Coronaviruses
Coronaviruses are a large family of viruses that can infect a range of hosts. They are known to cause diseases including the common cold, Severe Acute Respiratory Syndrome (SARS) and Middle East Respiratory Syndrome (MERS) in humans.
In January 2020, China saw an outbreak of a new coronavirus strain now named SARS-CoV-2. Although the animal reservoir for the SARS and MERS viruses are known, this has yet to have been confirmed for SARS-CoV-2. All three strains are transmissible between humans.
To allow the widest possible distribution of relevant research, the Microbiology Society has brought together articles from across our portfolio and made this content freely available.
Image credit: "MERS-CoV" by NIAID is licensed under CC BY 2.0, this image has been modified.
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201 - 220 of 298 results
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Characterization of the IgA and subclass IgG responses to neutralizing epitopes after infection of pregnant sows with the transmissible gastroenteritis virus or the antigenically related porcine respiratory coronavirus
In this study, we have investigated the characteristics of secreted IgA and other classes of Ig induced after vaccination of sows with transmissible gastroenteritis virus (TGEV) or the antigenically related porcine respiratory coronavirus (PRCV). Both viruses induced the secretion of neutralizing antibodies of different classes in the sows’ milk, but these protected suckling piglets against TGEV to different degrees. Quantitative differences in the induction of IgA by both viruses were found among the different viral antigenic sites and subsites of glycoprotein S. In TGEV-vaccinated sows, antigenic subsite A was the best inducer of IgA, followed by antigenic site D. After vaccination with PRCV, lower levels of IgA were detected on colostrum and milk, antigenic site D and subsite Ab being the immunodominant sites. This quantitative difference in epitope recognition could explain the differences in newborn piglet protection found using Ig classes purified from the milk of sows immunized with both viruses. Apparently only IgA recognizing at least antigenic sites A and D confers good protection in vivo, whereas any Ig class recognizing only one antigenic site may neutralize the virus in cell culture. These results indicate that the formulation of a subunit vaccine against TGEV has to consider the inclusion of more than one antigenic site involved in virus neutralization.
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Nucleotide sequence and expression of the spike (S) gene of canine coronavirus and comparison with the S proteins of feline and porcine coronaviruses
More LessWe have cloned, sequenced and expressed the spike (S) gene of canine coronavirus (CCV; strain K378). Its deduced amino acid sequence has revealed features in common with other coronavirus S proteins: a stretch of hydrophobic amino acids at the amino terminus (the putative signal sequence), another hydrophobic region at the carboxy terminus (the membrane anchor), heptad repeats preceding the anchor, and a cysteine-rich region located just downstream from it. Like other representatives of the same antigenic cluster (CCV-Insavc-1 strain, feline infectious peritonitis and enteric corona- viruses, porcine transmissible gastroenteritis and respiratory coronaviruses, and the human coronavirus HCV 229E), the CCV S polypeptide lacks a proteolytic cleavage site present in many other coronavirus S proteins. Pairwise comparisons of the S amino acid sequences within the antigenic cluster demonstrated that the two CCV strains (K378 and Insavc-1) are 93·3% identical, about as similar to each other as they are to the two feline coronaviruses. The porcine sequences are clearly more divergent mainly due to the large differences in the amino-terminal (residues 1 to 300) domains of the proteins; when only the carboxy-terminal parts (residues 301 and on) are considered the homologies between the canine, feline and porcine S polypeptides are generally quite high, with identities ranging from 90·8 % to 96·8 %. The human coronavirus is less related to the other members of the antigenic group. A phylogenetic tree constructed on the basis of the S sequences showed that the two CCVs are evolutionarily more related to the feline than to the porcine viruses. Expression of the CCV S gene using the vaccinia virus T7 RNA polymerase system yielded a protein of the expected M r (approximately 200K) which could be immunoprecipitated with an anti-feline infectious peritonitis virus polyclonal serum and which was indistinguishable from the S protein synthesized in CCV-infected cells.
The nucleotide sequence data presented in this paper have been submitted to the EMBL database and assigned the accession number X77047.
