Evolution of the 5'-end of genomic RNA of murine coronaviruses during passages in vitro

Reselection of a genomic upstream open reading frame in mouse hepatitis coronavirus 5'-untranslated-region mutants

An AUG-initiated upstream open reading frame (uORF) encoding a potential polypeptide of 3 to 13 amino acids (aa) is found within the 5' untranslated region (UTR) of >75% of coronavirus genomes based on 38 reference strains. Potential CUG-initiated uORFs are also found in many strains. The AUG-initiated uORF is presumably translated following genomic 5'-end cap-dependent ribosomal scanning, but its function is unknown. Here, in a reverse-genetics study with mouse hepatitis coronavirus, the following were observed. (i) When the uORF AUG-initiating codon was replaced with a UAG stop codon along with a U112A mutation to maintain a uORF-harboring stem-loop 4 structure, an unimpaired virus with wild-type (WT) growth kinetics was recovered. However, reversion was found at all mutated sites within five virus passages. (ii) When the uORF was fused with genomic (main) ORF1 by converting three in-frame stop codons to nonstop codons, a uORF-ORF1 fusion protein was made, and virus replicated at WT levels. However, a frameshifting G insertion at virus passage 7 established a slightly 5'-extended original uORF. (iii) When uAUG-eliminating deletions of 20, 30, or 51 nucleotides (nt) were made within stem-loop 4, viable but debilitated virus was recovered. However, a C80U mutation in the first mutant and an A77G mutation in the second appeared by passage 10, which generated alternate uORFs that correlated with restored WT growth kinetics. In vitro, the uORF-disrupting nondeletion mutants showed enhanced translation of the downstream ORF1 compared with the WT. These results together suggest that the uORF represses ORF1 translation yet plays a beneficial but nonessential role in coronavirus replication in cell culture.

Genetic evidence of a long-range RNA-RNA interaction between the genomic 5' untranslated region and the nonstructural protein 1 coding region in murine and bovine coronaviruses

Higher-order RNA structures in the 5' untranslated regions (UTRs) of the mouse hepatitis coronavirus (MHV) and bovine coronavirus (BCoV), separate species in the betacoronavirus genus, appear to be largely conserved despite an ∼36% nucleotide sequence divergence. In a previous study, each of three 5'-end-proximal cis-acting stem-loop domains in the BCoV genome, I/II, III, and IV, yielded near-wild-type (wt) MHV phenotypes when used by reverse genetics to replace its counterpart in the MHV genome. Replacement with the BCoV 32-nucleotide (nt) inter-stem-loop fourth domain between stem-loops III and IV, however, required blind cell passaging for virus recovery. Here, we describe suppressor mutations within the transplanted BCoV 32-nt domain that along with appearance of potential base pairings identify an RNA-RNA interaction between this domain and a 32-nt region ∼200 nt downstream within the nonstructural protein 1 (Nsp1)-coding region. Mfold and phylogenetic covariation patterns among similarly grouped betacoronaviruses support this interaction, as does cotransplantation of the BCoV 5' UTR and its downstream base-pairing domain. Interestingly, cotransplantation of the BCoV 5' UTR and BCoV Nsp1 coding region directly yielded an MHV wt-like phenotype, which demonstrates a cognate interaction between these two BCoV regions, which in the MHV genome act in a fully interspecies-compliant manner. Surprisingly, the 30-nt inter-stem-loop domain in the MHV genome can be deleted and viral progeny, although debilitated, are still produced. These results together identify a previously undescribed long-range RNA-RNA interaction between the 5' UTR and Nsp1 coding region in MHV-like and BCoV-like betacoronaviruses that is cis acting for viral fitness but is not absolutely required for viral replication in cell culture.

Mouse hepatitis virus stem-loop 4 functions as a spacer element required to drive subgenomic RNA synthesis

The 5' 140 nucleotides of the mouse hepatitis virus (MHV) 5' untranslated region (5'UTR) are predicted to contain three secondary structures, stem-loop 1 (SL1), SL2, and SL4. SL1 and SL2 are required for subgenomic RNA synthesis. The current study focuses on SL4, which contains two base-paired regions, SL4a and SL4b. A series of reverse genetic experiments show that SL4a is not required to be base paired. Neither the structure, the sequence, nor the putative 8-amino-acid open reading frame (ORF) in SL4b is required for viral replication. Viruses containing separate deletions of SL4a and SL4b are viable. However, deletion of SL4 is lethal, and genomes carrying this deletion are defective in directing subgenomic RNA synthesis. Deletion of (131)ACA(133) just 3' to SL4 has a profound impact on viral replication. Viruses carrying the (131)ACA(133) deletion were heterogeneous in plaque size. We isolated three viruses with second-site mutations in the 5'UTR which compensated for decreased plaque sizes, delayed growth kinetics, and lower titers associated with the (131)ACA(133) deletion. The second-site mutations are predicted to change either the spacing between SL1 and SL2 or that between SL2 and SL4 or to destabilize the proximal portion of SL4a in our model. A mutant constructed by replacing SL4 with a shorter sequence-unrelated stem-loop was viable. These results suggest that the proposed SL4 in the MHV 5'UTR functions in part as a spacer element that orients SL1, SL2, and the transcriptional regulatory sequence (TRS), and this spacer function may play an important role in directing subgenomic RNA synthesis.

5'-proximal hot spot for an inducible positive-to-negative-strand template switch by coronavirus RNA-dependent RNA polymerase

Coronaviruses have a positive-strand RNA genome and replicate through the use of a 3' nested set of subgenomic mRNAs each possessing a leader (65 to 90 nucleotides [nt] in length, depending on the viral species) identical to and derived from the genomic leader. One widely supported model for leader acquisition states that a template switch takes place during the generation of negative-strand antileader-containing templates used subsequently for subgenomic mRNA synthesis. In this process, the switch is largely driven by canonical heptameric donor sequences at intergenic sites on the genome that match an acceptor sequence at the 3' end of the genomic leader. With experimentally placed 22-nt-long donor sequences within a bovine coronavirus defective interfering (DI) RNA we have shown that matching sites occurring anywhere within a 65-nt-wide 5'-proximal genomic acceptor hot spot (nt 33 through 97) can be used for production of templates for subgenomic mRNA synthesis from the DI RNA. Here we report that with the same experimental approach, template switches can be induced in trans from an internal site in the DI RNA to the negative-strand antigenome of the helper virus. For these, a 3'-proximal 89-nt acceptor hot spot on the viral antigenome (nt 35 through 123), largely complementary to that described above, was found. Molecules resulting from these switches were not templates for subgenomic mRNA synthesis but, rather, ambisense chimeras potentially exceeding the viral genome in length. The results suggest the existence of a coronavirus 5'-proximal partially double-stranded template switch-facilitating structure of discrete width that contains both the viral genome and antigenome.

Induction of transcription factor Egr-1 gene expression in astrocytoma cells by Murine coronavirus infection

Mouse hepatitis virus (MHV) causes encephalitis and demyelination in the central nervous system (CNS) of susceptible rodents. Astrocytes are one of the major targets for MHV infection in the CNS, and respond to MHV infection by expressing diverse molecules that may contribute to CNS pathogenesis. Here we characterized the activation of an immediate-early transcription factor Egr-1 by MHV infection in an astrocytoma cell line. We found that the expression of Egr-1 was dramatically increased following virus infection. Using various inhibitors of mitogen-activated protein kinases, we identified that the extracellular signal-regulated kinases 1/2 were involved in the activation of Egr-1 transcription by MHV infection. Experiments with ultraviolet light-inactivated virus revealed that the induction of Egr-1 did not require virus replication and was likely mediated during cell entry. We further found that over-expression of Egr-1 suppressed the expression of BNip3, a pro-apoptotic member of the Bcl-2 family. This finding may provide an explanation for our previously observed down-regulation of BNip3 by MHV infection in astrocytoma cells (Cai, Liu, Yu, and Zhang, Virology 316:104-115, 2003). Furthermore, knockdown of Egr-1 by an siRNA inhibited MHV propagation, suggesting the biological relevance of Egr-1 induction to virus replication. In addition, the persistence/demylinating-positive strains (JHM and A59) induced Egr-1 expression, whereas the persistence/demylinating-negative strain (MHV-2) did not. These results indicate a correlation between the ability of MHVs to induce Egr-1 expression and their ability to cause demyelination in the CNS, which may suggest a potential role for the induction of Egr-1 in viral pathogenesis.

