs (comprised of 50-99 codons) in the sense orientation. No large ORFs were found in the inverse orientation suggesting that the SINV-2 genome was from a positive-strand RNA virus. Further evidence for this conclusion includes abolished RT-PCR amplification by RNase treatment of SINV-2 nucleic acid template, and failure to amplify without first conducting cDNA synthesis. Blastp analysis indicated that ORF 4 contained conserved domains of an RNA-dependent RNA polymerase, helicase, and protease, characteristic of positive-strand RNA viruses. However, the protease domain and putative structural proteins (ORFs 1, 2, and 3) were less well conserved. Phylogenetic analysis of the RdRp, helicase, and ORF 1 indicate unique placement of SINV-2 exclusive from the Dicistroviridae, iflaviruses, Picornaviridae, and plant small RNA viruses.     

The S gene of canine coronavirus, strain UCD-1, is more closely related to the S gene of transmissible gastroenteritis virus than to that of feline infectious peritonitis virus.

To gain insight into the genetic relationships among six canine coronavirus (CCV) strains, the variable region of the spike (S) protein gene was sequenced. The CCV strains were: two ATCC reference strains, the Insavc-1 vaccine strain, the National Veterinary Services Laboratories (Ames, IA) challenge strain, and two California field isolates (UCD-1 and UCD-2) from the 1970s. All six strains, downstream of the nucleocapsid (N) protein gene, had sufficient size for an ORF 7b, and thus, none were transmissible gastroenteritis virus (TGEV)-like since TGEV lacks ORF 7b. By sequence analysis of the variable domain at the 5' end of the S gene, five of the six CCV strains had a high degree of identity with feline infectious peritonitis virus (FIPV). However, one CCV field isolate (UCD-1) was different and had a high degree of identity with the 5' end of the TGEV S gene. This suggests that RNA recombination occurred at this site between antigenically related coronaviruses. The low passage field isolates, UCD-1 and UCD-2, varied in their initial infectivity for swine testicular cells suggesting that sequence differences in the variable domain of the S gene may account for biological variation among CCVs.     

Differentiation of transmissible gastroenteritis virus from porcine respiratory coronavirus and other antigenically related coronaviruses by using cDNA probes specific for the 5'' region of the S glycoprotein gene.

Two cDNA clones prepared from the virulent Miller strain of transmissible gastroenteritis virus (TGEV) were identified, and their nucleotide sequences were determined. The clones were nonoverlapping and located in the 5' region of the S glycoprotein gene. Their nucleotide and predicted amino acid sequences were compared with published sequences of the attenuated Purdue strain of TGEV and feline infectious peritonitis virus (FIPV). TGEV clone pE21 contained 381 bp of the S glycoprotein gene and had greater than 98% nucleotide and amino acid sequence homology with Purdue TGEV and over 87% nucleotide and amino acid sequence homology with FIPV. TGEV clone pD24 contained 267 bp of the S glycoprotein gene. It had greater than 98% nucleotide and amino acid sequence homology with Purdue TGEV but only 54% nucleotide sequence homology and 24% amino acid sequence homology with FIPV. A probe prepared from pD24 could differentiate TGEV from porcine respiratory coronavirus and other antigenically related coronaviruses, FIPV, feline enteric coronavirus, and canine coronavirus in a dot blot hybridization assay.     

The nucleotide sequence and genome organization of Sclerophthora macrospora virus A

Sclerophthora macrospora virus A (SmV A) found in S. macrospora, the pathogenic fungus responsible for downy mildew of gramineous plants, is a small icosahedral virus containing three segments (RNAs 1, 2, and 3) of the positive-strand ssRNA genome. In the present study we report the complete nucleotide sequence of the SmV A genome. The viral genome RNA 1 consists of 2928 nucleotides (nt) and has two open reading frames (ORFs 1a and 1b). ORF 1a contains the motifs of RNA-directed RNA polymerase (RdRp). The function of ORF 1b is unknown. RNA 2 consists of 1981 nt and single ORF (ORF 2). ORF 2 encodes a capsid protein. RNA 3 consists of 977 nt but not any ORFs, suggesting it as a satellite RNA. The deduced amino acid sequence of ORF 1a shows some similarity to those of RdRp of certain positive-strand RNA viruses, especially to the members of the family Nodaviridae, and that of ORF 2 to CP of the members in the family Tombusviridae. The nucleotide sequence of RNA 3 shows a 40-nucleotide length of partial similarity to S. macrospora virus B (SmV B) RNA. The capsid of SmV A is composed of two capsid proteins, CP 1 (p43) and CP 2 (p39), both encoded in ORF 2. CP 2 is apparently derived from CP 1 via proteolytic cleavage at the N-terminus. The genome organization of SmV A is characteristic and distinct from those of other known fungal RNA viruses, including SmV B. These results suggest that SmV A should be classified into a new group of mycoviruses.     

