Coronavirus MHV-JHM: nucleotide sequence of the mRNA that encodes the membrane protein

Unique N-linked glycosylation of murine coronavirus MHV-2 membrane protein at the conserved O-linked glycosylation site

The membrane (M) proteins of murine coronavirus (MHV) strains have been reported to contain only O-linked oligosaccharides. The predicted O-glycosylation site consisting of four amino acid residues of Ser-Ser-Thr-Thr is located immediately adjacent to the initiator Met and is well conserved among MHV strains investigated so far. We analyzed the nucleotide sequence of a highly virulent strain MHV-2 M-coding region and demonstrated that MHV-2 had a unique amino acid, Asn, at position 2 at the conserved O-glycosylation site. We also demonstrated that this substitution added N-linked glycans to MHV-2 M protein resulting in increment of molecular mass of MHV-2 M protein compared with JHM strain having only O-linked glycans.

Sequence analysis of major structural proteins of newly isolated mouse hepatitis virus

We have isolated the virus from a fecal pellet in the colon of a BALB/c mouse with X-linked immunodeficiency (xid) housed in a room in which there has recently been an epidemic due to mouse hepatitis virus (MHV) and designated it as the MHV-TY strain. Sequence analysis of the MHV-TY strain was performed on major structural, spike (S), membrane (M) and nucleocapsid (N), proteins directly from PCR products. The comparison of nucleotide sequences of MHV-TY with other strains investigated so far revealed that all three structural proteins of the TY strain had some unique amino acid sequences among MHV strains which can be used as markers of this strain.

Sequence analysis of the matrix/nucleocapsid gene region of turkey coronavirus

A reverse transcriptase, polymerase chain reaction (RT-PCR) procedure was used to amplify a segment of the genome of turkey coronavirus (TCV) spanning portions of the matrix and nucleocapsid (MN) protein genes (approximately 1.1 kb). The MN gene region of three epidemiologically distinct TCV strains (Minnesota, NC95, Indiana) was amplified, cloned into pUC19, and sequenced. TCV MN gene sequences were compared with published sequences of other avian and mammalian coronaviruses. A high degree of similarity (>90%) was observed between the nucleotide, matrix protein, and nucleocapsid protein sequences of TCV strains and published sequences of infectious bronchitis virus (IBV). The matrix and nucleocapsid protein sequences of TCV had limited homology (<30%) with MN sequences of mammalian coronaviruses. These results demonstrate a close genetic relationship between the avian coronaviruses, IBV and TCV.

Viral evolution and CTL epitope stability during JHMV infection in the central nervous system

The JHM strain of mouse hepatitis virus (JHMV) establishes a persistent infection in the murine central nervous system (CNS) associated with chronic ongoing demyelination in the absence of detectable virus. To distinguish between immune and replication associated mechanisms of persistence, brains from acutely and persistently infected mice were analyzed for viral RNA mutations in the encapsidation sequence (ECS) and regions encoding either the transmembrane domains of the matrix (M) protein or a protective CTL epitope in the nucleocapsid (N) protein. Detection of the ECS to 120 days post infection (p.i.) indicated low levels of replication. The ECS remained stable whereas the fragment encoding the CTL epitope revealed extensive diversity with mutation frequencies in the order of 2.0 per 1000 nts. The M gene also remained stable despite random mutations during the acute phase. Mutations in the N gene were random and not selected for during persistence, with the exception of a single prominent Pro363 to Ser substitution in a region not associated with any known regulatory function or immune response. Mutations within the CTL epitope affecting CTL recognition were found early in responder BALB/c mice (H-2d), but also in non-responder C57BL/6 (H-2b) mice, suggesting that CTL escape variants play no significant role in establishing persistence.