Suppression of coronavirus replication by inhibition of the MEK signaling pathway

We previously demonstrated that infection of cultured cells with murine coronavirus mouse hepatitis virus (MHV) resulted in activation of the mitogen-activated protein kinase (Raf/MEK/ERK) signal transduction pathway (Y. Cai et al., Virology 355:152-163, 2006). Here we show that inhibition of the Raf/MEK/ERK signaling pathway by the MEK inhibitor UO126 significantly impaired MHV progeny production (a reduction of 95 to 99% in virus titer), which correlated with the phosphorylation status of ERK1/2. Moreover, knockdown of MEK1/2 and ERK1/2 by small interfering RNAs suppressed MHV replication. The inhibitory effect of UO126 on MHV production appeared to be a general phenomenon since the effect was consistently observed in all six different MHV strains and in three different cell types tested; it was likely exerted at the postentry steps of the virus life cycle because the virus titers were similarly inhibited from infected cells treated at 1 h prior to, during, or after infection. Furthermore, the treatment did not affect the virus entry, as revealed by the virus internalization assay. Metabolic labeling and reporter gene assays demonstrated that translation of cellular and viral mRNAs appeared unaffected by UO126 treatment. However, synthesis of viral genomic and subgenomic RNAs was severely suppressed by UO126 treatment, as demonstrated by a reduced incorporation of [3H]uridine and a decrease in chloramphenicol acetyltransferase (CAT) activity in a defective-interfering RNA-CAT reporter assay. These findings indicate that the Raf/MEK/ERK signaling pathway is involved in MHV RNA synthesis.

Down-regulation of transcription of the proapoptotic gene BNip3 in cultured astrocytes by murine coronavirus infection

Murine coronavirus mouse hepatitis virus (MHV) causes encephalitis and demyelination in the central nervous system of susceptible rodents. Astrocytes are the major target for MHV persistence. However, the mechanisms by which astrocytes survive MHV infection and permit viral persistence are not known. Here we performed DNA microarray analysis on differential gene expression in astrocyte DBT cells by MHV infection and found that the mRNA of the proapoptotic gene BNip3 was significantly decreased following MHV infection. This finding was further confirmed by quantitative reverse transcription-polymerase chain reaction, Western blot analysis, and BNip3-promoter-luciferase reporter system. Interestingly, infection with live and ultraviolet light-inactivated viruses equally repressed BNip3 expression, indicating that the down-regulation of BNip3 expression does not require virus replication and is mediated during cell entry. Furthermore, treatment of cells with chloroquine, which blocks the acidification of endosomes, significantly inhibited the repression of the BNip3 promoter activity induced by the acidic pH-dependent MHV mutant OBLV60, which enters cells via endocytosis, indicating that the down-regulation of BNip3 expression is mediated by fusion between viral envelope and cell membranes during entry. Deletion analysis showed that the sequence between nucleotides 262 and 550 of the 588-base-pair BNip3 promoter is necessary and sufficient for driving the BNip3 expression and that it contains signals that are responsible for MHV-induced down-regulation of BNip3 expression in DBT cells. These results may provide insights into the mechanisms by which MHV evades host antiviral defense and promotes cell survival, thereby allowing its persistence in the host astrocytes.

Recombination and Coronavirus Defective Interfering RNAs

Naturally occurring defective interfering RNAs have been found in 4 of 14 coronavirus species. They range in size from 2.2 kb to approximately 25 kb, or 80% of the 30-kb parent virus genome. The large DI RNAs do not in all cases appear to require helper virus for intracellular replication and it has been postulated that they may on their own function as agents of disease. Coronavirus DI RNAs appear to arise by internal deletions (through nonhomologous recombination events) on the virus genome or on DI RNAs of larger size by a polymerase strand-switching (copy-choice) mechanism. In addition to their use in the study of virus RNA replication and virus assembly, coronavirus DI RNAs are being used in a major way to study the mechanism of a high-frequency, site-specific RNA recombination event that leads to leader acquisition during virus replication (i.e., the leader fusion event that occurs during synthesis of subgenomic mRNAs, and the leader-switching event that can occur during DI RNA replication), a distinguishing feature of coronaviruses (and arteriviruses). Coronavirus DI RNAs are also being engineered as vehicles for the generation of targeted recombinants of the parent virus genome.

Enhanced accumulation of coronavirus defective interfering RNA from expressed negative-strand transcripts by coexpressed positive-strand RNA transcripts

Expression of negative-strand murine coronavirus mouse hepatitis virus (MHV) defective interfering (DI) RNA transcripts in MHV-infected cells results in the accumulation of positive-strand DI RNAs (M. Joo et al., 1996, J. Virol. 70, 5769-5776). However, the expressed negative-strand DI RNA transcripts are poor templates for positive-strand DI RNA synthesis. The present study demonstrated that DI RNA accumulation from the expressed negative-strand DI RNA transcripts in MHV-infected cells was enhanced by the coexpression of complementary RNA transcripts that correspond to the 5' region of positive-strand DI RNA. The positive-strand RNA transcripts corresponding to the 5' end-most 0.7-2.0 kb DI RNA had a similar enhancement effect. The coexpressed positive-strand RNA transcripts lacking the leader sequence or those containing only the leader sequence failed to demonstrate this enhancement effect, demonstrating that the presence of the leader sequence in the coexpressed positive-strand RNA transcripts was necessary, but not sufficient, for the enhancement of DI RNA accumulation from the coexpressed negative-strand DI RNA transcripts. Negative-strand DI RNA transcripts that were coexpressed with the partial-length positive-strand RNA transcripts were no more stable than those expressed alone, suggesting that a higher stability of the expressed negative-strand RNA transcripts was an unlikely reason for the higher DI RNA accumulation in cells coexpressing two complementary DI RNA transcripts. Sequence analyses unexpectedly demonstrated that the leader sequence of the majority of accumulated DI RNAs switched to helper virus derived leader sequence, suggesting that enhancement of DI RNA accumulation was mediated by the efficient utilization of helper virus derived leader sequence for DI RNA synthesis. Furthermore, our data suggested that this leader switching, a type of homologous RNA-RNA recombination, occurred during positive-strand DI RNA synthesis and that MHV positive-strand RNA synthesis mechanism may have a preference toward recognizing double-stranded RNA structures over single-stranded negative-strand RNA to produce positive-strand DI RNAs.

Identification of a noncanonical signal for transcription of a novel subgenomic mRNA of mouse hepatitis virus: implication for the mechanism of coronavirus RNA transcription

Subgenomic RNA transcription of coronaviruses involves the interaction between the leader (or antileader) and the intergenic (IG) sequences. However, it is not clear how these two sequences interact with each other. In this report, a previously unrecognized minor species of subgenomic mRNA, termed mRNA5-1, was identified in cells infected with mouse hepatitis virus (MHV) strains JHM2c, JHM(2), JHM(3), A59, and MHV-1. Sequence analysis revealed that the leader-body fusion site of the mRNA is located at approximately 150 nucleotides (nt) downstream of the consensus IG sequence for mRNA 5 and did not have sequence homology with any known IG consensus sequences. To determine whether this sequence functions independently as a promoter, we cloned a 140-nt sequence (from approximately 70 nt upstream to approximately 70 nt downstream of the fusion site) from viral genomic RNA and placed it in front of a reporter gene in the defective-interfering (DI) RNA-chloramphenicol acetyltransferase (CAT) reporter vector. Transfection of the reporter RNA into MHV-infected cells resulted in synthesis of a CAT-specific subgenomic mRNA detected by reverse transcription-polymerase chain reaction (RT-PCR). The strength of this promoter was similar to that of the IG7 (for mRNA 7) as measured by the CAT activity. Deletion analysis showed that the sequence as few as 13 nt was sufficient to initiate mRNA transcription, while mutations within the 13-nt abolished mRNA transcription. In vitro translation study confirmed that the envelope (E) protein was translated from mRNA5-1, which encodes the open reading frame (ORF) 5b at its 5'-end, indicating that mRNA5-1 is a functional message. Furthermore, when the ORF5b was replaced with the CAT gene and placed in the DI in the context of viral mini-genome, CAT was expressed not only from the first ORF of mRNA5-1 but also from the second and third ORF of mRNA5 and genomic DI RNA, respectively, suggesting that more than one mechanism is involved in regulation of ORF5b expression. Our findings thus support the notion that base-pairing between the leader (or antileader) and the IG is not the sole mechanism in subgenomic RNA transcription.