Analysis of the genome sequence of an alpaca coronavirus

Coronaviral infection of New World camelids was first identified in 1998 in llamas and alpacas with severe diarrhea. In order to understand this infection, one of the coronavirus isolates was sequenced and analyzed. It has a genome of 31,076 nt including the poly A tail at the 3' end. This virus designated as ACoV-00-1381 (ACoV) encodes all 10 open reading frames (ORFs) characteristic of Group 2 bovine coronavirus (BCoV). Phylogenetic analysis showed that the ACoV genome is clustered closely (>99.5% identity) with two BCoV strains, ENT and LUN, and was also closely related to other BCoV strains (Mebus, Quebec, DB2), a human corona virus (strain 043) (>96%), and porcine hemagglutinating encephalomyelitis virus (>93% identity). A total of 145 point mutations and one nucleotide deletion were found relative to the BCoV ENT. Most of the ORFs were highly conserved; however, the predicted spike protein (S) has 9 and 12 amino acid differences from BCoV LUN and ENT, respectively, and shows a higher relative number of changes than the other proteins. Phylogenetic analysis suggests that ACoV shares the same ancestor as BCoV ENT and LUN.     

Nucleotide sequence of the ononis yellow mosaic tymovirus genome

The nucleotide sequence of the genome of ononis yellow mosaic tymovirus (OYMV) has been determined. The genome is single-stranded RNA, 6211 nucleotides long, and has three main open reading frames (ORFs), two of them overlapping. The largest ORF (nucleotides 179-5509) encodes a polyprotein of 1776 amino acid residues that has sequence similarities with polymerases of other viruses with RNA genomes. The smaller overlapping ORF (nucleotides 172-1965) encodes a protein of 597 amino acids of unknown function. The third ORF located at the 3' end of the genome (nucleotides 5487-6065) is the virion protein gene, and it overlaps by 20 nucleotides the 3' terminus of the largest ORF. The organization of the OYMV genome, its sequence, and the sequences of the protein it encodes are clearly similar to those of two other tymoviruses, turnip yellow mosaic virus and eggplant mosaic virus. The 5' terminal noncoding region of the OYMV genome is much longer than the same region of other tymoviral genomes and includes a direct duplication of a sequence of 21-23 nucleotides.     

Map location of lactate dehydrogenase-elevating virus (LDV) capsid protein (Vp1) gene

Lactate dehydrogenase-elevating virus (LDV) is currently classified within the Togaviridae family. In an effort to obtain further information on the characteristics of this virus, we have begun to sequence the viral RNA genome and to map the virion structural protein genes. A sequence of 1064 nucleotides, which represents the 3' terminal end of the genome, was obtained from LDV cDNA clones. A 3' noncoding region of 80 nucleotides followed by two complete open reading frames (ORFs) were found within this sequence. The two ORFs were in different reading frames and overlapped each other by 11 nucleotides. One ORF encoded a protein of 170 amino acids and the other ORF, located adjacent to the 3' noncoding region of the viral genome, encoded a 114 amino acid protein. Thirty-three N-terminal residues were sequenced directly from purified LDV capsid protein, Vp1, and this amino acid sequence mapped to the ORF adjacent to the 3' noncoding region. The presence of overlapping ORFs and the 3' terminal map position of Vp1 indicate that LDV differs significantly from the prototype alpha togaviruses.     

Analysis of the terminal sequences of the genome segments of four orbiviruses

The dsRNA genome segments of bluetongue virus (BTV) types 1 and 20 and Ibaraki virus (a member of the epizootic haemorrhagic disease (EHD) serogroup) have conserved sequences of six bases at both of their 3' termini. One strand of all the genome segments analysed ends in 3'CAUUCA ... 5' while the other strand ends in 3'CAAUUU ... 5'. These conserved sequences are identical to those previously reported for BTV types 10 and 11 (A. Kiuchi, C. D. Rao, and P. Roy (1983), "Double-Stranded RNA Viruses" (R. W. Compans and D. H. L. Bishop, eds.), pp. 55-64. Elsevier, New York; C. D. Rao, A. Kiuchi, and P. Roy (1983), J. Virol. 46, 378-383). The 3' terminal sequences of segments 3 and 10 of the BTV type 1 genome were confirmed by the detection of exactly complementary sequences at the 5' termini of the ssRNA strands of opposite polarity. This also confirmed for these dsRNA segments (and by analogy for all the genome segments of these viruses) that the dsRNA molecules are fully base paired end to end. Using in vitro synthesised mRNA of BTV type 1 in annealing experiments with the two ssRNAs separated from each of the individual genome segments, it was shown that in each case the strand ending in 3'CAUUCA ... 5' is of the same polarity as the mRNA (+ve), while the strand ending in 3'CAAUUU ... 5' is of the opposite (-ve) polarity. The fourth virus analysed (Tilligerry virus, a member of the Eubenangee serogroup) only had five conserved bases at the 3' termini of one strand of its genome segments (3'CAU-CA ... 5') and three conserved bases at the 3' termini of the other strand (3'CA--U ... 5'). Considerable sequence homology was found in the near-terminal nonconserved regions of comparable genome segments from the different viruses, particularly between the different BTV types. There was little evidence, however, for absolute conservation of "segment specific" sequences in these regions of the RNA.     

