Characterization of the early region 3 and fiber genes of Ad7

The nucleotide sequence and the predicted amino acid sequences for open reading frames (ORFs) encoded in the Bam-Hl D fragment of Ad7 (Gomen) DNA show an organization and conservation of potential polypeptides between Ad3 and Ad7. Five ORFs encoded within early region 3 (E3) and shared with the corresponding region of Ad3 can be identified; four of these potential coding regions also share homology to ORFs found in E3 of Ad2 and Ad5. The fiber gene of late region 5 (L5) is also apparent within this region; S1 mapping experiments show that the 5' and 3' boundaries of the main exon in fiber mRNA lie at each end of the proposed fiber ORF. The predicted amino acid sequence for Ad7 fiber shares 60% amino acid homology to Ad3 fiber, but only 20% to Ad2 fiber. Surprisingly, there are three regions of partial amino acid homology near the N- and C-termini of the predicted fiber gene sequences from Ad2, Ad3, Ad5, and Ad7; these conserved regions may be important for interaction with penton base, for proper folding of the shaft of the molecule, or for recognition of the cellular receptor to which adenovirus attaches during infection.     

Genetic Organization and Sequence Analysis of pVIII,Fiber and Early Region 4 of Bovine Adenovirus Type 7

The DNA sequence of 8810 nucleotides at the right end of bovine adenovirus type 7 (BAV7) genome was determined and compared with similar regions of other adenoviruses. This genomic region of BAV7 consists of sequences encoding partial 33K, pVIII, fiber, putative early region 4 (E4) proteins and other unassigned proteins. However, BAV7 E3 region is not present in the expected location between pVIII and fiber as BAV7 intergenic region between pVIII and fiber genes is only 183 nucleotides. The predicted pVIII and fiber demonstrates highest homology to corresponding proteins of ovine adenovirus 287 (OAV287), bovine adenovirus-4 (BAV4) and egg drop syndrome virus (EDSV). The E4 region encodes three ORFs, which shows significant homology only to corresponding proteins encoded by E4 region of OAV287 and BAV4. Sequence comparisons, phylogenetic analysis and overall genome organization in this region of BAV7 provide further evidence for the inclusion of BAV7 together with OAV287, BAV4, and EDSV in the proposed genus Atadenovirus.     

Analysis of early region 4 of porcine adenovirus type 3

The early region 4 (E4) of porcine adenovirus (PAdV)-3, located at the right-hand end of the genome is transcribed in a leftward direction and has the potential to encode seven (p1-p7) open reading frames (ORFs). To determine the role of each protein in viral replication, we constructed full-length PAdV-3 genomic clones containing deletions of individual E4 ORF or combined deletions of the neighboring ORFs. Transfection of swine testicular (ST) cells with individual E4 mutant plasmid DNAs generated PAdV-3 E4 mutant viruses except with plasmids containing a deletion of ORF p3, ORF p2+ p3 or ORF p3+ p4. Each of the mutants was further analyzed for growth kinetics, and early/late protein synthesis. Mutant viruses carrying deletions in ORF p1, ORF p2 or ORF p4 showed growth characteristics similar to that of wild-type PAdV-3. Early/late protein synthesis was also indistinguishable from that of wild-type PAdV-3. However, mutant viruses carrying deletions in ORF p5, ORF p6 or ORF p7 showed a modest effect in their ability to grow in porcine cells and express early proteins. These results suggest that the E4 ORF p3 (showing low homology with non-essential human adenovirus (HAdV)-9-E4 ORF1 encoded proteins) is essential for the replication of PAdV-3 in vitro. In contrast, the E4 ORF p7 (showing homology to essential HAdV-2 34 kDa protein) is not essential for replication of PAdV-3 in vitro. Moreover, successful deletion of 1.957 kb fragment in E4 region increased the available capacity of replication-competent PAdV-3 (E3 + E4 deleted) to approximately 4.3 kb and that of replication-defective PAdV-3 (E1 + E3 + E4 deleted) to approximately 7 kb. This is extremely useful for the construction of PAdV-3 vectors that express multiple genes and/or regulatory elements for gene therapy and vaccination.     