The leader RNA of coronavirus mouse hepatitis virus contains an enhancer-like element for subgenomic mRNA transcription

While the 5' cis-acting sequence of mouse hepatitis virus (MHV) for genomic RNA replication has been determined in several defective interfering (DI) RNA systems, it remains elusive for subgenomic RNA transcription. Previous studies have shown that the leader RNA in the DI genome significantly enhances the efficiency of DI subgenomic mRNA transcription, indicating that the leader RNA is a cis-acting sequence for mRNA transcription. To further characterize the cis-acting sequence, we made a series of deletion mutants, all but one of which have an additional deletion of the cis-acting signal for replication in the 5' untranslated region. This deletion effectively eliminated the replication of the DI-chloramphenicol acetyltransferase (CAT)-reporter, as demonstrated by the sensitive reverse transcription (RT)-PCR. The ability of these replication-minus mutants to transcribe subgenomic mRNAs was then assessed using the DI RNA-CAT reporter system. Results from both CAT activity and mRNA transcripts detected by RT-PCR showed that a 5'-proximal sequence of 35 nucleotides (nt) at nt 25 to 59 is a cis-acting sequence required for subgenomic RNA transcription, while the consensus repeat sequence of the leader RNA does not have such effect. Analyses of the secondary structure indicate that this 35-nt sequence forms two stem-loops conserved among MHVs. Deletion of this sequence abrogated transcriptional activity and disrupted the predicted stem-loops and overall RNA secondary structure at the 5' untranslated region, suggesting that the secondary structure formed by this 35-nt sequence may facilitate the downstream consensus sequence accessible for the discontinuous RNA transcription. This may provide a mechanism by which the 5' cis-acting sequence regulates subgenomic RNA transcription. The 5'-most 24 nt are not essential for transcription, while the 9 nt immediately downstream of the leader enhances RNA transcription. The sequence between nt 86 and 135 had little effect on transcription. This study thus defines the cis-acting transcription signal at the 5' end of the DI genome.

The nucleocapsid protein of coronavirus mouse hepatitis virus interacts with the cellular heterogeneous nuclear ribonucleoprotein A1 in vitro and in vivo

The nucleocapsid (N) protein of mouse hepatitis virus (MHV) and the cellular heterogeneous nuclear ribonucleoprotein A1 (hnRNP-A1) are RNA-binding proteins, binding to the leader RNA and the intergenic sequence of MHV negative-strand template RNAs, respectively. Previous studies have suggested a role for both N and hnRNP-A1 proteins in MHV RNA synthesis. However, it is not known whether the two proteins can interact with each other. Here we employed a series of methods to determine their interactions both in vitro and in vivo. Both N and hnRNP-A1 genes were cloned and expressed in Escherichia coli as glutathione S-transferase (GST) fusion proteins, and their interactions were determined with a GST-binding assay. Results showed that N protein directly and specifically interacted with hnRNP-A1 in vitro. To dissect the protein-binding domain on the N protein, 15 deletion constructs were made by PCR and expressed as GST fusion proteins. Two hnRNP-A1-binding sites were identified on N protein: site A is located at amino acids 1 to 292 and site B at amino acids 392 to 455. In addition, we found that N protein interacted with itself and that the self-interacting domain coincided with site A but not with site B. Using a fluorescence double-staining technique, we showed that N protein colocalized with hnRNP-A1 in the cytoplasm, particularly in the perinuclear region, of MHV-infected cells, where viral RNA replication/transcription occurs. The N protein and hnRNP-A1 were coimmunoprecipitated from the lysates of MHV-infected cells either by an N- or by an hnRNP-A1-specific monoclonal antibody, indicating a physical interaction between N and hnRNP-A1 proteins. Furthermore, using the yeast two-hybrid system, we showed that N protein interacted with hnRNP-A1 in vivo. These results thus establish that MHV N protein interacts with hnRNP-A1 both in vitro and in vivo.

Formation of a ribonucleoprotein complex of mouse hepatitis virus involving heterogeneous nuclear ribonucleoprotein A1 and transcription-regulatory elements of viral RNA

The heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1) specifically binds to two transcription-regulatory elements, i.e., the leader and intergenic sequence, of the negative-strand (template-strand) RNA of mouse hepatitis virus (MHV) and may play a role in viral RNA transcription. Previous studies based on the defective-interfering RNAs of MHV suggested that these two RNA elements may interact with each other during transcription, although they do not have complementary sequences. In this study, we showed by an in vitro reconstitution assay that hnRNP A1 could mediate the formation of an RNP complex involving these two RNA elements. Both the RNA-binding domains and protein-interacting domain of hnRNP A1 contributed to the efficient formation of the RNP complex; however, the presence of the two RNA-binding domains alone, without the protein-interacting domain, also resulted in some RNP formation. Omission of hnRNP A1 in the reconstitution reaction abolished the RNP formation, and mutations of the IG sequences significantly inhibited the RNP formation. These findings suggest that the two cis-acting transcription-regulatory sequences of MHV RNA can interact with each other through the formation of an RNP complex involving a cellular protein hnRNP A1. This RNP complex may participate in MHV RNA transcription.

Occurrence and structure-function relationship of pentameric short sequence repeats in microbial genomes

It is suggested that genomes found in any form of cellular life contain potentially size-variable repetitive DNA moieties. In eukaryotes, large proportions of the multi-chromosomal genome consist of various classes of repetitive DNA. Also in archaeal genomes, repetitive DNA is encountered and, as is the case for the eukaryotes as well, little or no function is at present attributable to most of it. For prokaryotes, elegant experiments have highlighted so-called slipped strand nucleotide mispairing (SSM) as a basic and causal mechanism, giving rise to repeat unit number variation at a distinct locus. Illegitimate base pairing in regions of repetitive DNA during replication, in association with defective DNA repair and enhanced nuclease susceptibility of replication intermediates, in the end gives rise to deletion or addition of repeat units. Prokaryotic short sequence repeats (SSRs) harbour arrays of short repeat units, between one and approximately 20 nucleotides in length. SSRs are involved in various mechanisms of microbial gene expression regulation. Promoter strength can be affected by altering the spacing between important structural domains as can the integrity of open reading frames. In the present communication the literature on microbial SSRs harbouring repeat units that are five nucleotides in length will be briefly reviewed. Examples of these SSRs with discrete functionality are encountered in bacterial species such as Haemophilus influenzae, Neisseria gonorrhoeae, and Pasteurella haemolytica. In addition, several of the currently known bacterial and archaeal whole genome sequences were scanned for the presence of novel examples of potential five-nucleotide SSRs (and others) in order to gather additional knowledge on the propensity and putative functions of this type of potential genetic switch.