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Expression of the S1 and S2 subunits of murine coronavirus JHMV spike protein by a vaccinia virus transient expression system
More LessThe spike (S) protein of murine coronavirus JHMV, variant cl-2, comprises two polypeptides, N-terminal S1 (with an N-terminal signal peptide) and C-terminal S2 (with a C-terminal transmembrane domain). In order to express these subunits, we constructed three different vaccinia virus transfer vectors (VV-TVs) containing cDNAs encoding the S1 protein without a transmembrane domain (pSFS1utt), the S1 protein with a C-terminal transmembrane domain derived from S2 (pSFS1tmd) or the S2 protein with an N-terminal signal peptide derived from S1 (pSFssS2). The S1 and S2 proteins were expressed in DBT cells by infection with vaccinia virus and transfection of these VV-TVs. In cells transfected with the pSFS1utt and pSFS1tmd, 96K and 106K proteins, respectively, were detected by Western blotting. The ssS2 protein expressed by pSFssS2 was 96K, which was slightly larger than the authentic S2 protein. The S1utt and S1tmd proteins were shown by binding studies using a panel of monoclonal antibodies to be antigenically indistinguishable from the authentic S1 protein. The S1tmd and ssS2 proteins were detected on the cell surface by immunofluorescence, whereas the S1utt protein was not. However, when the S1utt protein was expressed together with the ssS2 protein, the S1utt was detected on the cell membrane. This suggested that the S1utt was associated with ssS2 on the cell membrane. These observations indicate that the expressed S1 and S2 proteins associated in a similar manner to the authentic S1 and S2 proteins produced in DBT cells infected with cl-2. However, cell fusion was not observed in cells expressing either S1 or S2 nor in cells coexpressing both S1 and S2, although the whole S protein expressed by VV-TV did induce fusion.
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Molecular characterization of the S protein gene of human coronavirus OC43
More LessThe gene encoding the spike protein of the OC43 strain of human coronavirus (HCV-OC43) was cloned and sequenced. The complete nucleotide sequence revealed an open reading frame of 4062 nucleotides encoding a protein of 1353 amino acids with a predicted M r of 150078. Structural features include 22 N-glycosylation sites, an N-terminal hydrophobic signal sequence of 17 amino acids, an hydrophilic cysteine-rich sequence of 35 amino acids near the C terminus, and a potential proteolytic cleavage site (RRSR) between amino acid residues 758 and 759, yielding S1 and S2 segments of 84730 and 65366 M r, respectively. The predicted amino acid sequence of the spike protein of HCV-OC43 has 91% identity with that of the Mebus strain of bovine coronavirus, revealing more sequence divergence in the putative bulbous part (S1) than in the predicted stem region (S2).
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Sequence determination of the nucleocapsid protein gene of the porcine epidemic diarrhoea virus confirms that this virus is a coronavirus related to human coronavirus 229E and porcine transmissible gastroenteritis virus
More LessThe nucleotide sequence of 1.7 kbp cDNA, comprising the region nearest the 3′ end of the genome of the porcine epidemic diarrhoea virus (PEDV), has been independently determined for two European isolates of PEDV. Almost identical results were obtained for the two isolates, which were derived from cases of PEDV infection in Belgium and Britain in 1977 and 1987, respectively. The sequences contained a 1323 nucleotide (nt) open reading frame (ORF), which showed moderate identity to the nucleocapsid (N) gene of other coronaviruses. The greatest similarity at both the nucleic acid and protein levels was to the human coronavirus 229E. The PEDV N gene was, however, notably larger than that of the human 229E and porcine transmissible gastroenteritis viruses. This reflects the presence of a putative insertion of approximately 135 nt located towards the middle of the N gene. A second 336 nt ORF, which might encode a leucine-rich protein similar to, but shorter than, the bovine coronavirus internal protein was found within the PEDV N gene. Several RNA motifs typical of coronaviruses were also observed. These results confirm the earlier provisional classification of PEDV as a coronavirus.
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An immunodominant CD4+ T cell site on the nucleocapsid protein of murine coronavirus contributes to protection against encephalomyelitis
More LessThe murine coronavirus neurotropic strain JHM (MHV-JHM) nucleocapsid (N) protein induces a strong T-helper cell response in Lewis rats. It has been shown previously that N-specific CD4+ T cells can confer protection against acute disease upon transfer to otherwise lethally infected rats. To define the major antigenic regions that elicit this T cell response, truncated fragments of N protein were expressed from a bacterial expression vector and employed as T cell antigens. Lymphocytes from either MHV-JHM-infected or immunized rats were stimulated in culture with virus antigen, grown and tested for their specificity to the N protein fragments. The carboxy-terminally located C4-N fragment (95 amino acids) induced the most pronounced proliferative response irrespective of whether the lymphocyte culture was derived from immunized or MHV-JHM-infected rats. We established T cell lines specific for the truncated N protein fragments and tested their potential to mediate protection by transfer experiments. Only the T cell line C4-N and the T cell line specific for the full-length N protein were protective. By contrast, all truncated N protein fragments elicited a humoral immune response and contained antigenic sites recognized by antibodies from diseased rats.
