Ratification vote on taxonomic proposals to the International Committee on Taxonomy of Viruses (2015).

Changes to virus taxonomy approved and ratified by the International Committee on Taxonomy of Viruses in February 2015 are listed.

Reverse genetics of coronaviruses using vaccinia virus vectors.

In this article, we describe the reverse genetic system that is based on the use of vaccinia virus cloning vectors. This system represents a generic approach to coronavirus reverse genetics and was first described for the generation of recombinant human coronavirus 229E representing a group I coronavirus. Subsequently, the same approach has been used to generate recombinant avian infectious bronchitis coronavirus and, recently, recombinant mouse hepatitis virus, representing group III and group II coronaviruses, respectively. We describe how vaccinia virus-mediated homologous recombination can be used to introduce specific mutations into the coronavirus genomic cDNA during its propagation in vaccinia virus and how recombinant coronaviruses can be isolated. Finally, we describe how the coronavirus reverse genetic system has now been extended to the generation of coronavirus replicon RNAs.

Genomic targeting with an MBP-Cre fusion protein.

The Cre recombinase of bacteriophage P1 catalyses site-specific recombination between lox-recombination target sites both in prokaryotic and eukaryotic cells and has thus become a popular tool in genetic research. Stable, Cre-mediated integration of DNA sequences at pre-existing lox sites in the eukaryotic genome is facilitated when a Cre recombinase protein rather than a cre-expression plasmid is used to direct site-specific recombination (Baubonis and Sauer (1993) Nucleic Acids Res., 21, 2025-2029). We bacterially produced a Cre recombinase containing a nuclear localisation signal as a fusion protein with the E. coli maltose binding protein (MBP) and purified the protein by one step affinity chromatography. Subsequent cleavage with the protease factor Xa releases the Cre recombinase including the nuclear localisation signal from the maltose binding protein. Surprisingly, we found that the recombination activity of the uncleaved MBP-Cre fusion protein is virtually identical to that of the native Cre recombinase. This suggests that the MBP portion of the fusion protein behaves as a separate protein domain which does not interfere with Cre activity and can thus be used as an independent molecular tag. Additionally, the fusion protein is very resistant to proteolytic degradation and active over a wide range of temperatures. It efficiently catalyses excision and integration reactions in vitro and in eukaryotic cells. Finally, we could show that, by using MBP-Cre, it is possible to concomitantly excise a lox-flanked DNA sequence from a plasmid and integrate it into a pre-existing lox site in the genome in one transfection experiment. Vector backbone sequences which might have undesirable effects can thereby be excluded. The MBP-Cre fusion protein described here will be a useful tool not only for the catalysis of Cre-mediated recombination reactions in vitro and in vivo but also for the analysis of the mechanism of site-specific recombination.

Genomic targeting of a bicistronic DNA fragment by Cre-mediated site-specific recombination.

The Cre-recombinase of bacteriophage P1 catalyses site-specific recombination between DNA fragments containing loxP sites. Targeting of predefined genomic loci can be achieved by Cre-mediated linkage of a promoterless resistance marker gene to a floxed promoter pre-existing in the genome. In order to avoid the introduction of plasmid sequences into the host genome, we have constructed a series of plasmids in which the DNA segment to be integrated is flanked by two loxP sites. We show here that this floxed targeting fragment is reliably and effectively separated from the vector backbone and integrated into genomic loxP sites by Cre-mediated site-specific recombination in mammalian cells. We also demonstrate that by using this approach two convergent, promoterless coding regions can simultaneously be linked to two independent promoter elements at a pre-existing genomic loxP site. This methodology will be particularly useful for genomic targeting experiments in transgenic animals.

Insertion of a foreign gene into the beta-casein locus by Cre-mediated site-specific recombination.

The expression of foreign genes in transgenic animals is generally unpredictable as transgenes are integrated at random after pro-nuclear injection into fertilized oocytes. In many cases, transgene expression is inhibited by neighbouring chromatin structures or by the repeated nature of the multiple transgene copies present at the integration site. A strategy involving homologous and site-specific recombination has been devised by which single copies of a foreign gene can be inserted specifically into the locus of a highly expressed gene. As a first step, a loxP recombination target site is introduced by homologous recombination into a predetermined gene locus such that the loxP sequence is placed next to the promoter region and replaces the translational initiation signal. In a subsequent site-specific recombination reaction, a gene of interest can be integrated into the pre-existing loxP site. This biphasic recombination strategy was used to integrate a luciferase reporter gene into the locus of the murine beta-casein gene in embryonic stem cells.