The hemagglutinin-esterase of mouse hepatitis virus strain S is a sialate-4-O-acetylesterase

By comparative analysis of the hemagglutinin-esterase (HE) protein of mouse hepatitis virus strain S (MHV-S) and the HE protein of influenza C virus, we found major differences in substrate specificities. In striking contrast to the influenza C virus enzyme, the MHV-S esterase was unable to release acetate from bovine submandibulary gland mucin. Furthermore, MHV-S could not remove influenza C virus receptors from erythrocytes. Analysis with free sialic acid derivatives revealed that the MHV-S HE protein specifically de-O-acetylates 5-N-acetyl-4-O-acetyl sialic acid (Neu4, 5Ac2) but not 5-N-acetyl-9-O-acetyl sialic acid (Neu5,9Ac2), which is the major substrate for esterases of influenza C virus and bovine coronaviruses. In addition, the MHV-S esterase converted glycosidically bound Neu4,5Ac2 of guinea pig serum glycoproteins to Neu5Ac. By expression of the MHV esterase with recombinant vaccinia virus and incubation with guinea pig serum, we demonstrated that the viral HE possesses sialate-4-O-acetylesterase activity. In addition to observed enzymatic activity, MHV-S exhibited affinity to guinea pig and horse serum glycoproteins. Binding required sialate-4-O-acetyl groups and was abolished by chemical de-O-acetylation. Since Neu4,5Ac2 has not been identified in mice, the nature of potential substrates and/or secondary receptors for MHV-S in the natural host remains to be determined. The esterase of MHV-S is the first example of a viral enzyme with high specificity and affinity toward 4-O-acetylated sialic acids.

Polypyrimidine tract-binding protein binds to the leader RNA of mouse hepatitis virus and serves as a regulator of viral transcription

A cellular protein, previously described as p55, binds specifically to the plus strand of the mouse hepatitis virus (MHV) leader RNA. We have purified this protein and determined by partial peptide sequencing that it is polypyrimidine tract-binding protein (PTB) (also known as heterogeneous nuclear ribonucleoprotein [hnRNP] I), a nuclear protein which shuttles between the nucleus and cytoplasm. PTB plays a role in the regulation of alternative splicing of pre-mRNAs in normal cells and translation of several viruses. By UV cross-linking and immunoprecipitation studies using cellular extracts and a recombinant PTB, we have established that PTB binds to the MHV plus-strand leader RNA specifically. Deletion analyses of the leader RNA mapped the PTB-binding site to the UCUAA pentanucleotide repeats. Using a defective-interfering RNA reporter system, we have further shown that the PTB-binding site in the leader RNA is critical for MHV RNA synthesis. This and our previous study (H.-P. Li, X. Zhang, R. Duncan, L. Comai, and M. M. C. Lai, Proc. Natl. Acad. Sci. USA 94:9544-9549, 1997) combined thus show that two cellular hnRNPs, PTB and hnRNP A1, bind to the transcription-regulatory sequences of MHV RNA and may participate in its transcription.

Characterizations of coronavirus cis-acting RNA elements and the transcription step affecting its transcription efficiency

Seven to eight species of viral subgenomic mRNAs are produced in coronavirus-infected cells. These mRNAs are produced in different quantities, and their molar ratios remain constant during viral replication. We studied RNA elements that affect coronavirus transcription efficiency by characterizing a series of cloned coronavirus mouse hepatitis virus (MHV) defective interfering (DI) RNAs containing an inserted intergenic sequence, from which subgenomic DI RNA is transcribed in MHV-infected cells. Certain combinations of upstream and downstream flanking sequences of the intergenic sequence suppressed subgenomic DI RNA transcription, yet changing one of the flanking sequences to a different sequence eliminated transcription suppression. The suppressive effect of certain combinations of flanking sequences, but not all combinations, could be counteracted by altering the intergenic sequence. Thus, the combination of intergenic sequence and flanking sequence affected transcription efficiency. We also characterized another set of DI RNAs designed to clarify which transcription step determines the relative molar ratios of coronavirus mRNAs. Our study indicated that if subgenomic mRNAs were exclusively synthesized from negative-strand genomic RNA, then the relative molar ratios of coronavirus mRNAs were most likely determined after synthesis of the genomic-sized template RNA. If negative-strand subgenomic RNAs were templates for subgenomic mRNAs, then the relative molar ratios of coronavirus mRNAs probably were determined after synthesis of the genomic-sized template RNA used for subgenomic-sized RNA transcription but prior to the completion of the synthesis of subgenomic-sized RNAs containing the leader sequence. The relative molar ratios of coronavirus mRNAs, therefore, seem to have been established prior to a putative replicon-type amplification of subgenomic mRNAs.

Expression of hemagglutinin/esterase by a mouse hepatitis virus coronavirus defective-interfering RNA alters viral pathogenesis

A defective-interfering (DI) RNA of mouse hepatitis virus (MHV) was developed as a vector for expressing MHV hemagglutinin/esterase (HE) protein. The virus containing an expressed HE protein (A59-DE-HE) was generated by infecting cells with MHV-A59, which does not express HE, and transfecting the in vitro-transcribed DI RNA containing the HE gene. A similar virus (A59-DE-CAT) expressing the chloramphenicol acetyltransferase (CAT) was used as a control. These viruses were inoculated intracerebrally into mice, and the role of the HE protein in viral pathogenesis was evaluated. Results showed that all mice infected with parental A59 or A59-DE-CAT succumbed to infection by 9 days postinfection (p.i.), demonstrating that inclusion of the DI did not by itself alter pathogenesis. In contrast, 60% of mice infected with A59-DE-HE survived infection. HE- or CAT-specific subgenomic mRNAs were detected in the brains at days 1 and 2 p.i. but not later, indicating that the genes in the DI vector were expressed only in the early stage of viral infection. No significant difference in virus titer or viral antigen expression in brains was observed between A59-DE-HE- and A59-DE-CAT-infected mice, suggesting that virus replication in brain was not affected by the expression of HE. However, at day 3 p.i. there was a slight increase in the extent of inflammatory cell infiltration in the brains of the A59-DE-HE-infected mice. Surprisingly, virus titers in the livers of A59-DE-HE-infected mice were 3 log10 lower than that of the A59-DE-CAT-infected mice at day 6 p.i. Also, substantially less necrosis and viral antigen were detected in the livers of the A59-DE-HE-infected mice. This may account for the reduced mortality of these mice. The possible contribution of the host immune system to this difference in pathogenesis was analyzed by comparing the expression of four cytokines. Results showed that both tumor necrosis factor-alpha and interleukin-6 mRNAs increased in the brains of the A59-DE-HE-infected mice at day 2 p.i., whereas interferon-gamma and interleukin-1 alpha mRNAs were similar between A59-DE-HE- and A59-DE-CAT-infected mice. These data suggest that the transient expression of HE protein enhances an early innate immune response, possibly contributing to the eventual clearance of virus from the liver. This study indicates the feasibility of the DI expression system for studying roles of viral proteins during MHV infection.

The molecular biology of coronaviruses

This chapter discusses the manipulation of clones of coronavirus and of complementary DNAs (cDNAs) of defective-interfering (DI) RNAs to study coronavirus RNA replication, transcription, recombination, processing and transport of proteins, virion assembly, identification of cell receptors for coronaviruses, and processing of the polymerase. The nature of the coronavirus genome is nonsegmented, single-stranded, and positive-sense RNA. Its size ranges from 27 to 32 kb, which is significantly larger when compared with other RNA viruses. The gene encoding the large surface glycoprotein is up to 4.4 kb, encoding an imposing trimeric, highly glycosylated protein. This soars some 20 nm above the virion envelope, giving the virus the appearance-with a little imagination-of a crown or coronet. Coronavirus research has contributed to the understanding of many aspects of molecular biology in general, such as the mechanism of RNA synthesis, translational control, and protein transport and processing. It remains a treasure capable of generating unexpected insights.

RNA-protein interactions in the regulation of coronavirus RNA replication and transcription

Coronavirus, with a 31-kb RNA genome, replicates its own RNA and transcribes subgenomic mRNAs by complex mechanisms. Viral RNA synthesis is regulated by multiple RNA regions, which appear to interact either directly or indirectly. Multiple cellular proteins bind to these regions and may undergo additional protein-protein interactions. These findings suggest that coronavirus RNA synthesis is carried out on a ribonucleoprotein via a mechanism that involves both viral and cellular proteins associated with viral RNA, similar to DNA-dependent RNA transcription. This mode of RNA synthesis may be applicable to most RNA viruses.