Nucleotide sequence of both genomic RNAs of a North American tobacco rattle virus isolate

Summary.  The complete sequence of a North American tobacco rattle virus (TRV) isolate, ‘Oregon yellow’ (ORY), was determined from cDNA and RT-PCR clones derived from the two genomic RNAs of this isolate. The RNA-1 is 6790 bases and RNA-2 is 3261 bases. The sequence of TRV-ORY RNA-1 was similar to RNA-1 of TRV isolate SYM, and differs in 48 nucleotides. TRV-ORY RNA-1 was one base shorter than -SYM, and had 47 base substitutions resulting in 12 amino acid substitutions of which 4 were conservative. The RNA-2 of TRV-ORY was distinct from RNA-2 of other characterized TRV isolates and contained three open reading frames (ORFs) that could potentially code for proteins of MW 22.4 kDa, 37.6 kDa and 17.9 kDa. Based on the homology of the predicted amino acid sequence with those of other tobraviruses, ORF1 of RNA-2 encodes the coat protein (CP). The protein sequence of ORF2 had regions of limited similarity with those of ORF2 of two other TRV isolates and pea early browning tobravirus. The ORF3 was unique to TRV-ORY. Phylogenetic analysis of tobravirus CPs indicated that TRV-ORY was most closely related to pepper ringspot tobravirus and TRV-TCM. The relationship of tobravirus CPs to other rod-shaped tubular plant viruses vis also discussed. Accepted March 21, 1998     

Complete nucleotide sequence of Sesbania mosaic virus: a new virus species of the genus Sobemovirus

Summary.  The complete nucleotide sequence of the Sesbania mosaic virus (SeMV) genomic RNA was determined by sequencing overlapping cDNA clones. The SeMV genome is 4149 nucleotides in length and encodes four potential overlapping open reading frames (ORFs). Comparison of the nucleotide sequence and the deduced amino acid sequence of the four ORFs of SeMV with that of other sobemoviruses revealed that SeMV was closest to southern bean mosaic virus Arkansas isolate (SBMV-Ark, 73% identity). The 5′ non-coding regions of SeMV, SBMV and southern cowpea mosaic virus (SCPMV) are nearly identical. However ORF1 of SeMV which encodes for a putative movement protein of M_r 18370 has only 34% identity with SBMV-Ark. ORF 2 encodes a polyprotein containing the serine protease, genome linked viral protein (VPg) and RNA dependent RNA polymerase domains and shows 78% identity with SBMV-Ark. The N-terminal amino acid sequence of VPg was found to be TLPPELSIIEIP, which mapped to the region 326–337 of ORF2 product and the cleavage site between the protease domain and VPg was identified to be E³²⁵-T³²⁶. The cleavage site between VPg and RNA dependent RNA polymerase was predicted to be E⁴⁴⁵-T⁴⁴⁶ based on the amino acid sequence analysis of the polyprotein from different sobemoviruses. ORF3 is nested within ORF2 in a − 1 reading frame. The potential ribosomal frame shift signal and the downstream stem-loop structure found in other sobemoviruses are also conserved in SeMV RNA sequence, indicating that ORF3 might be expressed via − 1 frame shifting mechanism. ORF4 encodes the coat protein of SeMV, which shows 76 and 66% identity with SBMV-Ark and SCPMV, respectively. Thus the comparison of the non-coding regions and the ORFs of SeMV with other sobemoviruses clearly revealed that it is not a strain of SBMV. Phylogenetic analysis of six different sobemoviruses, including SeMV, suggests that recombination event is not frequent in this group and that SeMV is a distinct member of the genus sobemovirus. The analysis also shows sobemoviruses infecting monocotyledons and dicotyledons fall into two distinct clusters. Received April 20, 2000 Accepted August 28, 2000     

Recombinant bovine adenovirus type 3 expressing bovine viral diarrhea virus glycoprotein E2 induces an immune response in cotton rats

