貂肠炎病毒的核苷酸序列和基因组结构

本试验测定了已克隆的貂肠炎病毒(MEV)复制型(RF)DNA的核苷酸序列,确定MEV基因组全长约为5064个核苷酸(nucleotides,nt),推测了3'端和5'端结构,在5'端非编码区有3个51 nt的重复。MEV基因组序列与犬细小病毒(CPV)、猫细小病毒(FPV)有很高的同源性,结构基因区的同源性分别达99.1%和99.9%,但在5'端非编码区有较大差异。MEV基因组结构与CPV和FPV基本一致,有两个大的开放阅读框架,分别编码688和722个氨基酸。在map unit(m.u.)3.7和m.u.39处有两个启动子,在m.u.97处有poly A位点。NS2、VP1和VP2的mRNA都发生剪接。     

Nucleotide sequence and corresponding amino acid sequence of the gene for the major antigen of foot and mouth disease virus

A segment of 1160 nucleotides of the FMDV genome has been sequenced using three overlapping fragments of cloned cDNA from FMDV strain O1K. This sequence contains the coding sequence for the viral capsid protein VP1 as shown by its homology to known and newly determined amino acid sequences from this man antigenic polypeptide of the FMDV virion. The structural gene for VP1 comprises 639 nucleotides which specify a sequence of 213 amino acids for the VP1 protein. The coding sequence is not flanked by start and stop codons which is consistent with the mode of biosynthesis of VP1 by post-translational processing of a polyprotein precursor.     

Evidence for genetic relationship between RNA and DNA viruses from the sequence homology of a putative polymerase gene of bluetongue virus with that of vaccinia virus: conservation of RNA polymerase genes from diverse species.

The nucleotide sequence of segment 1 of the double stranded RNA genome of bluetongue virus serotype 10 (BTV-10), encoding the largest viral core protein, VP1, has been determined. Linear sequence analysis of the predicted amino acid sequence of the 149-K Da protein, a putative component of the viral RNA-directed RNA polymerase, revealed extensive homology with the vaccinia virus 147K Da DNA-directed RNA polymerase subunit. Similar homologies were detected between the VP1 polypeptide and the beta chain subunit of Escherichia coli and common tobacco chloroplast RNA polymerases, yeast RNA polymerase II and III and fruit fly polymerase II.     

McDonough feline sarcoma virus: characterization of the molecularly cloned provirus and its feline oncogene (v-fms).

The genetic structure of the McDonough strain of feline sarcoma virus (SM-FeSV) was deduced by analysis of molecularly cloned, transforming proviral DNA. The 8.2-kilobase pair SM-FeSV provirus is longer than those of other feline sarcoma viruses and contains a transforming gene (v-fms) flanked by sequences derived from feline leukemia virus. The order of genes with respect to viral RNA is 5'-gag-fms-env-3', in which the entire feline leukemia virus env gene and an almost complete gag sequence are represented. Transfection of NIH/3T3 cells with cloned SM-FeSV proviral DNA induced foci of morphologically transformed cells which expressed SM-FeSV gene products and contained rescuable sarcoma viral genomes. Cells transformed by viral infection or after transfection with cloned proviral DNA expressed the polyprotein (P170gag-fms) characteristic of the SM-FeSV strain. Two proteolytic cleavage products (P120fms and pp55gag) were also found in immunoprecipitates from metabolically labeled, transformed cells. An additional polypeptide, detected at comparatively low levels in SM-FeSV transformants, was indistinguishable in size and antigenicity from the envelope precursor (gPr85env) of feline leukemia virus. The complexity of the v-fms gene (3.1 +/- 0.3 kilobase pairs) is approximately twofold greater than the viral oncogene sequences (v-fes) of Snyder-Theilen and Gardner-Arnstein FeSV. By heteroduplex, restriction enzyme, and nucleic acid hybridization analyses, v-fms and v-fes sequences showed no detectable homology to one another. Radiolabeled DNA fragments representing portions of the two viral oncogenes hybridized to different EcoRI and HindIII fragments of normal cat cellular DNA. Cellular sequences related to v-fms (designated c-fms) were much more complex than c-fes and were distributed segmentally over more than 40 kilobase pairs in cat DNA. Comparative structural studies of the molecularly cloned proviruses of Synder-Theilen, Gardner-Arnstein, and SM-FeSV showed that a region of the feline-leukemia virus genome derived from the pol-env junction is represented adjacent to v-onc sequences in each FeSV strain and may have provided sequences preferred for recombination with cellular genes.     