The molecular biology of coronaviruses

This chapter discusses the manipulation of clones of coronavirus and of complementary DNAs (cDNAs) of defective-interfering (DI) RNAs to study coronavirus RNA replication, transcription, recombination, processing and transport of proteins, virion assembly, identification of cell receptors for coronaviruses, and processing of the polymerase. The nature of the coronavirus genome is nonsegmented, single-stranded, and positive-sense RNA. Its size ranges from 27 to 32 kb, which is significantly larger when compared with other RNA viruses. The gene encoding the large surface glycoprotein is up to 4.4 kb, encoding an imposing trimeric, highly glycosylated protein. This soars some 20 nm above the virion envelope, giving the virus the appearance-with a little imagination-of a crown or coronet. Coronavirus research has contributed to the understanding of many aspects of molecular biology in general, such as the mechanism of RNA synthesis, translational control, and protein transport and processing. It remains a treasure capable of generating unexpected insights.

The UCUAAAC promoter motif is not required for high-frequency leader recombination in bovine coronavirus defective interfering RNA

The 65-nucleotide leader on the cloned bovine coronavirus defective interfering (DI) RNA, when marked by mutations, has been shown to rapidly convert to the wild-type leader of the helper virus following DI RNA transfection into helper virus-infected cells. A model of leader-primed transcription in which free leader supplied in trans by the helper virus interacts by way of its flanking 5'UCUAAAC3' sequence element with the 3'-proximal 3'AGAUUUG5' promoter on the DI RNA minus strand to prime RNA replication has been used to explain this phenomenon. To test this model, the UCUAAAC element which occurs only once in the BCV 5' untranslated region was either deleted or completely substituted in input DI RNA template, and evidence of leader conversion was sought. In both cases, leader conversion occurred rapidly, indicating that this element is not required on input RNA for the conversion event. Substitution mutations mapped the crossover region to a 24-nucleotide segment that begins within the UCUAAAC sequence and extends downstream. Although structure probing of the bovine coronavirus 5' untranslated region indicated that the UCUAAAC element is in the loop of a prominent stem and thus theoretically available for base pair-directed priming, no evidence of an unattached leader early in infection that might have served as a primer for transcription was found by RNase protection studies. These results together suggest that leader conversion on the DI RNA 5' terminus is not guided by the UCUAAAC element and might arise instead from a high-frequency, region-specific, homologous recombination event perhaps during minus-strand synthesis rather than by leader priming during plus-strand synthesis.

A 5'-proximal RNA sequence of murine coronavirus as a potential initiation site for genomic-length mRNA transcription

Coronavirus transcription is a discontinuous process, involving interactions between a trans-acting leader and the intergenic transcription initiation sequences. A 9-nucleotide (nt) sequence (UUUAUAAAC), which is located immediately downstream of the leader at the 5' terminus of the mouse hepatitis virus (MHV) genomic RNA, contains a sequence resembling the consensus intergenic sequence (UCUAAAC). It has been shown previously that the presence of the 9-nt sequence facilitates leader RNA switching and may enhance subgenomic mRNA transcription. It is unclear how the 9-nt sequence exerts these functions. In this study, we inserted the 9-nt sequence into a defective interfering (DI) RNA reporter system and demonstrated that mRNA transcription could be initiated from the 9-nt sequence almost as efficiently as from the intergenic sequence between genes 6 and 7. Sequence analysis of the mRNAs showed that the 9-nt sequence served as a site of fusion between the leaders and mRNA. The transcription initiation function of the 9-nt sequence could not be substituted by other 5'-terminal sequences. When the entire 5'-terminal sequence, including four copies of the UCUAA sequence plus the 9-nt sequence, was present, transcription could be initiated from any of the UCUAA copies or the 9-nt sequence, resulting in different copy numbers of the UCUAA sequence and the deletion of the 9-nt sequence in some mRNAs. All of these heterogeneous RNA species were also detected from the 5'-terminal region of the viral genomic-length RNA in MHV-infected cells. These results thus suggest tha the heterogeneity of the copy number of UCUAA sequences at the 5' end, the deletion of the 9-nt sequence in viral and DI RNAs, and the leader RNA switching are the results of transcriptional initiation from the 9-nt site. They also show that an mRNA species (mRNA 1) that lacks the 9-nt sequence can be synthesized during MHV infection. Therefore, MHV genomic RNA replication and mRNA 1 transcription may be distinguishable.

Interaction of mouse hepatitis virus (MHV) spike glycoprotein with receptor glycoprotein MHVR is required for infection with an MHV strain that expresses the hemagglutinin-esterase glycoprotein

In addition to the spike (S) glycoprotein that binds to carcinoembryonic antigen-related receptors on the host cell membrane, some strains of mouse coronavirus (mouse hepatitis virus [MHV]) express a hemagglutinin esterase (HE) glycoprotein with hemagglutinating and acetylesterase activity. Virions of strains that do not express HE, such as MHV-A59, can infect mouse fibroblasts in vitro, showing that the HE glycoprotein is not required for infection of these cells. The present work was done to study whether interaction of the HE glycoprotein with carbohydrate moieties could lead to virus entry and infection in the absence of interaction of the S glycoprotein with its receptor glycoprotein, MHVR. The DVIM strain of MHV expresses large amounts of HE glycoprotein, as shown by hemadsorption, acetylesterase activity, and immunoreactivity with antibodies directed against the HE glycoprotein of bovine coronavirus. A monoclonal anti-MHVR antibody, MAb-CC1, blocks binding of virus S glycoprotein to MHVR and blocks infection of MHV strains that do not express HE. MAb-CC1 also prevented MHV-DVIM infection of mouse DBT cells and primary mouse glial cell cultures. Although MDCK-I cells express O-acetylated sialic acid residues on their plasma membranes, these canine cells were resistant to infection with MHV-A59 and MHV-DVIM. Transfection of MDCK-I cells with MHVR cDNA made them susceptible to infection with MHV-A59 and MHV-DVIM. Thus, the HE glycoprotein of an MHV strain did not lead to infection of cultured murine neural cells or of nonmurine cells that express the carbohydrate ligand of the HE glycoprotein. Therefore, interaction of the spike glycoprotein of MHV with its carcinoembryonic antigen-related receptor glycoprotein is required for infectivity of MHV strains whether or not they express the HE glycoprotein.

Genetics of mouse hepatitis virus transcription: evidence that subgenomic negative strands are functional templates

Mouse hepatitis virus (MHV) A59 temperature-sensitive (ts) mutants belonging to complementation group C were characterized and mapped by standard genetic recombination techniques. Temperature shift experiments early in infection suggested that the group C allele can be divided into two phenotypically distinct subgroups, designated C1 and C2. Since previous data indicated that the group C1 mutants probably contained an early defect which affects negative-strand synthesis, RNA synthesis was further examined by analyzing replicative-form (RF) RNA. Full-length as well as subgenomic-length RF RNAs were radiolabeled from 3 to 12 h postinfection (p.i.) and labeled late in infection after shift to the nonpermissive temperature (39.5 degrees C). The relative percent molar ratios of each mRNA and corresponding RF RNA were roughly equivalent throughout infection. Temperature shift experiments at 5.5 or 6.0 h p.i. resulted in an 83 to 92% reduction in the amount of total RF RNA at 39.5 degrees C. Radiolabeling time course experiments after temperature shift to 39.5 degrees C also demonstrated incorporation (6 to 9 h p.i.) into both subgenomic-length and full-length RF RNAs, suggesting that previously transcribed negative strands were functional templates throughout infection. To determine if the reduction in RF RNA was due to a decrease in positive- or negative-strand RNA synthesis, rates of mRNA synthesis were calculated from both full-length and subgenomic-length templates. The rate of mRNA synthesis after the shift was increased at 39.5 degrees C compared with that at 32 degrees C regardless of the template used; however, transcription rates calculated from subgenomic-length templates were similar to those of other viral and eukaryotic polymerases. These findings support the notion that the group C1 allele regulates negative-strand RNA synthesis and strongly suggest that the subgenomic negative-strand RNAs are probably the predominant functional templates for the synthesis of positive-strand RNAs late in infection.