Variability of persisting MHV RNA sequences constituting immune and replication-relevant domains

Survivors of acute infection with the neurotropic JHM strain of mouse hepatitis virus develop a persistent infection of the central nervous system associated with chronic ongoing demyelination. Persistence is characterized by viral RNA in the absence of infectious virus. To associate persistence with possible immune evasion and/or replication defects, viral RNA from brains of acutely and persistently infected mice was examined for mutations by reverse transcriptase-PCR. Sequences analyzed included the encapsidation sequence (ECS), the transmembrane domains of the matrix (M) protein, and a cytotoxic T cell (CTL) epitope within the nucleocapsid (N) protein. The ECS, present only on genomic RNA, revealed minimal variability and was detected out to 120 days postinfection, suggesting low levels of replication. The M gene sequence also remained stable during persistence despite random mutations during the acute phase. Although the N gene sequence exhibited the greatest diversity, mutations were random and not selected for during persistence. A single exception was detected comprising a prominent Pro to Ser substitution in a region of N not associated with any known regulatory or immune function. Of the N gene mutations found within the CTL epitope in responder mice (H-2d), one resulted in reduced CTL recognition with no evidence of antagonist activity. However, this mutation was also detected in nonresponder mice (H-2b), suggesting that escape variants arising from CTL pressure play no role in establishing persistence in immunocompetent hosts infected as adults.

Sequence analysis of the nucleoprotein genes of three enterotropic strains of murine coronavirus

The nucleotide sequences of the nucleoprotein genes of three enterotropic strains of the murine coronavirus mouse hepatitis virus (MHV-Y, MHV-RI and DVIM) were determined and compared with previously reported sequences of three polytropic (respiratory) strains (MHV-A59, MHV-JHM and MHV-S). Greater than 92% homology was found among the six strains by pair-wise comparison at the nucleotide level. The genes encoded proteins of 451 to 455 residues and the deduced amino acid sequences were more than 91% homologous. A unique deletion of twelve nucleotides was found at the carboxy terminus of MHV-Y and a three nucleotide deletion was found in MHV-RI, which corresponded to the one previously reported in MHV-A59 and MHV-S. Two internal open reading frames were found within the coding region of the nucleoprotein, the smaller one was specific for the enterotropic strains. It could potentially encode a truncated version of the hypothetical protein described for MHV-A59 and MHV-S. Sequence relationship of the N gene showed no correlation with tissue tropism and no sequence or even single amino acid change unique to either tropism group was found. This indicates that the nucleoprotein of MHV probably has no part in the determination of the primary tissue tropism of an MHV strain. The role of the potential internal protein warrants further investigation.

A Th1 cell line (3E9.1) from resistant A/J mice inhibits induction of macrophage procoagulant activity in vitro and protects against MHV-3 mortality in vivo

Induction of immune coagulants has been implicated in the pathogenesis of murine hepatitis virus strain 3 (MHV-3)-induced fulminant hepatic necrosis. Previous work from our laboratory has shown that the induction of procoagulant activity (PCA) correlates with the resistance/susceptibility to disease in inbred and recombinant inbred (RI) strains of mice. Macrophages from susceptible, but not resistant, strains of mice expressed increased levels of PCA in response to MHV-3 stimulation. T lymphocytes, however, had a marked regulatory role in the final expression of macrophage PCA. CD3+ CD4+ CD8- lymphocytes from RI H-2 compatible susceptible mice were able to instruct macrophages from susceptible mice to express significantly augmented levels of PCA, whereas CD3+ lymphocytes from RI H-2 compatible MHV-3-immunized resistant mice were able to suppress induction of PCA. In this present study, T-cell lines were derived from draining popliteal lymph nodes from resistant A/J mice, which had been immunized with MHV-3. All T-cell lines showed marked proliferation to MHV-3 and MHV-JHM which was major histocompatibility complex (MHC) restricted. All cell lines were CD3+, four of these were CD4+ and one was CD8+. All of the CD4+ cell lines produced IL-2 and two produced interferon-gamma (IFN-gamma), consistent with the Th1 cytokine profile. One cell line (3E9.1) was able to inhibit the induction of macrophage PCA through production of a soluble factor although cell-to-cell contact could not be excluded. This CD4+ T-cell line conferred protection to infected and susceptible AXB8 mice. These results demonstrate that the existence of a Th1 subpopulation of cells with a regulatory effect on macrophage PCA induction in MHV-3-infected mice contributes to the resistance of the A/J strain of mice to MHV-3 infection.