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Neutralization and fusion inhibition activities of monoclonal antibodies specific for the S1 subunit of the spike protein of neurovirulent murine coronavirus JHMV c1-2 variant
More LessThe cleavage products of the spike (S) protein, the S1 and S2 subunits, of the highly neurovirulent murine coronavirus (MHV) JHMV c1-2 variant were identified by immunoprecipitation of virus-infected cell lysates after treatment with urea and 2-mercaptoethanol. By this method 14 monoclonal antibodies (MAbs) raised against the S protein of the c1-2 variant were revealed to react with the S1 subunit and one with the S2 subunit. These 14 MAbs were classified into the following three groups: (A) MAbs reactive to almost all MHV strains examined, (B) MAbs specific for the JHMV strain and (C) MAbs specific for a large S protein of the JHMV strain. All five MAbs classified in group B showed neutralization activity and four of them also showed fusion inhibition activity. Four of six MAbs in group C showed neutralizing activity to the c1-2 variant but not to the sp-4 variant, and most of them had no fusion inhibition activity. Western blot analyses showed that all of the MAbs, except for no. 2 in group A, failed to react with the denatured S and S1 proteins. All MAbs in groups A and C, with the exception of no. 19 in group A, reacted with the mildly denatured S proteins, whereas none of the MAbs in group B did. These results suggest that MAbs in group B recognized highly conformational epitopes which may be involved in the binding of virions to cellular receptors and the fusion activity of the virus.
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Proteolytic cleavage of the murine coronavirus surface glycoprotein is not required for fusion activity
More LessA cDNA copy of the murine coronavirus [otherwise known as murine hepatitis virus (MHV)] surface (S) glycoprotein gene was isolated and expressed in DBT cells by using a recombinant vaccinia virus system. The expressed S protein induced extensive syncytium formation at neutral pH. Oligonucleotide mutagenesis was used to engineer an S protein gene in which codons for the proteolytic cleavage site, Arg-Arg-Ala-Arg-Arg, were replaced with an equal number of codons for amino acids with aliphatic or aliphatic hydroxyl side-chains. The mutated S protein was stably expressed in DBT cells and, in contrast to the wild-type protein, was not proteolytically cleaved. Nevertheless, the non-cleaved protein induced extensive syncytium formation. These results clearly indicate that the non-cleaved form of the MHV S protein is able to mediate cell membrane fusion. Thus proteolytic cleavage is not an absolute requirement for fusion activity.
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Bovine coronavirus spike glycoprotein: localization of an immunodominant region at the amino-terminal end of S2
More LessWe have identified the binding site of monoclonal antibodies (MAbs) against the S2 subunit of the bovine coronavirus spike (S) glycoprotein. The location of this site was first investigated by using prokaryotic expression of DNA restriction fragments covering the entire S gene. The amino acid sequence containing the antibody binding site was shortened from 70 to 20 amino acids by digestion of plasmid DNA with exonuclease III, followed by sequencing of the smallest digestion product encoding an immunoreactive fusion protein. Finally we synthesized a set of nonapeptides covering the 20 amino acid sequence extending from the N-terminal residue of the S2 subunit (Ala 769 to Tyr 798). MAbs reacted mainly with six consecutive overlapping peptides with the sequence TTGYRFTN-FEPFTV. Polyclonal antibodies from hyperimmunized or convalescent animals reacted only with the recombinant proteins identified by MAbs, and the hyperimmune serum bound to the same set of peptides. This suggests that this highly conserved linear antigenic determinant corresponds to an immunodominant region. This region resembles both in location and immunodominance the linear determinant defined on the infectious bronchitis virus S2 subunit. The presence of similar regions in the N-terminal region of the S2 subunit of other coronaviruses is discussed.