Unusual heterogeneity of leader-mRNA fusion in a murine coronavirus: implications for the mechanism of RNA transcription and recombination

Coronavirus mRNA transcription was thought to be regulated by the interaction between the leader RNA and the intergenic sequence (IS), probably involving direct RNA-RNA interactions between complementary sequences. In this study, we found that a particular strain of mouse hepatitis virus, JHM2c, which has a deletion of a 9-nucleotide (nt) sequence (UUUAUAAAC) immediately downstream of the leader RNA, transcribed subgenomic mRNA species containing a whole array of heterogeneous leader fusion sites. Using a transfected defective interfering RNA which contains an IS and a reporter (chloramphenicol acetyltransferase) gene and JHM2c as a helper virus, we demonstrated that subgenomic mRNAs transcribed from the defective interfering RNAs were extremely heterogeneous. The leader-mRNA fusion sites in this virus can be grouped into five types. In type I, the leader is fused with the consensus IS of the template RNA at a site within the UCUAA repeats, consistent with the classical model of discontinuous transcription. In type II, the leader is fused with the consensus IS as in type I, but the leader of mRNA contains some nucleotide substitutions within the UCUAA repeats. In type III, the leader is fused with mRNAs at a site either upstream or downstream of the consensus IS. The sequences around the fusion sites bear little or no homology to the leader. As a result, mRNAs contain sequences complementary to the template sequences upstream of the IS or have sequence deletions downstream of the IS. In type IV, the leader is fused to the IS at the 9-nt sequence immediately downstream of the UCUAA repeats. In type V, the leader-mRNA fusion site contains a duplication of a portion of the leader sequence or an insertion of nontemplated sequences which are not present in either leader or template RNA. These patterns of leader-mRNA fusion resemble the aberrant homologous recombination frequently seen in other RNA viruses. The degree of heterogeneity of leader fusion sites is dependent on the sequences of both the leader RNA and IS. These results suggest that leader-mRNA fusion in coronavirus transcription does not require direct RNA-RNA interaction between complementary sequences. A modified model of RNA transcription and recombination based on protein-RNA and protein-protein interactions is proposed. This study also provides a paradigm for aberrant homologous recombination.

Coronavirus leader RNA regulates and initiates subgenomic mRNA transcription both in trans and in cis

Mouse hepatitis virus (MHV), a coronavirus, utilizes a discontinuous transcription mechanism for subgenomic mRNA synthesis. Previous studies (C.-L. Liao and M. C. C. Lai, J. Virol. 68:4727-4737, 1994) have demonstrated that an upstream cis-acting leader sequence serves as a transcriptional enhancer, but the mechanism of transcriptional regulation is not clear. In this study, we constructed a series of defective interfering (DI) RNAs containing the chloramphenicol acetyltransferase (CAT) gene behind a differentially expressed transcription initiation (intergenic) sequence (for mRNA2-1). These DI RNAs had different copy numbers of the UCUAA pentanucleotide sequence at the 3' end of the leader. Transfection of these DI RNA constructs into cells infected with a helper MHV, which contains either two or three UCUAA copies at the 3' end of the leader, resulted in differential expression of CAT activities. We demonstrated that the copy number of UCUAA repeats in the leaders of both helper viral and DI RNAs affected the level of CAT activity, suggesting that MHV leader RNA could regulate both in trans and in cis the transcription of subgenomic mRNAs. The leader RNA of subgenomic mRNAs was derived from either the trans- or the cis-acting leader. Furthermore, insertion of a UA-rich sequence (UUUAUAAAC) immediately downstream of the leader in DI RNA, to match the sequence of helper viral RNA, enhanced the CAT activity by threefold, suggesting that this nine-nucleotide sequence is a cis-acting element. Interestingly, when the nine-nucleotide sequence was absent in DI RNA, the leaders of subgenomic mRNAs were exclusively derived from the helper virus. In contrast, when the nine-nucleotide sequence was present in DI RNA, the leaders were derived from both helper viral and DI RNAs. These results suggest that the nine-nucleotide sequence either is required for the leader RNA to initiate mRNA synthesis or, alternatively, serves as a transcription terminator for the leader RNA synthesis. However, when a constitutively expressed intergenic sequence (for mRNA7) was used, no difference in transcription efficiency was noted, regardless of the copy number of UCUAA in the DI RNA and helper virus. This study thus indicates that MHV subgenomic RNA transcription requires the interaction among the intergenic (promoter) sequence, a trans-acting leader, and a cis-acting leader sequence. A novel model of transcriptional regulation of coronavirus subgenomic mRNAs is presented.

Evidence for coronavirus discontinuous transcription

Coronavirus subgenomic mRNA possesses a 5'-end leader sequence which is derived from the 5' end of genomic RNA and is linked to the mRNA body sequence. This study examined whether coronavirus transcription involves a discontinuous transcription step; the possibility that a leader sequence from mouse hepatitis virus (MHV) genomic RNA could be used for MHV subgenomic defective interfering (DI) RNA transcription was examined. This was tested by using helper viruses and DI RNAs that were easily distinguishable. MHV JHM variant JHM(2), which synthesizes a subgenomic mRNA encoding the HE gene, and variant JHM(3-9), which does not synthesize this mRNA, were used. An MHV DI RNA, DI(J3-9), was constructed to contain a JHM(3-9)-derived leader sequence and an inserted intergenic region derived from the region preceding the MHV JHM HE gene. DI(J3-9) replicated efficiently in JHM(2)- or JHM(3-9)-infected cells, whereas synthesis of subgenomic DI RNAs was observed only in JHM(2)-infected cells. Sequence analyses demonstrated that the 5' regions of both helper virus genomic RNAs and genomic DI RNAs maintained their original sequences in DI RNA-replicating cells, indicating that the genomic leader sequences derived from JHM(2) functioned for subgenomic DI RNA transcription. Replication and transcription of DI(J3-9) were observed in cells infected with an MHV A59 strain whose leader sequence was similar to that of JHM(2), except for one nucleotide substitution within the leader sequence. The 5' region of the helper virus genomic RNA and that of the DI RNA were the same as their original structures in virus-infected cells, and the leader sequence of DI(J3-9) subgenomic DI RNA contained the MHV A59-derived leader sequence. The leader sequence of subgenomic DI RNA was derived from that of helper virus; therefore, the genomic leader sequence had a trans-acting property indicative of a discontinuous step in coronavirus transcription.

A review of feline infectious peritonitis virus: molecular biology, immunopathogenesis, clinical aspects, and vaccination

Feline infectious peritonitis (FIP) has been an elusive and frustrating problem for veterinary practitioners and cat breeders for many years. Over the last several years, reports have begun to elucidate aspects of the molecular biology of the causal virus (FIPV). These papers complement a rapidly growing base of knowledge concerning the molecular organization and replication of coronaviruses in general. The fascinating immunopathogenesis of FIPV infection and the virus' interaction with macrophages has also been the subject of several recent papers. It is now clear that FIPV may be of interest to scientists other than veterinary virologists since its pathogenesis may provide a useful model system for other viruses whose infectivity is enhanced in the presence of virus-specific antibody. With these advances and the recent release of the first commercially-available FIPV vaccine, it is appropriate to review what is known about the organization and replication of coronaviruses and the pathogenesis of FIPV infection.

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.