Localization of major neutralizing epitopes on the S1 polypeptide of the murine coronavirus peplomer glycoprotein.

A recombinant baculovirus system has been used to express the amino terminal half of the murine coronavirus (JHMV) peplomer glycoprotein in insect cells. The expressed polypeptide is glycosylated and is recognized by a set of monoclonal antibodies (mAbs) specific for JHMV S protein. Three of these mAbs have a very high neutralizing activity for JHMV but not for other MHV strains. These results indicate that JHMV-specific, major neutralizing epitopes reside in the amino terminal S1 subunit of the peplomer glycoprotein.

Detection of human coronavirus 229E-specific antibodies using recombinant fusion proteins.

Human coronaviruses are known to be a common cause of respiratory infections in man. However, the diagnosis of human coronavirus infections is not carried out routinely, primarily because the isolation and propagation of these viruses in tissue culture is difficult and time consuming. The aim of this study was to evaluate the use of recombinant, bacterial expressed proteins in the serodiagnosis of coronavirus infections. Two proteins were examined: the human coronavirus 229E nucleocapsid protein (N), expressed as a fusion protein in the vector pUR and the coronavirus 229E surface glycoprotein (S), expressed as a fusion protein in the vector pROS. The recombinant proteins were used as antigens in Western blot (WB) assays to detect the 229E-specific IgG antibodies and the results were compared with a standard serological method, indirect immunofluorescence. Serum samples of 51 paediatric patients, suffering from acute respiratory illness, and 10 adults, voluntarily infected with human coronavirus, were tested. The serum samples of the adult group had coronavirus-specific IgG antibodies in both test systems. In contrast, only 8/51 sera of the paediatric group were positive for coronavirus-specific IgG by both WB and IF and 20/51 sera were positive by WB, but not by IF. The overall incidence of human coronavirus infections in the paediatric age group was 55% evaluated by WB analysis and 16% evaluated by IF. This study shows that recombinant human coronavirus 229E proteins are suitable reagents for the epidemiological screening of coronavirus 229E infections.

Characterization of a monoclonal antibody resistant variant of MHV.

A monoclonal antibody resistant (MAR) variant of MHV was isolated after infection of hybridoma cells secreting the neutralizing and fusion-inhibiting monoclonal antibody, mAb 11F. The isolated variant was able to mediate syncytia formation even in the presence of high concentrations of mAb 11F. The S gene of the variant was cloned and sequenced. There were three nucleotide exchanges in comparison to the wild-type S gene, resulting in two amino acid alterations. However, both amino acid substitutions (at positions 255 and 1116) were located outside the binding site of mAb 11F.

Replication and transcription of HCV 229E replicons. p6.

Replicons based upon the human coronavirus 229E (HCV 229E) genome were transfected into HCV 229E infected cells. We demonstrate that a synthetic RNA comprised of 646 nucloetides from the 5' end and 1465 nucloetides from the 3' end of the HCV 229E genome is replication competent. We conclude that the cis-acting elements necessary for replication are located in these 5' and 3' genomic regions. Furthermore, we inserted the intergenic region of the HCV 229E nucleocapsid protein gene into this basic construct and were able to demonstrate the transcription of "subgenomic" RNAs.

Characterization of a papain-like cysteine-proteinase encoded by gene 1 of the human coronavirus HCV 229E.

Expression of the coronaviral gene 1 polyproteins, pp 1a and pp 1ab, involves a series of proteolytic events that are mediated by virus-encoded proteinases similar to cellular papain-like cysteine-proteinases and the 3C-like proteinases of picornaviruses. In this study, we have characterized, in vitro, the human coronavirus HCV 229E papain-like cysteine-proteinase PCP 1. We show that PCP 1 is able to mediate cleavage of an aminoterminal polypeptide, p9, from in vitro translation products representing the aminoproximal region of pp 1a/pp 1ab. Mutagenesis studies support the prediction of Cys1054 and His1278 as the catalytic amino acids of the HCV 229E PCP 1, since mutation of these residues abolishes the proteolytic activity of the enzyme.

A strategy for the generation of infectious RNAs and autonomously replicating RNAs based on the HCV 229E genome.

A strategy to generate in vitro transcripts representing infectious RNAs and autonomously replicating RNAs based on the HCV 229E genome is presented. PCR-DNAs were ligated in vitro, resulting in 27 kbp and 22 kbp ligation products. These DNAs can now be transcribed in vitro and the RNAs tested for infectivity and their ability to replicate.