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Differential in vitro inhibition of feline enteric coronavirus and feline infectious peritonitis virus by actinomycin D
More LessThe growth of feline enteric coronavirus strain 79-1683 in whole feline embryo cells was inhibited by the presence of 1 µg/ml of actinomycin D in the culture fluid. No virus-specific mRNAs could be detected in such cultures and yields of infectious virus were depressed by >99%. By contrast, the antigenically related feline infectious peritonitis virus strain 79-1146 was unaffected by the presence of actinomycin D, indicating a fundamental difference between the two feline coronavirus strains in their requirements for host-encoded function(s).
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Analysis of a 9.6 kb sequence from the 3′ end of canine coronavirus genomic RNA
More LessWe have analysed the organization of the 3′ end of the genomic RNA of canine coronavirus (CCV), a virus which has a close antigenic relationship to transmissible gastroenteritis virus (TGEV), porcine respiratory coronavirus (PRCV) and feline infectious peritonitis virus (FIPV). Genomic RNA isolated from CCV strain Insavc-1-infected A72 cells was used to generate a cDNA library. Overlapping clones, spanning approximately 9.6 kb [from the 3′ end of the polymerase gene, 1b, to the poly(A) tail] were identified. Sequencing and subsequent analyses revealed 10 open reading frames (ORFs). Three of these code for the major coronavirus structural polypeptides S, M and N; a fourth codes for a small membrane protein, SM, a putative homologue of the IBV structural polypeptide 3c, and five code for polypeptides, designated 1b, 3a, 4, 7a and 7b, homologous to putative non-structural polypeptides encoded in the TGEV or FIPV genomes. An extra ORF which had not hitherto been identified in this antigenic group of coronaviruses was designated 3x. Pairwise alignment of these ORFs with their counterparts in TGEV, PRCV and FIPV revealed high levels of identity and highlighted the close relationship between the members of this group of viruses.
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Sequence analysis of the membrane protein gene of human coronavirus OC43 and evidence for O-glycosylation
More LessThe gene encoding the membrane (M) protein of the OC43 strain of human coronavirus (HCV-OC43) was amplified by a reverse transcription-polymerase chain reaction of viral RNA with HCV-OC43- and bovine coronavirus (BCV)-specific primers. The nucleotide sequence of the cloned 1.5 kb fragment revealed an open reading frame (ORF) of 690 nucleotides which was identified as the M protein gene from its homology to BCV. This ORF encodes a protein of 230 amino acids with an M r of 26416. The gene is preceded by the motif UCCAAAC, analogous to the consensus coronavirus transcription initiation sequence. The M protein of HCV-OC43 shows features typical of all coronavirus M proteins studied: a hydrophilic, presumably external N terminus including about 10% of the protein, and a potential N-glycosylation site followed by three major hydrophobic transmembrane domains. The amino acid sequence of the M protein of HCV-OC43 has 94% identity with that of the Mebus strain of BCV, and also contains six potential O-glycosylation sites in the exposed N-terminal domain. Indeed, the glycosylation of the M protein was not inhibited in the presence of tunicamycin, which is indicative of O-glycosylation, as previously reported for BCV and murine hepatitis virus. Virions released from tunicamycin-treated cells contained the M glycoprotein but were devoid of both peplomer (S) and haemagglutinin-esterase (HE) proteins. Thus, inhibition of the N-glycosylation of the S and HE structural proteins prevented their incorporation into progeny virions, an indication that they are dispensable for virion morphogenesis, unlike the M protein.