The receptor for mouse hepatitis virus in the resistant mouse strain SJL is functional: implications for the requirement of a second factor for viral infection

The SJL mouse strain is resistant to infection by some strains of the murine coronavirus mouse hepatitis virus (MHV), such as JHM and A59. The block to virus infection has been variously attributed to defects in virus receptors or virus spread. Since the cellular receptors for MHV, mmCGM1 and mmCGM2, have recently been identified as members of the carcinoembryonic antigen family, we reexamined the possible defectiveness of the MHV receptors in SJL mouse strain. Cloning and sequencing of the cDNAs of both mmCGMs RNAs from SJL mice revealed that they were identical in size to those of the susceptible C57BL/6 (B6) mouse. There was some sequence divergence in the N terminus of the mmCGM molecules between the two mouse strains, resulting in a different number of potential glycosylation sites. This was confirmed by in vitro translation of the mmCGM RNAs, which showed that the glycosylated mmCGM2 of SJL was smaller than that of B6 mice. However, transfection of either mmCGM1 or mmCGM2 from SJL mice into MHV-resistant Cos 7 cells rendered the cells susceptible to MHV infection. The ability of the SJL mmCGM molecules to serve as MHV receptors was comparable to that of those from B6. These molecules are expressed in SJL mouse brain and liver in a similar ratio and in amounts equivalent to those in the B6 mouse. Furthermore, we demonstrated that an SJL-derived cell line was susceptible to A59 but resistant to JHM infection. We concluded that the MHV receptor molecules in the SJL mouse are functional and that the resistance of SJL mice to infection by some MHV strains most likely results from some other factor(s) required for virus entry or some other step(s) in virus replication.

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.

Coronavirus mRNA transcription: UV light transcriptional mapping studies suggest an early requirement for a genomic-length template

Mouse hepatitis virus (MHV) synthesizes seven to eight mRNAs, each of which contains a leader RNA derived from the 5' end of the genome. To understand the mechanism of synthesis of these mRNAs, we studied how the synthesis of each mRNA was affected by UV irradiation at different time points after infection. When MHV-infected cells were UV irradiated at a late time in infection (5 h postinfection), the syntheses of the various mRNAs were inhibited to different extents in proportion to the sizes of the mRNAs. Analysis of the UV inactivation kinetics revealed that the UV target size of each mRNA was equivalent to its own physical size. In contrast, when cells were irradiated at 2.5 or 3 h postinfection, there appeared to be two different kinetics of inhibition of mRNA synthesis: the synthesis of every mRNA was inhibited to the same extent by a small UV dose, but the remaining mRNA synthesis was inhibited by additional UV doses at different rates for different mRNAs in proportion to RNA size. The analysis of the UV inactivation kinetics indicated that the UV target sizes for the majority of mRNAs were equivalent to that of the genomic-size RNA early in the infection. These results suggest that MHV mRNA synthesis requires the presence of a genomic-length RNA template at least early in the infection. In contrast, later in the infection, the sizes of the templates used for mRNA synthesis were equivalent to the physical sizes of each mRNA. The possibility that the genomic-length RNA required early in the infection was used only for the synthesis of a polymerase rather than as a template for mRNA synthesis was ruled out by examining the UV sensitivity of a defective interfering (DI) RNA. We found that the UV target size for the DI RNA early in infection was much smaller than that for mRNAs 6 and 7, which are approximately equal to or smaller in size than the DI RNA. This result indicates that even though DI RNA and viral mRNAs are synthesized by the same polymerase, mRNAs are synthesized from a larger (genomic-length) template. We conclude that a genomic-length RNA template is required for MHV subgenomic mRNA synthesis at least early in infection. Several transcription models are proposed.

Hemagglutinin-esterase-specific monoclonal antibodies alter the neuropathogenicity of mouse hepatitis virus

Some of mouse hepatitis virus strains contain an optional envelope glycoprotein, hemagglutinin-esterase (HE) protein. To understand the functional significance of this protein, monoclonal antibodies (MAbs) specific for this protein were generated and used for passive immunization of mice. None of these MAbs showed any virus-neutralizing activity in vitro; however, mice passively immunized with the purified MAbs were protected from lethal infection by the JHM strain of mouse hepatitis virus. Passive immunization altered the pathogenicity such that the virus caused subacute and chronic demyelination instead of acute lethal encephalitis. Virus titers in the brains of the immunized mice were significantly lower than those for the nonimmunized control mice, suggesting that the virus replication or spread was inhibited. In addition, histopathological analysis indicated that the spread of virus in the brain and spinal cord was significantly inhibited in the immunized mice. Furthermore, the mononuclear cell infiltration in the immunized mice appeared earlier than in the nonimmunized mice, suggesting that the exogenous antibody might have activated host immune responses, and thus facilitated clearance of the virus or virus-infected cells. The same protective effects were observed for both JHM(2) and JHM(3) viruses, which expressed different amounts of the HE protein. In contrast, mice infected with At11f, a variant of JHM which does not express the HE protein, were not protected by these MAbs, suggesting that protection was mediated by the specific interaction between the MAb and the HE protein. Thus, the mechanism of protection by the exogenous HE-specific MAbs may represent the early activation of innate immune mechanisms in response to the interaction between the MAbs and the HE protein.

Coronavirus mRNA synthesis: identification of novel transcription initiation signals which are differentially regulated by different leader sequences

The mRNA synthesis of mouse hepatitis virus (MHV) has been proposed to be the result of interaction between the leader RNA and the intergenic sites. Previously, we have identified a transcription initiation site (for mRNA 2-1), which is more efficiently transcribed by viruses containing two copies of UCUAA sequence in the leader RNA than by those with three copies. In this study, we have identified several sites which are regulated in the opposite way, namely, they are efficiently transcribed by the leader RNA with three UCUAA copies but not by those with two copies. These sites were characterized by primer extension and amplification by polymerase chain reaction. One of these sites is in the gene 3 region of a recombinant virus between A59 and JHM strains of MHV. Another is in the gene 2 region of MHV-1 strain. Both of these sites have a sequence similar to but different from the consensus transcription initiation signal (UCUAAUCUAUC and UUUAAUCUU, as opposed to UCUAAAC). These two novel intergenic sequences are not present in the genome of the JHM strain, consistent with the absence of these mRNAs in the JHM-infected cells. The discovery of this type of transcription initiation site provides additional evidence for the importance of the leader RNA in the transcription initiation of MHV mRNAs.

A system for study of coronavirus mRNA synthesis: a regulated, expressed subgenomic defective interfering RNA results from intergenic site insertion

A system that exploits defective interfering (DI) RNAs of mouse hepatitis virus (MHV) for deciphering the mechanisms of coronavirus mRNA transcription was developed. A complete cDNA clone of MHV DI RNA containing an inserted intergenic region, derived from the area of genomic RNA between genes 6 and 7, was constructed. After transfection of the in vitro-synthesized DI RNA into MHV-infected cells, replication of genomic DI RNA as well as transcription of the subgenomic DI RNA was observed. S1 nuclease protection experiments, sequence analysis, and Northern (RNA) blotting analysis revealed that the subgenomic DI RNA contained the leader sequence at its 5' end and that the body of the subgenomic DI RNA started from the inserted intergenic sequence. Two subgenomic DI RNAs were synthesized after inserting two intergenic sites into the MHV DI RNA. Metabolic labeling of virus-specific protein in DI RNA replicating cells demonstrated that a protein was translated from the subgenomic DI RNA, which can therefore be considered a functional mRNA. Transfection study of gel-purified genomic DI RNA and subgenomic DI RNA revealed that the introduction of the genomic DI RNA, but not subgenomic DI RNA, into MHV-infected cells was required for synthesis of the subgenomic DI RNA. A series of deletion mutations in the intergenic site demonstrated that the sequence flanking the consensus sequence of UCUAAAC affected the efficiency of subgenomic DI RNA transcription and that the consensus sequence was necessary but not sufficient for the synthesis of the subgenomic DI RNA.