The structure of parvoviruses

Capsids of autonomous parvoviruses are assembled from two proteins, VP1 and VP2, which overlap in sequence, with VP1 having additional amino-terminal residues. Empty capsids can be assembled from VP2 alone. Post-translational cleavage of assembled particles can modify some of the proteins by truncation of a few of the amino-terminal residues of VP2 to generate VP3 in full virions. The structures of canine parvovirus (CPV) and feline panleukopenia virus (FPV) have been solved to better than 3·5 Å resolution, while the structure of human parvovirus, B19, has been determined to 8 Å resolution only. In each case the T=1 icosahedron is made up of 60 copies of a mixture of VP1, VP2 and VP3, where each subunit has a structural motif common to many other RNA and DNA viruses, consisting of an eight-stranded anti-parallel β-barrel. The surface of the capsid is made up primarily of large elaborate loops which connect the β-strands that make up the barrel. Variation in the amino acid sequence and topology of these loops account for differing biological properties.     

Polyoma Virus DNA: Complete Nucleotide Sequence of the Gene Which Codes for Polyoma Virus Capsid Protein VP1 and Overlaps the VP2/VP3 Genes

The nucleotide sequence of part of the late region of the polyoma virus genome was determined. It contains coding information for the major capsid protein VP1 and the C-terminal region of the minor proteins VP2 and VP3. In the sequence with the same polarity as late mRNA's, all coding frames are blocked by termination codons in a region around 48 units on the physical map. This is the region where the N-terminus of VP1 and the C-termini of VP2 and VP3 have been located (T. Hunter and W. Gibson, J. Virol. 28:240-253, 1978; S. G. Siddell and A. E. Smith, J. Virol. 27:427-431, 1978; Smith et al., Cell 9:481-487, 1976). There are two long uninterrupted coding frames in the late region of polyoma virus DNA. One lies at the 5' end of the sequence and contains potential coding sequences for VP2 and VP3. The other contains 383 consecutive sense codons starting with the ATG at nucleotide position 1,218, extends from 47.5 to 25.8 units counterclockwise on the physical map, and is located where the VP1 gene has been mapped. The VP1 gene overlaps the genes for proteins VP2/VP3 by 32 nucleotides and uses a different coding frame. From the DNA sequence, the amino acid sequence of VP1 was predicted. The proposed VP1 sequence is in good agreement with other data, namely, with the partial N-terminal amino acid sequence and the total amino acid composition. The VP1 coding frame terminates with a TAA codon at 25.8 map units. This is followed by an AATAAA sequence, which may act as a processing signal for the viral late mRNA's. When both nucleotide and amino acid sequences are compared with their counterparts in the related simian virus 40, extensive homologies are found over the entire region of the two viral genomes. Maximum homology appears to occur in those regions which code for the C-termini of the VP1 proteins. The overlap region of VP1 with VP2/VP3 of polyoma virus is shorter by 90 nucleotides than is that of simian virus 40 and shows very limited homology with the simian virus 40 sequence. This leads to the suggestion that the overlap segments of both viruses have been freed from stringency imposed on drifting during evolution and that proteins VP2 and VP3 of polyoma virus may have been truncated by the appearance of a termination codon within the sequence.     

Mapping of sequences required for mouse neurovirulence of poliovirus type 2 Lansing.

Intracerebral inoculation of mice with poliovirus type 2 Lansing induces a fatal paralysis, while most other poliovirus strains are unable to cause disease in the mouse. To determine the molecular basis for Lansing virus neurovirulence, we determined the complete nucleotide sequence of the Lansing viral genome from cloned cDNA. The deduced amino acid sequence was compared with that of two mouse-avirulent strains. There are 83 amino acid differences between the Lansing and Sabin type 2 strain and 179 differences between the Lansing and Mahoney type 1 strain scattered throughout the genome. To further localize Lansing sequences important for mouse neurovirulence, four intertypic recombinants were isolated by exchanging DNA restriction fragments between the Lansing 2 and Mahoney 1 infectious poliovirus cDNA clones. Plasmids were transfected into HeLa cells, and infectious recombinant viruses were recovered. All four recombinant viruses, which contained the Lansing capsid region and different amounts of the Mahoney genome, were neurovirulent for 18- to 21-day-old Swiss-Webster mice by the intracerebral route. The genome of neurovirulent recombinant PRV5.1 contained only nucleotides 631 to 3413 from Lansing, encoding primarily the viral capsid proteins. Therefore, the ability of Lansing virus to cause paralysis in mice is due to the viral capsid. The Lansing capsid sequence differs from that of the mouse avirulent Sabin 2 strain at 32 of 879 amino acid positions: 1 in VP4, 5 in VP2, 4 in VP3, and 22 in VP1.     

Fine structure of epithelial cells of Lieberkühn's crypts in feline panleukopenia.