Requirement of the 5'-end genomic sequence as an upstream cis-acting element for coronavirus subgenomic mRNA transcription

We have developed a defective interfering (DI) RNA containing a chloramphenicol acetyltransferase reporter gene, placed behind an intergenic sequence, for studying subgenomic mRNA transcription of mouse hepatitis virus (MHV), a prototype coronavirus. Using this system, we have identified the sequence requirement for MHV subgenomic mRNA transcription. We show that this sequence requirement differs from that for RNA replication. In addition to the previously identified requirement for an intergenic (promoter) sequence, additional sequences from the 5' end of genomic RNA are required for subgenomic mRNA transcription. These upstream sequences include the leader RNA and a spacer sequence between the leader and intergenic sequence, which is derived from the 5' untranslated region and part of gene 1. The spacer sequence requirement is specific, since only the sequence derived from the 5' end of RNA genome, but not from other MHV genomic regions or heterologous sequences, could initiate subgenomic transcription from the intergenic sequence. These results strongly suggest that the wild-type viral subgenomic mRNAs (mRNA2 to mRNA7) and probably their counterpart subgenomic negative-sense RNAs cannot be utilized for mRNA amplification. Furthermore, we have demonstrated that a partial leader sequence present at the 5' end of genome, which lacks the leader-mRNA fusion sequence, could still support subgenomic mRNA transcription. In this case, the leader sequences of the subgenomic transcripts were derived exclusively from the wild-type helper virus, indicating that the MHV leader RNA initiates in trans subgenomic mRNA transcription. Thus, the leader sequence can enhance subgenomic transcription even when it cannot serve as a primer for mRNA synthesis. These results taken together suggest that the 5'-end leader sequence of MHV not only provides a trans-acting primer for mRNA initiation but also serves as a cis-acting element required for the transcription of subgenomic mRNAs. The identification of an upstream cis-acting element for MHV subgenomic mRNA synthesis defines a novel sequence requirement for regulating mRNA synthesis in RNA viruses.

Nucleotide sequence comparison of the membrane protein genes of three enterotropic strains of mouse hepatitis virus

The nucleotide sequences of the membrane (M) protein genes and their deduced amino acid sequences of three enterotropic strains of the coronavirus mouse hepatitis virus (MHV) -Y, -RI and -DVIM were determined and compared with the previously reported sequences of two respiratory MHV strains -A59 and -JHM. The five MHV strains shared extensive nucleotide (95.2-99.0%) as well as amino acid homology (95.6-98.7%). A variable region, including a 15 nucleotide deletion unique to MHV-RI, could be identified at the 5'-terminus of the gene. This region of the M protein may be immunogenic and may contribute to the antigenic diversity of the MHV strains. Sequence relationships between the strains showed no correspondence with the primary cell tropism. This may suggest that evolution of enterotropism was not a single occurrence among different MHV strains. No sequence unique to either tropism group could be identified, indicating that the M protein of MHV probably has no part in the determination of MHV tissue tropism.

Characterization of mouse hepatitis virus-specific cytotoxic T cells derived from the central nervous system of mice infected with the JHM strain