Heterogeneity of gene expression of the hemagglutinin-esterase (HE) protein of murine coronaviruses

The hemagglutinin-esterase (HE) membrane glycoprotein is present only in some members of the coronavirus family, including some strains of mouse hepatitis virus (MHV). In the JHM strain of MHV, expression of the HE gene is variable and corresponds to the number of copies of a UCUAA pentanucleotide sequence present at the 3'-end of the leader RNA. This copy number varies among MHV strains, depending on their passage history. The JHM isolates with two copies of UCUAA in their leader RNA showed a high level of HE expression, whereas the JHM isolate with three copies had a low-level expression. In this study, the analysis of HE gene expression was extended to other MHV strains. The synthesis of HE mRNA in these viruses also correlates with the copy number of UCUAA in the leader RNA and the particular intergenic sequence preceding the HE gene. In one MHV strain, MHV-1, no detectable HE mRNA was synthesized, despite the presence of a proper transcription initiation signal. This lack of HE mRNA expression was consistent with a leader RNA containing three UCUAA copies. However, mutations and deletions within the coding region of the MHV-1 HE gene have generated a stretch of sequence which resembled the transcriptional initiation motif, and was shown to initiate the synthesis of a novel smaller mRNA. These findings strengthened the theory that interactions between leader RNA and transcriptional initiation sequences regulate MHV subgenomic mRNA transcription. Sequence analysis revealed that most MHV strains, through extensive mutations, deletions, or insertions, have lost the complete HE open reading frame, thus turning HE into a pseudogene. This high degree of variation is unusual as the other three structural proteins (spike, membrane, and nucleocapsid) are well-maintained. In contrast to bovine coronavirus, which apparently requires HE for viral replication, the HE protein in MHV may be only an accessory protein which is not necessary for viral replication. JHM and MHV-S, however, have preserved the expression of HE protein.

Localization of extensive deletions in the structural genes of two neurotropic variants of murine coronavirus JHM

The intracellular RNA of two neurotropic variants of the JHM strain of mouse hepatitis virus (MHV) independently isolated from the brain and spinal cord of an infected Wistar Furth rat were compared with that of the parental virus. The mRNAs corresponding to the genes encoding the peplomer (S) and the hemagglutinin-esterase (HE) proteins of the variant viruses were found to be smaller in size. The possible sequence changes were studied by oligonucleotide fingerprinting and direct RNA sequencing. Both variants have a large deletion of 246 amino acids in the carboxy-terminal end of the HE protein. However, this truncated protein was not detected in the infected cells, suggesting either a translational regulation or rapid degradation of the truncated protein in these cells. The variant virus isolated from the spinal cord has a second deletion of 147 amino acids in the amino-terminal half of the S protein. This deletion site corresponds to a hypervariable region where deletions have been frequently noted among MHV variants with different biological properties. These findings suggest that the changes in pathogenic properties of the two neural isolates are associated with drastic alterations of the viral structural glycoproteins.

A clustering of RNA recombination sites adjacent to a hypervariable region of the peplomer gene of murine coronavirus

Coronaviruses undergo RNA recombination at a very high frequency. To understand the mechanism of recombination in murine coronavirus, we have performed RNA sequencing of viral genomic RNA to determine the precise sites of recombination in a series of recombinants which have crossovers within the gene encoding the peplomer protein. We found that all of the recombination sites are clustered within a region of 278 nucleotides in the 5'-half of the gene. This region in which all of the crossovers occurred represents a small fraction of the distance between the two selection markers used for the isolation of these recombinant viruses. This result suggests that this region may be a preferred site for RNA recombination. The crossover sites are located within and immediately adjacent to a hypervariable area of the gene. This area has undergone deletions of varying sizes in several virus strains which have been passaged either in vivo or in vitro. These results suggest that a similar RNA structure may be involved in the occurrence of both recombination and deletion events.

Studies of coronavirus DI RNA replication using in vitro constructed DI cDNA clones

Sequence analysis of an intracellular defective-interfering (DI) RNA, DIssE, of mouse hepatitis virus (MHV) revealed that it is composed of three noncontiguous genomic regions, representing the first 864 nucleotides of the 5'-end, an internal 748 nucleotides of the polymerase gene, and 601 nucleotides from the 3'-end of the parental MHV genome. DIssE had three base substitutions within the leader sequence and also a deletion of nine nucleotides located at the junction of the leader and the remaining genomic sequence. A system was developed for generating DI RNAs to study the mechanism of MHV RNA replication. A cDNA copy of DIssE RNA was placed downstream of T7 RNA polymerase promoter to generate DI RNAs capable of extremely efficient replication in the presence of a helper virus. We demonstrated that, in the DI RNA-transfected cells, the leader sequence of these DI RNAs was switched to that of the helper virus during one round of replication. This high-frequency leader sequence exchange was not observed if a nine-nucleotide stretch at the junction between the leader and the remaining DI sequence was deleted. This observation suggests that a free leader RNA is utilized for the replication of MHV RNA.

High-frequency leader sequence switching during coronavirus defective interfering RNA replication

A system was developed that exploited defective interfering (DI) RNAs of coronavirus to study the role of free leader RNA in RNA replication. A cDNA copy of mouse hepatitis virus DI RNA was placed downstream of the T7 RNA polymerase promoter to generate DI RNAs capable of extremely efficient replication in the presence of a helper virus. We demonstrated that, in the DI RNA-transfected cells, the leader sequence of these DI RNAs was switched to that of the helper virus during one round of replication. This high-frequency leader sequence exchange was not observed if a nine-nucleotide stretch of sequence (UUUAUAAAC) at the junction between the leader and the remaining DI sequence was deleted. This observation suggests that a free leader RNA generated from the genomic RNA of mouse hepatitis virus may participate in the replication of DI RNA.

Biosynthesis, structure, and biological activities of envelope protein gp65 of murine coronavirus

We have previously shown that gp65 (E3) is a virion structural protein which varies widely in quantity among different strains of mouse hepatitis virus (MHV). In this study, the biosynthetic pathway and possible biological activities of this protein were examined. The glycosylation of gp65 in virus-infected cells was inhibited by tunicamycin but not by monensin, suggesting that it contains an N-glycosidic linkage. Glycosylation is cotranslational and appears to be complete before the glycoprotein reaches the Golgi complex. Pulse-chase experiments showed that this protein decreased in size after 30 min of chase, suggesting that the carbohydrate chains of gp65 undergo trimming during its transport across the Golgi. This interpretation is supported by the endoglycosidase treatment of gp65, which showed that the peptide backbone of gp65 did not decrease in size after pulse-chase periods. This maturation pathway is distinct from that of the E1 or E2 glycoproteins. Partial endoglycosidase treatment indicated that gp65 contains 9 to 10 carbohydrate side chains; thus, almost all of the potential glycosylation sites of gp65 were glycosylated. In vitro translation studies coupled with protease digestion suggest that gp65 is an integral membrane protein. The presence of gp65 in the virion is correlated with the presence of an acetylesterase activity. No hemagglutinin activity was detected.

Identification of a new transcriptional initiation site and the corresponding functional gene 2b in the murine coronavirus RNA genome

We have previously shown that some strains of the murine coronavirus mouse hepatitis virus (MHV) synthesize an additional mRNA species (mRNA 2b, previously called mRNA 2a) with a size intermediate between that of mRNAs 2 and 3, suggesting the presence of an optional transcriptional initiation site. This transcriptional start is dependent on the leader sequence of the virus strains. To study the mechanism of coronavirus transcriptional regulation, we have cloned and sequenced the region of the viral genome corresponding to the 5' unique coding region of mRNA 2 of the JHM strain of MHV. In addition to the open reading frame (ORF) predicted to encode the viral nonstructural protein p30, a second complete ORF, with the potential to encode a 439-amino-acid polypeptide, was discovered. The transcriptional initiation sites of both mRNA 2a (formerly called mRNA 2) and mRNA 2b were determined by primer extension studies and RNA sequencing. The data indicated that transcription of mRNA 2a initiated at a site, UCUAUAC, that resembled the consensus intergenic sequence. In contrast, the start signal of the optional mRNA 2b, UAAUAAAC, deviated from the consensus sequence. mRNA 2b is a functional mRNA, as shown by in vitro translation studies of mRNA and ORF 2b and by the detection of an additional viral structural protein, gp65, in the JHM strain that synthesized this mRNA. Although the A59 strain of MHV was found to retain ORF 2b, it lacked the correct transcriptional and translational start signals for this gene. This study has therefore identified an optional gene product for murine coronaviruses and provided insights into the mechanism of regulation of MHV RNA transcription.