Electron microscopic observation was carried out on epithelial cells of Lieberkühn's crypts of cats naturally affected with feline panleukopenia. The most important change was the replication of feline panleukopenia. The most important change was the replication of feline panleukopenia virus in the nucleus with associated alterations in the lining epithelial cells of the crypts. In these cells in the early stage of infection, virus particles 20 nm in average diameter were found either singly or in small regularly arrayed clusters everywhere in the markedly swollen nucleus. In the course of infection, the nucleus of infected cells became rather atrophic with a marked margination of chromatin granules. Its major portion was occupied with masses of fine fibrillar substance. It was a "viral matrix area" in which appeared a large compact aggregate of virus particles showing a crystalline array. At the same time, the outer membrane of the nuclear envelope partially extended and disrupted. Membranous elements related to it in the cytoplasm were regularly distributed almost always with particles indistinguishable from the virus particles in the nucleus. From these results it was suggested that the major portion of the infected nucleus, or the site of viral replication, might correspond to the amphophilic intranuclear inclusion body revealed by light microscopy.     

Canine parvovirus host range is determined by the specific conformation of an additional region of the capsid.

We analyzed a region of the capsid of canine parvovirus (CPV) which determines the ability of the virus to infect canine cells. This region is distinct from those previously shown to determine the canine host range differences between CPV and feline panleukopenia virus. It lies on a ridge of the threefold spike of the capsid and is comprised of five interacting loops from three capsid protein monomers. We analyzed 12 mutants of CPV which contained amino acid changes in two adjacent loops exposed on the surface of this region. Nine mutants infected and grew in feline cells but were restricted in replication in one or the other of two canine cell lines tested. Three other mutants whose genomes contain mutations which affect one probable interchain bond were nonviable and could not be propagated in either canine or feline cells, although the VP1 and VP2 proteins from those mutants produced empty capsids when expressed from a plasmid vector. Although wild-type and mutant capsids bound to canine and feline cells in similar amounts, infection or viral DNA replication was greatly reduced after inoculation of canine cells with most of the mutants. The viral genomes of two host range-restricted mutants and two nonviable mutants replicated to wild-type levels in both feline and canine cells upon transfection with plasmid clones. The capsids of wild-type CPV and two mutants were similar in susceptibility to heat inactivation, but one of those mutants and one other were more stable against urea denaturation. Most mutations in this structural region altered the ability of monoclonal antibodies to recognize epitopes within a major neutralizing antigenic site, and that site could be subdivided into a number of distinct epitopes. These results argue that a specific structure of this region is required for CPV to retain its canine host range.     

Feline panleukopenia virus replicates in cells in which cellular DNA synthesis is blocked.

The components of the cell cycle for a feline embryo cell line were defined. Thymidine (6mM)-supplemented medium reversibly arrested cells 1 h into the S phase of the cell cycle and was used in a double blocking procedure to synchronize cells to the early S phase. The kinetics of feline panleukopenia virus replication in synchronized cells was studied by using (i) inclusion body formation, (ii) a plaque assay for cell-associated and cell-free virus under one-step growth conditions, (iii) an enzyme immunoassay for viral protein, (iv) electron microscopy of infected cells, and (v) the detection and identification of viral replicative form DNA by restriction endonuclease analysis. Parallel studies by each of these procedures of the replication of feline panleukopenia virus in cells in which a 6 mM thymidine block was maintained indicated that parvovirus replicated with essentially similar kinetics in both unblocked, synchronized cells and in cells in which the block was maintained. Accordingly, a 6 mM thymidine-supplemented medium, although it effectively blocks cellular DNA synthesis, does not block the replication of parvovirus.     

Molecular cloning of a novel isolate of feline immunodeficiency virus biologically and genetically different from the original U.S. isolate.

The Japanese isolate (TM1 strain) of feline immunodeficiency virus (FIV) which replicates in a feline CD4 (fCD4)-positive lymphoblastoid cell line (MYA-1 cells) was molecularly cloned from extrachromosomal closed circular DNA. The restriction map of the clone, termed pFTM 191 complete genome (CG), showed a considerable difference from that of the U.S. isolate (Petaluma strain) of FIV. The sequence homology in the long terminal repeat between the TM1 and Petaluma strain was 82%. The pFTM 191 CG was biologically active after transfection into Crandell feline kidney cells which were permissive for replication of FIV Petaluma. However, the progeny virions could not reinfect fCD4-negative Crandell feline kidney cells but could infect fCD4-positive MYA-1 cells. When a specific-pathogen-free cat was inoculated with the virus derived from the pFTM 191 CG, the cat seroconverted within 8 weeks postinoculation and FIV was reisolated at 4, 8, and 20 weeks postinoculation. These results indicate the infectivity of the pFTM 191 CG in vivo.     