Sequence of the genomic RNA of nudaurelia beta virus (Tetraviridae) defines a novel virus genome organization.

The monopartite genome of Nudaurelia beta virus, the type species of the Betatetravirus genus of the family Tetraviridae, consists of a single-stranded positive-sense RNA (ss+RNA) of 6625 nucleotides containing two open reading frames (ORFs). The 5' proximal ORF of 5778 nucleotides encodes a protein of 215 kDa containing three functional domains characteristic of RNA-dependent RNA polymerases of ss+RNA viruses. The 3' proximal ORF of 1836 nucleotides, which encodes the 66-kDa capsid precursor protein, overlaps the replicase gene by more than 99% (1827 nucleotides) and is in the +1 reading frame relative to the replicase reading frame. This capsid precursor is expressed via a 2656-nucleotide subgenomic RNA. The 3' terminus of the genome can be folded into a tRNA-like secondary structure that has a valine anticodon; the tRNA-like structure lacks a pseudoknot in the aminoacyl stem, a feature common to both genera of tetraviruses. Comparison of the sequences of Nudaurelia beta virus and another member of the Tetraviridae, Helicoverpa armigera stunt virus, which is in the genus Omegatetravirus, shows identities of 31.6% for the replicase and 24.5% for the capsid protein. The viruses in the genera Betatetravirus and Omegatetravirus of the Tetraviridae are clearly related but show significant differences in their genome organization. It is concluded that the ancestral virus with a bipartite genome, as found in the genus Omegatetravirus, likely evolved from a virus with an unsegmented genome, as found in the genus Betatetravirus, through evolution of the subgenomic RNA into a separate genomic component, with the accompanying loss of the capsid gene from the longer genomic RNA.     

Sequence analysis of the porcine transmissible gastroenteritis coronavirus nucleocapsid protein gene

The 3' end of the 20-kb genome of the Purdue strain of porcine transmissible gastroenteritis coronavirus (TGEV) was copied into cDNA after priming with oligo(dT) and the double-stranded product was cloned into the PstI site of the pUC9 vector. One clone of 2.0-kb contained part of the poly(A) tail and was sequenced in its entirety using the chemical method of Maxam and Gilbert. Another clone of 0.7 kb also contained part of the poly(A) tail and was sequenced in part to confirm the primary structure of the most 3' end of the genome. Two potential, nonoverlapping genes were identified within the 3'-terminal 1663-base sequence from an examination of open reading frames. The first gene encodes a 382-amino acid protein of 43,426 mol wt, that is the apparent nucleocapsid protein on the basis of size, chemical properties, and amino acid sequence homology with other coronavirus nucleocapsid proteins. It is flanked on its 5' side by at least part of the matrix protein gene. The second encodes a hypothetical 78-amino acid protein of 9101 mol wt that is hydrophobic at both ends. A 3'-proximal noncoding sequence of 276 bases was also determined and a conserved stretch of 9 nucleotides near the poly(A) tail was found to be common among TGEV, the mouse hepatitis coronavirus, and the avian infectious bronchitis coronavirus.     

Structure of the gene encoding the M1 protein of sonchus yellow net virus

The gene encoding the M1 protein of sonchus yellow net virus (SYNV), a plant rhabdovirus, has been sequenced and identified by Western blot analysis of SYNV proteins using antibodies directed against a fusion protein derived from a portion of the sequenced gene. The M1 gene is positioned between nucleotides 4039 and 5109 relative to the 3' end of the viral RNA and is the fourth gene from the 3' end of the genome. The 1071-nucleotide (nt) M1 gene lies between a putative nonstructural gene of unknown function and the gene encoding the glycoprotein and is bordered on either side by the same GG intergenic dinucleotide that separates other genes in the SYNV genome. The M1 mRNA (scRNA 6) consists of a 71-nt untranslated region at the 5' terminus followed by an 858-nt open reading frame (ORF) capable of encoding a protein with a calculated molecular weight of 31,779. The amino acid sequence deduced from this ORF is not highly homologous to those of other rhabdovirus matrix proteins, but has some localized regions of similarity. The UGA codon that terminates the M1 ORF is followed by a 3' untranslated region of 142 nt. The viral RNA (minus-sense) sequence corresponding to the extreme 3' end of the mRNA contains a 9-nt tract (3'-AUUGUUUUU-5') that is identical to the sequences at the termini of other SYNV genes.