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Synthesis and Processing of the Haemagglutinin—esterase Glycoprotein of Bovine Coronavirus Encoded in the E3 Region of Adenovirus
The haemagglutinin—esterase gene (HE) of bovine coronavirus (BCV) encodes a major viral membrane glycoprotein that elicits BCV-neutralizing antibodies. The BCV HE gene was cloned into a human adenovirus serotype 5 (Ad5) transfer vector in place of early transcription region 3, and a helper-independent recombinant virus was constructed by rescue of the transcription unit by homologous in vivo recombination between the vector and Ad5 genomic DNA. The BCV HE polypeptide expressed by this recombinant Ad was characterized in vivo and in vitro. A 65K polypeptide was identified using an anti-BCV antibody in both human (293) and bovine (MDBK) cells infected with the recombinant Ad. In the absence of a reducing agent, migration of the 65K polypeptide was shifted to 130K, indicating that the recombinant HE polypeptide existed in a dimeric form. The HE polypeptide was glycosylated, as demonstrated by labelling with [3H]glucosamine, and was immunoreactive with three distinct groups of conformation-specific anti-HE monoclonal antibodies (MAbs). Cells infected with recombinant Ad expressing BCV HE exhibited both haemadsorption activity and acetylesterase activity. In addition, the anti-HE group A MAbs HC10-5 and KD9-40 inhibited both the haemadsorption activity and esterase activity of the recombinant HE polypeptide, suggesting that the antigenic domain responsible for BCV neutralization may overlap (or is closely associated with) the domain(s) responsible for haemagglutination and/or acetylesterase activities. When mice were inoculated intraperitoneally with live recombinant Ad, a significant level of BCV-neutralizing HE-specific antibody was induced. These results indicate that the recombinant Ad replicates and directs the synthesis of the BCV HE polypeptide in vivo.
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Bovine coronavirus peplomer glycoproteins: detailed antigenic analyses of S1, S2 and HE
More LessForty-four monoclonal antibodies (MAbs) to the G110 isolate of bovine enteric coronavirus were used for the characterization of the peplomer proteins S and HE. Fourteen of these MAbs reacted with HE and the remaining 30 with the products of the S gene, S1 (19 MAbs), S2 (six MAbs) and gp200 (five MAbs). S1 and HE were found to carry major neutralization determinants, and S1 appeared to elicit the production of the MAbs displaying the highest neutralizing activity. The topography of the epitopes was assessed by means of a competitive binding assay; the 44 MAbs defined four independent antigenic domains on S1, two on S2, one on gp200 and two on HE. All the neutralizing anti-S1 MAbs mapped in antigenic sites A and B and all the neutralizing anti-HE MAbs in HE-B. Antigenic site S1-B was further subdivided into four subsites. Functional mapping was performed by testing a library of neutralization-resistant mutants against the neutralizing MAbs. Analysis of their reactivity in a neutralization test confirmed the overall distribution of epitopes in S1-B and HE-B.
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Molecular cloning and expression of a spike protein of neurovirulent murine coronavirus JHMV variant c1-2
More LessA cDNA encoding the spike (S) protein of the neurovirulent murine coronavirus JHMV variant c1-2 was isolated and sequenced. Analysis of the cDNA revealed that the S protein consists of 1376 amino acids, as does the S protein of mouse hepatitis virus 4. We inserted the cDNA into the genome of vaccinia virus to obtain a recombinant vaccinia virus (rVV). The S protein expressed in RK13 cells infected by the rVV was shown to be electrophoretically and immunologically indistinguishable from the S protein produced in DBT cells infected with c1-2 virus. RVV infection of rats and mice induced S protein-specific antibody production detectable by immunofluorescence and neutralization. Moreover, the S protein expressed by the rVV induced syncytium formation not only in mouse DBT and L cells, which are susceptible to c1-2 virus infection, but also in rabbit RK13 cells, which are not susceptible to c1-2 virus infection. This result suggests the possibility that RK13 cells have binding sites for the c1-2 virus S protein.
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Bovine coronavirus uses N-acetyl-9-O-acetylneuraminic acid as a receptor determinant to initiate the infection of cultured cells
More LessThe importance of N-acetyl-9-O-acetylneuraminic acid (Neu5,9Ac2) as a receptor determinant for bovine coronavirus (BCV) on cultured cells was analysed. Pretreatment of MDCK I (Madin Darby canine kidney) cells with neuraminidase or acetylesterase rendered the cells resistant to infection by BCV. The receptors on a human (CaCo-2) and a porcine (LLC-PK1) epithelial cell line were also found to be sensitive to neuraminidase treatment. The susceptibility to infection by BCV was restored after resialylation of asialo-MDCK I cells with Neu5,9Ac2. Transfer of sialic acid lacking a 9-O-acetyl group was ineffective in this respect. These results demonstrate that 9-O-acetylated sialic acid is used as a receptor determinant by BCV to infect cultured cells. The possibility is discussed that the initiation of a BCV infection involves the recognition of different types of receptors, a first receptor for primary attachment and a second receptor to mediate the fusion between the viral envelope and the cellular membrane.