Evaluation of tri-combinant vaccine for feline herpesvirus, calicivirus and panleukopenia virus infections in Japanese native cats

Tri-combinant vaccine consisting of attenuated feline herpesvirus (FHV) and feline calicivirus (FCV) and inactivated feline panleukopenia virus (FPLV), were evaluated for safety and efficacy, using Japanese native cats and the viral strains isolated in Japan. Thirty-eight 9- to 12-week-old kittens were inoculated intramuscularly and subcutaneously with the vaccine. Consequently, no adverse reaction was found, and protective efficacy was confirmed by challenge tests with the virulent strains of each virus. Serum-neutralizing antibodies against FCV and FPLV were maintained for at least one year after vaccination, whereas antibody against FHV disappeared in two cases at 24 weeks after vaccination. Application of this vaccine seemed effective for control of feline viral disease in cats for experimental use.     

Structural Characteristics and Nucleotide Sequence Analysis of Genomic RNA from RD-114 Virus and Feline RNA Tumor Viruses

The results of molecular hybridization experiments have demonstrated that the RNA genome of RD-114 virus has extensive nucleotide sequence homology with the RNA genome of Crandell virus, an endogenous type C virus of cats, but only limited homology with the RNA genomes of feline sarcoma virus and feline leukemia virus. The genomic RNAs of RD-114 virus and Crandell virus also had identical sedimentation coefficients of 50S. A structural rearrangement of genomic RNA did not exist within released RD-114 virions, whereas a structural rearrangement of genomic RNA did occur within feline sarcoma virions and feline leukemia virions after release from virus-producing cells.     

Molecular cloning of Snyder-Theilen feline leukemia and sarcoma viruses: comparative studies of feline sarcoma virus with its natural helper virus and with Moloney murine sarcoma virus

Extrachromosomal DNA obtained from mink cells acutely infected with the Snyder-Theilen (ST) strain of feline sarcoma virus (feline leukemia virus) [FeSV(FeLV)] was fractionated electrophoretically, and samples enriched for FeLV and FeSV linear intermediates were digested with EcoRI and cloned in lambda phage. Hybrid phages were isolated containing either FeSV or FeLV DNA "inserts" and were characterized by restriction enzyme analysis, R-looping with purified 26 to 32S viral RNA, and heteroduplex formation. The recombinant phages (designated lambda FeSV and lambda FeLV) contain all of the genetic information represented in FeSV and FeLV RNA genomes but lack one extended terminally redundant sequence of 750 bases which appears once at each end of parental linear DNA intermediates. Restriction enzyme and heteroduplex analyses confirmed that sequences unique to FeSV (src sequences) are located at the center of the FeSV genome and are approximately 1.5 kilobase pairs in length. With respect to the 5'-3' orientation of genes in viral RNA, the order of genes in the FeSV genome is 5'-gag-src-env-c region-3'; only 0.9 kilobase pairs of gag and 0.6 kilobase pairs of env-derived FeLV sequences are represented in ST FeSV. Heteroduplex analyses between lambda FeSV or lambda FeLV DNA and Moloney murine sarcoma virus DNA (strain m1) were performed under conditions of reduced stringency to demonstrate limited regions of base pair homology. Two such regions were identified: the first occurs at the extreme 5' end of the leukemia and both sarcoma viral genomes, whereas the second corresponds to a 5' segment of leukemia virus "env" sequences conserved in both sarcoma viruses. The latter sequences are localized at the 3' end of FeSV src and at the 5' end of murine sarcoma virus src and could possibly correspond to regions of helper virus genomes that are required for retroviral transforming functions.     

Serological survey of the Iriomote cat (Felis iriomotensis) in Japan

The Iriomote cat (Felis iriomotensis) was first discovered on Iriomote Island in the Yaeyama Islands of Japan in 1965. Ten male and 11 female adult cats were captured during the 6 yr period from 1983 to 1988. These were examined for evidence of viral and mycoplasmal infections. Neither Mycoplasma sp. nor Ureaplasma sp. were detected in swab samples of oropharyngeal and urogenital regions. A foamy virus was isolated from the oropharyngeal swab of a female cat examined in 1988. Feline leukemia virus was not detected in any of the cats. All cats were negative for serum antibodies to feline panleukopenia virus, feline herpesvirus, feline immunodeficiency virus and rotavirus. Eleven of 19 (58%), 14 of 17 (82%) and 6 of 17 cats (35%) had serum antibodies against feline calicivirus, coronavirus and feline syncytium forming virus, respectively.     

A nonstructural protein of feline panleukopenia virus: expression in Escherichia coli and detection of multiple forms in infected cells.

Sequences coding for the nonstructural protein NS1 of the autonomous parvovirus feline panleukopenia virus were expressed in Escherichia coli as fusion proteins. The fusion proteins were specifically bound by antisera from canine parvovirus-infected dogs. Antisera against one of the fusion proteins bound to several proteins found only in feline panleukopenia virus-infected feline cells.