The cytotoxic T lymphocyte (CTL) activity of spleen cells from BALB/c (H-2d) mice immunized with the neurotropic JHM strain of mouse hepatitis virus (JHMV) was stimulated in vitro for 7 days. CTL were tested for recognition of target cells infected with either JHMV or vaccinia virus recombinants expressing the four virus structural proteins. Only target cells infected with either JHMV or the vaccinia virus recombinant expressing the JHMV nucleocapsid protein were recognized. Cytotoxic T cell lines were established by limiting dilution from the brains of mice undergoing acute demyelinating encephalomyelitis after infection with JHMV. Twenty of the 22 lines recognized JHMV-infected but not uninfected syngeneic target cells, indicating that they are specific for JHMV. All T-cell lines except one were CD8+. The specificity of the CTL lines was examined by using target cells infected with vaccinia virus recombinants expressing the JHMV nucleocapsid, spike, membrane, and hemagglutinin-esterase structural proteins. Seventeen lines recognized target cells expressing the nucleocapsid protein. Three of the JHMV-specific T-cell lines were unable to recognize target cells expressing any of the JHMV structural proteins, indicating that they are specific for an epitope of a nonstructural protein(s) of JHMV. These data indicate that the nucleocapsid protein induces an immunodominant CTL response. However, no CTL activity specific for the nucleocapsid protein could be detected in either the spleens or cervical lymph nodes of mice 4, 5, 6, or 7 days after intracranial infection, suggesting that the CTL response to JHMV infection within the central nervous system may be induced or expanded locally.

Effect of intergenic consensus sequence flanking sequences on coronavirus transcription

Insertion of a region, including the 18-nucleotide-long intergenic sequence between genes 6 and 7 of mouse hepatitis virus (MHV) genomic RNA, into an MHV defective interfering (DI) RNA leads to transcription of subgenomic DI RNA in helper virus-infected cells (S. Makino, M. Joo, and J. K. Makino, J. Virol. 66:6031-6041, 1991). In this study, the subgenomic DI RNA system was used to determine how sequences flanking the intergenic region affect MHV RNA transcription and to identify the minimum intergenic sequence required for MHV transcription. DI cDNAs containing the intergenic region between genes 6 and 7, but with different lengths of upstream or downstream flanking sequences, were constructed. All DI cDNAs had an 18-nucleotide-long intergenic region that was identical to the 3' region of the genomic leader sequence, which contains two UCUAA repeat sequences. These constructs included 0 to 1,440 nucleotides of upstream flanking sequence and 0 to 1,671 nucleotides of downstream flanking sequence. An analysis of intracellular genomic DI RNA and subgenomic DI RNA species revealed that there were no significant differences in the ratios of subgenomic to genomic DI RNA for any of the DI RNA constructs. DI cDNAs which lacked the intergenic region flanking sequences and contained a series of deletions within the 18-nucleotide-long intergenic sequence were constructed to determine the minimum sequence necessary for subgenomic DI RNA transcription. Small amounts of subgenomic DI RNA were synthesized from genomic DI RNAs with the intergenic consensus sequences UCUAAAC and GCUAAAC, whereas no subgenomic DI RNA transcription was observed from DI RNAs containing UCUAAAG and GCTAAAG sequences. These analyses demonstrated that the sequences flanking the intergenic sequence between genes 6 and 7 did not play a role in subgenomic DI RNA transcription regulation and that the UCUAAAC consensus sequence was sufficient for subgenomic DI RNA transcription.

Mutagenic analysis of the coronavirus intergenic consensus sequence

Previously, a system in which an intergenic region from mouse hepatitis virus (MHV) inserted into an MHV defective interfering (DI) RNA led to transcription of a subgenomic DI RNA in helper virus-infected cells was established. In the present study, a DI cDNA containing one UCUAAAC consensus sequence in the middle of the 0.3-kb-long intergenic region located between genes 6 and 7 was constructed. From this DI cDNA clone, 21 mutant DI RNAs were constructed so that each of the seven consensus sequence nucleotides was changed individually to the three alternative bases. These mutants were used to define how changes in the integrity of MHV transcription consensus sequence UCUAAAC affected mRNA transcription. Except for two mutants with the sequences UGUAAAC and UCGAAAC, all of the mutants supported efficient subgenomic DI RNA transcription. This indicated that MHV transcription regulation was sufficiently flexible to recognize altered consensus sequences. Next, these and other mutants were used to examine the leader-body fusion site on the subgenomic DI RNAs. Sequence analysis demonstrated that all subgenomic DI RNAs analyzed contained two pentanucleotide sequences; the first sequence seemed to be contributed by the leader, and the leader-body fusion most likely took place at either the first or the second nucleotide of the second sequence. This observation was not consistent with the proposed coronavirus transcription model (S. C. Baker and M. M. C. Lai, EMBO J. 9:4173-4179, 1990) which states that nucleotide mismatch can be corrected by RNA polymerase proofreading activity.