Recombinant bovine adenovirus is being developed as a live vector for animal vaccination and for human gene therapy. In this study, two replication-competent bovine adenovirus 3 (BAV-3) recombinants (BAV331 and BAV338) expressing bovine viral diarrhea virus (BVDV) glycoprotein E2 in the early region 3 (E3) of BAV-3 were constructed. Recombinant BAV331 contains chemically synthesized E2 gene (nucleotides modified to remove internal cryptic splice sites) under the control of BAV-3 E3/major late promoter (MLP), while recombinant BAV338 contains original E2 gene under the control of human cytomegalovirus immediate early promoter. Since E2, a class I membrane glycoprotein, does not contain its own signal peptide sequence at the 5' end, the bovine herpesvirus 1 (BHV-1) glycoprotein D signal sequence was fused in frame to the E2 open reading frame (ORF) for proper processing of the E2 glycoprotein in both the recombinant viruses. Recombinant E2 protein expressed by BAV331 and BAV338 recombinant viruses was recognized by E2-specific monoclonal antibodies as a 53-kDa protein, which also formed dimer with an apparent molecular weight of 94 kDa. Insertion of an E2-expression cassette in the E3 region did not effect the replication of recombinant BAV-3s. Intranasal immunization of cotton rats with these recombinant viruses generated E2-specific IgA and IgG responses at the mucosal surfaces and in the serum. In summary, these results show that the pestivirus glycoprotein can be expressed efficiently by BAV-3. In addition, mucosal immunization with replication-competent recombinant bovine adenovirus 3 can induce a specific immune response against the expressed antigen.     

Molecular cloning and complete nucleotide sequence of galinsoga mosaic virus genomic RNA

Summary.  The complete genomic sequence of galinsoga mosaic virus (GaMV) was determined. The genome consists of 3 803 nucleotides and has five open reading frames (ORFs). The 5′ ORF (ORF 1) encodes a protein with predicted molecular mass of 23 kDa and readthrough of its amber stop codon probably yields a 82 kDa protein (ORF 2). ORFs 3 and 4 encode two polypeptides with molecular masses of 8 and 7 kDa, respectively. ORF 5 encodes the 36 kDa capsid protein. Amino acid sequence comparisons revealed that the nonstructural proteins encoded by ORFs 1, 3, and 4 were more similar to the corresponding gene products of tobacco necrosis virus, strain A, than to those of carmoviruses. Conversely, the coat protein was more similar to that of tombusviruses. The readthrough region of the viral replicase (ORF 2) had high sequence homology with that of carmo-, tombus-, and necroviruses. Computer analysis of the protein encoded by ORF 1 as well as of the corresponding product of turnip crinkle (TCV) and melon necrotic spot (MNSV) carmoviruses revealed the presence of a sequence with local hydrophobicity and hydrophobic moment characteristic of mitochondrial targeting sequence which may explain the origin of the carmovirus-induced multivesicular bodies from mitochondria. Accepted August 25, 1997 Received June 18, 1997     

7型腺病毒疫苗株87mu-97.4mu片段核苷酸序列分析

目的获得７型腺病毒（Ａｄ７）疫苗株８７ｍｕ－９７．４ｍｕ核苷酸序列，分析该区段的基因结构和功能。方法应用Ｓａｎｇｅｒ双脱氧法进行核苷酸序列分析。结果Ａｄ７疫苗株８７ｍｕ－９７．４ｍｕ全长３６９８个核苷酸，推测编码纤维蛋白（３２５个氨基酸）和Ｅ３区１５．４ｋＤ蛋白，Ｅ４区５个蛋白（ＯＲＦ１４．２，ＯＲＦ１５．７，ＯＲＦ８．１，ＯＲＦ４２．８和ＯＲＦ１０．３）。结论这一结果为阐明Ａｄ７的基因结构与功能及利用该病毒做为基因工程疫苗载体打下一定的基础     

Coding properties of the S and the M genome segments of Sapporo rat virus: comparison to other causative agents of hemorrhagic fever with renal syndrome