Long distance RT-PCRs of human coronavirus 229E RNA.

The generation and cloning of cDNA fragments longer than 10 kb is often a difficult and time consuming task. In this study, we have analysed the conditions necessary of produce reverse transcripts longer than 10 kb that can be amplified by polymerase chain reaction. Thus, we isolated poly(A)-RNA from human coronavirus 229E infected MRC-5 cells and did reverse transcription using a sequence-specific primer. Subsequently, we amplified PCR products of varying length upstream of the primer position. Optimisation of the poly(A)-RNA preparation, the reverse transcription protocol and the polymerase chain reaction cycle conditions enabled us to successfully amplify regions of the human coronavirus 229E genome between 11.5 and 20.3 kb in length.

Characterization of the human coronavirus 229E (HCV 229E) gene 1.

The sequence of the HCV 229E gene 1 has been determined and compared with the homologous sequences of the murine hepatitis virus and the avian infectious bronchitis virus. The coding sequence of gene 1 is 20,273 nucleotides in length. Within this coding region are two large open reading frames, ORF 1a (4,086 codons) and ORF 1b (2,687 codons) which overlap by 40 nucleotides. In the overlapping region, the genomic RNA can be folded into a pseudoknot structure, an element which is known to mediate -1 ribosomal frame-shifting in other coronaviruses. Assuming that -1 frame-shifting occurs at the HCV sequence UUUAAAC (nucleotides 12,514-12,520), the ORF 1a - ORF 1b product is predicted to be 6,758 amino acids in length. Our sequence analysis of the HCV 229E gene 1 has revealed a high degree of similarity within the ORF 1b of HCV, MHV and IBV, whereas ORF 1a is much less conserved. Elements which are believed to be necessary for specific (e.g. frame-shifting) and general (e.g. NTP-binding/helicase) transcriptional functions have been identified. This study completes the genomic sequence of HCV 229E which is 27.27 kb long and one of the largest known RNA genomes.

Substrate specificity of the human coronavirus 229E 3C-like proteinase.

Coronavirus gene expression involves proteolytic processing of the gene 1-encoded polyproteins and a key enzyme in this process is the virus-encoded 3C-like proteinase. In this study, we describe the biosynthesis of the human coronavirus 229E 3C-like proteinase in Escherichia coli and the substrate specificity of the purified protein. Using immunofluorescence microscopy, we have also investigated the subcellular localization of the 3C-like proteinase and have found a punctate, perinuclear distribution of the proteinase in virus-infected cells.

Molecular analysis of the coronavirus-receptor function of aminopeptidase N.

Aminopeptidase N (APN) is a major cell surface for coronaviruses of the serogroup I. By using chimeric APN proteins assembled from human, porcine and feline APN we have identified determinants which are critically involved in the coronavirus-APN interaction. Our results indicate that human coronavirus 229E (HCV 229E) is distinct from the other serogroup I coronaviruses in that determinants located within the N-terminal parts of the human and feline APN proteins mediate the infection of HCV 229E, whereas determinants located within the C-terminal parts of porcine, feline and canine APN mediate the infection of transmissible gastro-enteritis virus (TGEV), feline infectious peritonitis virus (FIPV) and canine coronavirus (CCV), respectively. A further analysis of the mapped amino acid segments by site directed mutagenesis revealed that a short stretch of 8 amino acids in the hAPN protein plays a decisive role in mediating HCV 229E reception.

Isolation and recombinant expression of an MHV-JHM neutralising monoclonal antibody.

The monoclonal antibody A1 (mab A1) efficiently neutralises the infection of susceptible cells by the murine hepatitis virus MHV-JHM in vitro and in vivo (Wege et al., 1984). The variable regions of mab A1 were amplified from mRNA of the respective hybridoma cell line by RT-PCR and integrated into different eukaryotic expression vectors. The biological function of the recombinant antibody constructs was verified by virus neutralisation assays. Whereas a complete recombinant antibody (mab A1rec.) expressed in transfected murine myeloma cells inhibited the MHV-JHM infection as well as the parental antibody, a single-chain Fv derived from mab A1 did not show any neutralising activity.

Transcription strategy of coronaviruses: fusion of non-contiguous sequences during mRNA synthesis.