Immune response to a murine coronavirus: identification of a homing receptor-negative CD4+ T cell subset that responds to viral glycoproteins

The lymphocyte proliferative response to mouse hepatitis virus, strain JHM (MHV-JHM), a well-described cause of chronic and acute neurological infections, has been studied using vaccinia virus recombinants expressing individual MHV proteins. The surface (S) and transmembrane (M) glycoproteins were the most active proteins in causing proliferation of lymphocytes isolated from immunized adult mice, whereas lymphocytes from persistently infected mice proliferated only in response to the S protein. The cells from immunized mice which proliferated most actively in response to MHV were positive for the CD4 antigen and secreted interferon-gamma. In addition, the most responsive subset of cells did not express gp90MEL-14, the lymph node-specific homing receptor. The results identify a subpopulation of CD4+ T cells that may be an important component of the cell-mediated immune response to this virus. The data also suggest that response to the M protein is important in preventing disease progression in C57BL/6 mice since cells which recognize this protein are absent from persistently infected mice.

Detection of rodent coronaviruses in tissues and cell cultures by using polymerase chain reaction

A polymerase chain reaction (PCR) method was developed for the detection of rodent coronaviruses in biological material by using reverse transcriptase and two primers which flanked an M gene sequence of 375 bp. PCR detected all of 11 different strains of mouse hepatitis virus (MHV) as well as rat sialodacryoadenitis virus but not bovine coronavirus or human coronavirus strains OC43 and 229E. The M gene sequences of bovine coronavirus and human coronavirus OC43 are homologous to that of MHV, but minor differences exist in the primer regions, preventing annealing of the primers. For detecting MHV-Y in tissue samples, PCR was faster than and at least as sensitive as either of the two bioassays (infant mouse bioassay and mouse antibody production test) currently used for MHV diagnostic purposes.

Sequence analysis of the membrane protein gene of human coronavirus 229E

Human coronaviruses (HCV) are ubiquitous pathogens which cause respiratory, gastrointestinal, and possibly neurological disorders. To better understand the molecular biology of the prototype HCV-229E strain, the complete nucleotide sequence of the membrane protein (M) gene was determined from cloned cDNA. The open reading frame is preceded by a consensus transcriptional initiation sequence UCUAAACU, identical to the one found upstream of the N gene. The M gene encodes a 225-amino acid polypeptide with a molecular weight (MW) of 25,822, slightly higher than the apparent MW of 19,000-22,000 observed for the unprocessed M protein obtained after in vitro translation and immunoprecipitation. The M amino acid sequence presents a significant degree of homology (38%) with its counterpart of transmissible gastroenteritis coronavirus (TGEV). The M protein of HCV-229E is highly hydrophobic and its hydropathicity profile shows a transmembranous region composed of three major hydrophobic domains characteristic of a typical coronavirus M protein. About 10% (20 amino acids) of the HCV-229E M protein constitutes a hydrophilic and probably external portion. One N-glycosylation and three potential O-glycosylation sites are found in this exposed domain.