Three serologically distinct groups of hantaviruses have been associated with severe, moderate, and mild forms of hemorrhagic fever with renal syndrome (HFRS). To gain a better understanding of the genetic variation among these viruses, we cloned and sequenced the M and the S genome segments of Sapporo rat virus, an etiologic agent of moderate HFRS, and compared the predicted gene products to those of Hantaan virus, and the H?lln?s strain of Puumala virus, which are etiologic agents of severe and mild HFRS, respectively. The SR-11 S segment consisted of 1769 nucleotides and had an open reading frame (ORF) in the virus-complementary sense RNA with a coding capacity of 429 amino acids. Deduced amino acids from the SR-11 S segment ORF displayed 83% homology with those of Hantaan nucleocapsid (N) protein. Comparison of the S segment ORFs of all three viruses revealed 58% homology. No evidence for additional nonstructural protein(s) encoded by the SR-11 S segment was obtained. The SR-11 M segment consisted of 3651 nucleotides and had an ORF in the virus-complementary sense RNA with a coding capacity of 1134 amino acids. Amino acid sequences predicted from the SR-11 M segment ORF were 75% homologous with those encoding Hantaan G1 and G2 envelope glycoproteins. Comparison of the deduced amino acid sequences of the M segment ORFs of SR-11, Hantaan, and H?lln?s viruses revealed a 43% homology for amino acids constituting the G1 proteins and a 55% homology for amino acids constituting the G2 proteins of the three viruses. The envelope proteins of SR-11 virus were localized within the M segment ORF by amino-terminal sequence analysis of purified G1 and G2. G1 initiated at amino acid 17 and G2 at amino acid 647 within the ORF. Five potential asparagine-linked glycosylation sites were identified in the SR-11 G1 coding sequences, four of which were conserved between Hantaan and SR-11 viruses and three of which were conserved among all three viruses. One potential glycosylation site was identified in the SR-11 G2 coding sequences and was conserved among Hantaan, SR-11 and H?lln?s viruses. Cysteine residues were highly conserved within the M segment ORFs of all three viruses, suggesting a similar structure and function of the G1 and G2 proteins.     

Comparison of the sequence of the secretory glycoprotein A (gA) gene in Md5 and BC-1 strains of Marek's disease virus type 1

DNA fragments containing the secretory glycoprotein A (gA) gene of Marek's disease virus type 1 (MDV 1) were cloned from the DNA libraries of very virulent Md5 and virulent BC-1 strains and sequenced. Two open reading frames (ORF1 and ORF2) were identified for both strains. The ORF1 has the potential to code for a protein of 501 amino acids with a molecular weight of 56 kD that contains strong hydrophobic regions in both the amino and carboxyl termini, and nine potential N-linked glycosylation sites, while the ORF2 is capable of coding for a 24-kD protein. These results indicate that the ORF1 codes for the unprocessed form of gA. Between the Md5 and BC-1 strains, only two sequence mismatches exist in the DNA fragment. More differences appear to exist in the gA sequence of the MDV 1 GA strain (12), which lacks a strong hydrophobic anchor sequence. Similarities between the predicted amino acid sequences of the MDV 1 gA and the proteins of the other herpesviruses such as herpes simplex type I gC, pseudorabies virus gIII, and varicella zoster virus gpV were noted.     

Open reading frames encoding a protein kinase, homolog of glycoprotein gX of pseudorabies virus, and a novel glycoprotein map within the unique short segment of equine herpesvirus type 1.