MHV replicates in the cell cytoplasm and viral genetic information is expressed in infected cells as one genomic sized RNA ( mRNA1 ) and six subgenomic mRNAs. The seven RNAs were assumed to have common 3' ends of the size of RNA7 , the smallest RNA. The data reported here, show that this model is too simple and that the mRNAs are composed of a leader and body sequence. Electron microscopic analysis of hybrids formed between single stranded cDNA copied from mRNA7 and genomic RNA or mRNA6 shows that genomic RNA, mRNA6 and mRNA7 have common 5' terminal sequences. Furthermore, nucleotide sequence analysis shows that the nucleotide sequence of the 5' end of mRNA7 diverges from the corresponding region of the genome just upstream from the initiation codon of the nucleocapsid gene. Because the synthesis of each mRNA is inactivated by UV irradiation in proportion to its own length, the subgenomic mRNAs are apparently not produced by the processing of larger RNAs. The available data have to be explained by translocation of the polymerase/leader complex to specific internal positions on the negative strand. In this way the leader and body sequences are joined together by a mechanism completely different from conventional RNA splicing but nevertheless giving the same end result.

The Coronaviridae now comprises two genera, coronavirus and torovirus: report of the Coronaviridae Study Group.

At the April 1992, mid-term meeting of the International Committee on Taxonomy of Viruses (ICTV) a proposal from the Coronaviridae Study Group (CSG) to include the torovirus genus in the Coronaviridae was accepted. Following another proposal, the arterivirus genus was removed from the Togaviridae but not assigned to another family. The arteriviruses have some features in common with the Coronaviridae but also have major differences. After much debate, culminating in September 1992, it was decided that the CSG would not recommend inclusion of arterivirus in the Coronaviridae. It was agreed that (a) the nomenclature used for coronavirus genes, mRNAs and polypeptides (Cavanagh et al., 1990) should be used for toroviruses, (b) that the small (about 100 amino acids) membrane-associated protein, which is distinct from the integral membrane glycoprotein M, associated with virions of infectious bronchitis (Liu & Inglis, 1991) and transmissible gastroenteritis (Godet et al., 1992) coronaviruses would be referred to by the acronym sM (lower case 's') and (c) that 'pol' (polymerase) should be used as a working term for gene 1, which comprises open reading frames (ORFs) 1a and 1b in both genera of the Coronaviridae.

Expression of a recombinant monoclonal antibody from a bicistronic mRNA.

The variable regions of the murine monoclonal antibody A1, which effectively neutralizes the infection of susceptible cells by the murine hepatitis virus strain JHM, were cloned, sequenced, and expressed in mammalian cells as a functional recombinant antibody. To accomplish the concurrent synthesis of both antibody chains, the light- and heavy-chain-coding regions were inserted into a bicistronic expression cassette based on the encephalomyocarditis virus internal ribosomal entry site. The strategy of combining both coding regions in one bicistronic mRNA allows for the rapid isolation of cell clones expressing high levels of recombinant antibody.

Phylogenetic analysis of feline coronavirus strains in an epizootic outbreak of feline infectious peritonitis.

BACKGROUND: Feline coronavirus (FCoV) infection is common. In a small percentage of cats, FCoV infection is associated with the fatal disease feline infectious peritonitis (FIP). Genetically distinct virulent and avirulent strains of FCoV might coexist within a cat population. OBJECTIVES: To determine whether the strains of FCoV in FIP-affected cats are closely related or genetically distinct from the fecally derived strains of FCoV in contemporary-asymptomatic cats during an epizootic outbreak of FIP. ANIMALS: Four cats euthanized because of FIP and 16 asymptomatic cats. METHODS: This prospective outbreak investigation was initiated during an outbreak of FIP in cats within or rehomed from a rescue/rehoming center. Postmortem samples were collected from cats with FIP and contemporaneous fecal samples from asymptomatic cats. RNA was purified from tissue and fecal samples, FCoV gene fragments were reverse transcribed, PCR-amplified using novel primers, and sequenced. Sequences were aligned with ClustalW and compared with published FCoV sequences. RESULTS: FCoV RNA was detected in all 4 FIP cat postmortem samples and in 9 of the 16 fecal samples from contemporary-asymptomatic cats. Novel primers successfully amplified fragments from 4 regions of the genome for all FCoV-positive samples. Phylogenetic analysis showed that the FIP-associated strains of FCoV from the outbreak were very closely related to the fecally derived strains of FCoV from contemporary-asymptomatic cats. CONCLUSIONS AND CLINICAL IMPORTANCE: Sequence analysis provided no evidence that genetically distinct virulent and avirulent strains of FCoV were present during this FIP outbreak.