Sequence and analysis of BECV F15 matrix protein

Clones from the bovine enteric coronavirus (F15) cDNA library were cloned in pBR322 and sequenced by the method of Sanger and Coulson. This led to the identification of a sequence of 1,300 bases which contained a single open reading frame of 690 bases yielding a protein having properties of the matrix protein (M). It was comprised of 230 amino acids with a molecular weight of 26,376 Da. It was hydrophobic and had a net charge of +8 at neutral pH. Analysis of its secondary structure could not establish a simple transmembrane arrangement of the amino acids. Comparison of its nucleotide sequence with that of BECV Mebus strain showed only a two-base change resulting in a 100% homology between the two amino acid sequences. Furthermore, a very conserved structure of M appeared on comparison with the Dayoff optimal alignment of MHV-A59, MHV-JHM, TGEV, IBV Beaudette and IBV 6/82M amino acid sequences. As the two strains of BECV, F15 and Mebus present some antigenic differences, this led us to reconsider the role of M in viral antigen specificity. A hypothesis is that, as it seems to possess the necessary information on its transmembrane region, it is an ideal candidate for the viral budding process.

Nucleotide sequence of the gene encoding the membrane protein of human coronavirus 229 E

The sequence of the gene encoding the membrane protein of human coronavirus 229 E (HCV 229 E) has been determined. The primary translation product, deduced from the DNA sequence, is a polypeptide of 225 amino acids with a predicted molecular weight of 26,000. The polypeptide has 3 potential N-glycosylation sites. Many structural similarities with the membrane proteins of other coronaviruses can be recognized.

Discontinuous transcription generates heterogeneity at the leader fusion sites of coronavirus mRNAs

Coronavirus mRNA is synthesized by a discontinuous transcription process, which involves a free leader RNA species. As a result, each virus-specific mRNA contains an identical leader RNA derived from the 5', end of the genomic RNA. In this study, we demonstrate by primer extension studies that the leader-fusion sites on a given species of coronavirus subgenomic mRNA are heterogeneous. The heterogeneity was due to variation in the number of pentanucleotide (UCUAA) repeats present at the leader fusion site. This pentanucleotide repeat region was complementary between the free leader RNA and the transcription start sites on the template RNA. This result suggests that the discontinuous transcription of coronavirus mRNAs occurs within the complementary sequences localized in two different RNA segments and that RNA joining occurs at variable sites.

The integral membrane protein from a virulent isolate of transmissible gastroenteritis virus: molecular characterization, sequence and expression in Escherichia coli

Subgenomic mRNA from a virulent isolate of porcine transmissible gastroenteritis virus (TGEV) was used to produce cDNA clones. Part of a new clone and a previously reported clone were sequenced and used to construct the viral gene for integral membrane protein. A single open reading frame (ORF) encoding a polypeptide of 262 amino acids, relative molecular mass (Mr) 29,459, was identified. The positive identification of the polypeptide as the integral membrane protein was demonstrated by the production in E. coli of a chimaeric protein comprising most of the ORF encoding the Mr 29,459 polypeptide and beta-galactosidase. The chimaeric protein reacted with a specific monoclonal antibody to viral integral membrane protein and antibodies raised against the chimaeric protein immune precipitated the viral protein. Comparison with the sequence of an avirulent isolate indicates amino acid residues that may be important in pathogenicity.

Primary structure of the glycoprotein E2 of coronavirus MHV-A59 and identification of the trypsin cleavage site

The nucleotide sequence of the peplomer (E2) gene of MHV-A59 was determined from a set of overlapping cDNA clones. The E2 gene encodes a protein of 1324 amino acids including a hydrophobic signal peptide. A second large hydrophobic domain is found near the COOH terminus and probably represents the membrane anchor. Twenty glycosylation sites are predicted. Cleavage of the E2 protein results in two different 90K species, 90A and 90B (L.S. Sturman, C. S. Ricard, and K. V. Holmes (1985) J. Virol. 56, 904-911), and activates cell fusion. Protein sequencing of the trypsin-generated N-terminus revealed the position of the cleavage site. 90A and 90B could be identified as the C-terminal and the N-terminal parts, respectively. Amino acid sequence comparison of the A59 and JHM E2 proteins showed extensive homology and revealed a stretch of 89 amino acids in the 90B region of the A59 E2 protein that is absent in JHM.