DNA sequence analysis of the unique short (Us) segment of the genome of equine herpesvirus type 1 Kentucky A strain (EHV-1) by our laboratory and strains Kentucky D and AB1 by other workers identifies a total of nine open reading frames (ORF). In this report, we present the DNA sequence of three of these newly identified ORFs, designated EUS 2, EUS 3, and EUS 4. The EUS 2 ORF is 1146 nucleotides (nt) in length and encodes a potential protein of 382 amino acids. Cis-regulatory sequences upstream of the putative ATG start codon include a G/C box 112 nt upstream and two potential TATA-like elements located between 15 and 90 nt before the ATG. The EUS 2 translation product exhibits significant homology to Ser/Thr protein kinases encoded within the Us segments of other herpesviruses, such as herpes simplex virus (26% homology) and pseudorabies virus (PRV), (45% homology), and possesses sequence domains conserved in protein kinases of cellular and viral origin. The EUS 3 ORF begins 127 nt downstream from the EUS 2 stop codon and ends at a stop codon 1119 nt further downstream. A single TATA-like element maps 61 nt upstream of the ORF. This ORF encodes a potential protein of 373 amino acids and is a homolog of glycoprotein gX of PRV, as judged by overall homology of amino acid residues, cysteine displacement, and presence of potential glycosylation sites and signal sequence. Interestingly, the EUS 4 ORF encodes a potential membrane glycoprotein that does not exhibit homology to any reported protein sequence. The EUS 4 ORF encodes a 383 amino acid polypeptide with a sequence indicative of a signal sequence at its amino terminal end, glycosylation sites for N-linked oligosaccharides, and a transmembrane domain near its carboxyl terminus. Several cis-acting regulatory sequences lie upstream of this ORF. These findings support the observation that the short region of alphaherpesviruses show considerable variation in their genetic content and gene organization.     

Nucleotide sequence and genome organisation of cherry mottle leaf virus and its relationship to members of the Trichovirus genus

Summary.  The nucleotide sequence of cherry mottle leaf virus (CMLV) was determined and compared to sequences of a number of plant viruses including the type member of the Trichovirus genus (apple chlorotic leafspot virus, ACLSV), and members of the Vitivirus genus including grapevine virus B, (GVB). The CMLV genome was determined to consist of 8003 nt excluding the poly(A) tail at the 3′ end of the genome. The overall A+U content of CMLV genomic RNA was 59. 1%, which is similar to ACLSV, but significantly different from GVB. Four putative open reading frames were identified (ORFs 1, 2, 3, and 4) encoding proteins of M_r 215. 8 kDa, 47 kDa, 21.6 kDa, and 15. 3 kDa, respectively. This differs from ACLSV which has 3 ORFS, and GVB which has 5 ORFs. Protein database searches showed no matches of CMLV ORF4 with ACLSV sequences, but found similarities between ORF4 of CMLV and ORF5 of GVB, suggesting that this may be a nucleic acid-binding protein. CMLV and ACLSV formed a common virus clade in phylogenetic analysis of the coat protein amino acid sequence and except for CMLV’s ORF4, these viruses show high levels of similarity throughout the genome. CMLV appears to be a member of the Trichovirus genus. Accepted November 19, 1999/Received August 12, 1999     

Picobirnaviruses encode a protein with repeats of the ExxRxNxxxE motif

Picobirnaviruses possess a bisegmented double-stranded RNA genome. While the segment 2 encodes the RNA-dependent RNA polymerase, the segment 1 displays two open reading frames (ORFs). ORF2 was recently shown to code the capsid precursor and ORF1 product has not been characterized. In this study, we show that the three ORF1 sequences available in databases and representing three phylogenetically distant picobirnaviruses (two from human and one from rabbit hosts) encode proteins of various sizes (106-224 residues and without proline and cysteine) harbouring a particular sequence motif (ExxRxNxxxE) repeated four to ten times, depending on the virus species. Several algorithms predicted the three proteins to be mainly unfolded in the domains containing the repeats. The glycine-rich 25-40 amino acid long C-terminal domains containing hydrophobic residues with a periodicity of 3-4 residues are predicted structurally different of the upstream domains containing the motif repetitions. The ExxRxNxxxE sequence was not previously identified as a short linear motif in eukaryotic and prokaryotic proteins. Its function remains elusive.     