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Monoclonal antibodies differentiate between the haemagglutinating and the receptor-destroying activities of bovine coronavirus
More LessA relatively simple and sensitive method is described which enables the effect of monoclonal antibodies (MAbs) on the receptor-destroying enzyme (RDE) and the haemagglutination (HA) activity of bovine coronavirus (BCV) to be analysed in one assay. A lysate of HRT-18 cells infected with the L9 strain of BCV was found to have a higher RDE:HA ratio than purified virus. At 4 °C the lysate induced an HA pattern which completely disappeared upon raising of the temperature to 37 °C. This L9-infected cell lysate was used to determine the HA inhibition (HAI) titres of MAbs directed against the surface glycoproteins S and HE of BCV. Thereafter, the test plates were incubated at 37 °C to enable the ability of the MAbs to prevent elution of virus from BCV-erythrocyte complexes to be assessed. No inhibition of RDE was detectable with MAbs against glycoprotein S, which had HAI titres ranging from 1:16 to 1:128. On the other hand, MAbs directed against glycoprotein HE had similar HAI titres, but they inhibited elution of 8 HA units of BCV at titres of up to 1:65000.
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Sequence analysis of the turkey enteric coronavirus nucleocapsid and membrane protein genes: a close genomic relationship with bovine coronavirus
More LessThe 3′ end of the turkey coronavirus (TCV) genome and the gene encoding the nucleocapsid protein (N) were cloned and sequenced. The gene encoding the membrane protein (M) was obtained by cloning a polymerase chain reaction (PCR)-amplified fragment obtained using bovine coronavirus (BCV)-specific primers. Furthermore, five TCV DNA fragments, obtained by PCR on RNA from clinical specimens and corresponding to either the N terminus of the M protein or the complete M protein were also cloned and sequenced. The sequence revealed a 3′ non-coding region of 291 bases, an open reading frame (ORF) encoding the N protein with a predicted size of 448 amino acids, or an M r of 49K, and an ORF encoding the M protein with a predicted size of 230 amino acids and an M r of 26K. A third ORF, encoding a hypothetical protein of 207 amino acids with an M r of 23K was found within the N gene sequence. The amino acid sequences of both the N and M proteins were more than 99% similar to those published for BCV. Extensive similarity was also observed between the amino acid sequences of the TCV N protein and those of murine hepatitis virus (MHV) (70%) and human respiratory coronavirus strain OC43 (HCV-OC43) (98%) and between the amino acid sequences of the predicted M proteins of TCV and MHV (86%). Such striking identity suggests that BCV, TCV and HCV-OC43 must have diverged from each other only recently. A potential N-glycosylation site was found at the N terminus of the TCV M protein and is situated at the same location in BCV, MHV and transmissible gastroenteritis virus.
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High level transient expression of the murine coronavirus haemagglutinin-esterase
More LessWe have expressed the murine coronavirus haemagglutinin-esterase protein in a vaccinia virus/T7 RNA polymerase system. The levels of expression observed are significantly higher than those found in virus-infected cells. The expressed protein has both receptor-destroying (esterase) and receptor-binding (haemad-sorption) activities. The use of this system will greatly facilitate analysis of the structure-function relationships of this protein.
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Sequence comparison of the 5′ end of mRNA 3 from transmissible gastroenteritis virus and porcine respiratory coronavirus
More LessAnalysis of porcine transmissible gastroenteritis virus (TGEV) and porcine respiratory coronavirus (PRCV) mRNA species indicated a deletion in mRNA 3 of PRCV. Polymerase chain reaction (PCR) was used to clone the 5′ end of mRNA 3 from PRCV for comparison with the equivalent region in TGEV. Small deletions were observed within and around the PRCV sequence equivalent to the putative open reading frame (ORF) ORF-3a identified in TGEV. The potential RNA polymerase-leader complex binding site (leader RNA binding site), ACTAAAC, found upstream of ORF-3a in TGEV, was absent from the PRCV genome but a potential site was found in the PRCV genome upstream of a gene equivalent to TGEV ORF-3b. PCR analysis, using primers corresponding to sequences within the ORF-3b gene and the leader RNA sequence, confirmed that the leader RNA binding site was upstream of a gene equivalent to TGEV ORF-3b on PRCV mRNA 3 but upstream of ORF-3a on TGEV mRNA 3. The presence of the new leader RNA binding site would be responsible for generating the smaller mRNA 3 species found in PRCV-infected cells.
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