Identification of a Gene Cluster within the Genome of Chilo Iridescent Virus Encoding Enzymes Involved in Viral DNA Replication and Processing

The nucleotide sequence of the genome of Chilo iridescent virus (CIV) between the genome coordinates 0.974 and 0.101 comprising 27,079 bp was determined. Computer-assisted analysis of the DNA sequence of this particular region of the CIV genome revealed the presence of 42 potential open reading frames (ORFs) with coding capacities for polypeptides ranging from 50 to 1,273 amino acid residues. The analysis of the amino acid sequences deduced from the individual ORFs resulted in the identification of 10 potential viral genes that show significant homology to functionally characterized proteins of other species. A cluster of five viral genes that encode enzymes involved in the viral DNA replication was identified including the DNA topoisomerase II (A039L, 1,132 amino acids (aa)), the DNA polymerase (ORF A031L, 1,273 aa), a helicase (ORF A027L, 530 aa), a nucleoside triphosphatase I (ORF A025L, 1,171 aa), and an exonuclease II (ORF A019L, 624 aa), all ORFs possessing the same genomic orientation. The DNA polymerase of CIV showed the highest homology (24.8% identity) to the DNA polymerase of lymphocystis disease virus lymphocystis disease virus 1 (LCDV-1), a member of the family Iridoviridae, indicating the close relatedness of the two viruses. In addition, four putative gene products were found to be significantly homologous to previously identified hypothetical proteins of CIV.     

Nucleotide sequence of a gene essential for viral DNA replication in the baculovirus Autographa californica nuclear polyhedrosis virus

The nucleotide sequence of the 60.1- to 65.5-m.u. region of Autographa californica nuclear polyhedrosis virus (AcMNPV) was determined. Seven large open reading frames were identified. Two open reading frames potentially encoding gene products of 143 and 38 kDa were found in the counterclockwise direction upstream of the p6.9 gene. Four additional open reading frames were found in the opposite direction. Analysis of the predicted amino acid sequence of the 143-kDa gene revealed a potential leucine zipper motif, a putative nuclear localization signal, and seven amino acid motifs previously identified in a number of proteins involved in NTP binding and DNA/RNA unwinding. The mutation in a DNA replication defective temperature-sensitive mutant was fine mapped to the carboxy terminus of the ORF1(p143) gene. Sequence analysis of the mutation site identified a single base change of a guanine to an adenine, resulting in the substitution of a methionine for valine. This mutation resides seven amino acids downstream of the putative NTP-binding motif of the ORF1(p143) gene product and results in a DNA negative mutant. Together these data strongly suggest that the ORF1(p143) gene product is a baculovirus helicase.     

Complete cDNA sequence of a South American isolate of potato virus X

The complete cDNA sequence corresponding to the genomic RNA of a South American strain of potato virus X (PVXc) is reported. The sequence (6432 nucleotides) contains five open reading frames coding for polypeptides with molecular weights of 165.3, 24.3, 12.3, 7.6 and 25.0 and displays an overall homology of 77.4% with those previously reported for two European isolates. Comparison of amino acid sequences shows an average homology of 87%. Two major domains of variability, located between amino acids 476-615 of ORF 1 and 64-100 of ORF 5, are identified. Sequence similarities between RNA stretches lying upstream of ORFs 2, 4 and 5, and at the 3'-non coding regions of PVX and other plus-strand RNA viruses are described.     

Genomic location and nucleotide sequence of a porcine adenovirus penton base gene

Summary The putative penton base gene of a porcine adenovirus serotype 3 (PAV3) has been identified, cloned and sequenced. The genomic location of the PAV3 penton base was deduced by probing a Southern blot with a polymerase chain reaction generated product containing the human adenovirus type 2 (HAV2) penton base gene. Sequencing revealed an open reading frame (ORF) of 1527 nucleotides coding for a polypeptide of 509 amino acids. However, cDNA analysis indicated an acceptor splice site one nucleotide upstream of the second ATG in the ORF. This produced an ORF of 1452 nucleotides coding for a polypeptide of 484 amino acids with a calculated molecular weight of 54.5 kDa. Comparison with the HAV2 penton base amino acid sequence revealed the putative PAV3 penton base homologue to be 87 amino acids shorter with an overall amino acid homology of approximately 65%. Comparison with the penton base proteins of other HAV types revealed a region between amino acid positions 283 and 379 with no similarity.GenBank Accession No. U24432.