Replication of mouse hepatitis virus: negative-stranded RNA and replicative form RNA are of genome length

Mechanisms of Coronavirus Nsp1-Mediated Control of Host and Viral Gene Expression

Many viruses disrupt host gene expression by degrading host mRNAs and/or manipulating translation activities to create a cellular environment favorable for viral replication. Often, virus-induced suppression of host gene expression, including those involved in antiviral responses, contributes to viral pathogenicity. Accordingly, clarifying the mechanisms of virus-induced disruption of host gene expression is important for understanding virus–host cell interactions and virus pathogenesis. Three highly pathogenic human coronaviruses (CoVs), including severe acute respiratory syndrome (SARS)-CoV, Middle East respiratory syndrome (MERS)-CoV, and SARS-CoV-2, have emerged in the past two decades. All of them encode nonstructural protein 1 (nsp1) in their genomes. Nsp1 of SARS-CoV and MERS-CoV exhibit common biological functions for inducing endonucleolytic cleavage of host mRNAs and inhibition of host translation, while viral mRNAs evade the nsp1-induced mRNA cleavage. SARS-CoV nsp1 is a major pathogenic determinant for this virus, supporting the notion that a viral protein that suppresses host gene expression can be a virulence factor, and further suggesting the possibility that SARS-CoV-2 nsp1, which has high amino acid identity with SARS-CoV nsp1, may serve as a major virulence factor. This review summarizes the gene expression suppression functions of nsp1 of CoVs, with a primary focus on SARS-CoV nsp1 and MERS-CoV nsp1.

Translational control of coronaviruses

Coronaviruses represent a large family of enveloped RNA viruses that infect a large spectrum of animals. In humans, the severe acute respiratory syndrome coronavirus type 2 (SARS-CoV-2) is responsible for the current COVID-19 pandemic and is genetically related to SARS-CoV and Middle East respiratory syndrome-related coronavirus (MERS-CoV), which caused outbreaks in 2002 and 2012, respectively. All viruses described to date entirely rely on the protein synthesis machinery of the host cells to produce proteins required for their replication and spread. As such, virus often need to control the cellular translational apparatus to avoid the first line of the cellular defense intended to limit the viral propagation. Thus, coronaviruses have developed remarkable strategies to hijack the host translational machinery in order to favor viral protein production. In this review, we will describe some of these strategies and will highlight the role of viral proteins and RNAs in this process.

The Endonucleolytic RNA Cleavage Function of nsp1 of Middle East Respiratory Syndrome Coronavirus Promotes the Production of Infectious Virus Particles in Specific Human Cell Lines

Middle East respiratory syndrome coronavirus (MERS-CoV) nsp1 suppresses host gene expression in expressed cells by inhibiting translation and inducing endonucleolytic cleavage of host mRNAs, the latter of which leads to mRNA decay. We examined the biological functions of nsp1 in infected cells and its role in virus replication by using wild-type MERS-CoV and two mutant viruses with specific mutations in the nsp1; one mutant lacked both biological functions, while the other lacked the RNA cleavage function but retained the translation inhibition function. In Vero cells, all three viruses replicated efficiently with similar replication kinetics, while wild-type virus induced stronger host translational suppression and host mRNA degradation than the mutants, demonstrating that nsp1 suppressed host gene expression in infected cells. The mutant viruses replicated less efficiently than wild-type virus in Huh-7 cells, HeLa-derived cells, and 293-derived cells, the latter two of which stably expressed a viral receptor protein. In 293-derived cells, the three viruses accumulated similar levels of nsp1 and major viral structural proteins and did not induce IFN-β and IFN-λ mRNAs; however, both mutants were unable to generate intracellular virus particles as efficiently as wild-type virus, leading to inefficient production of infectious viruses. These data strongly suggest that the endonucleolytic RNA cleavage function of the nsp1 promoted MERS-CoV assembly and/or budding in a 293-derived cell line. MERS-CoV nsp1 represents the first CoV gene 1 protein that plays an important role in virus assembly/budding and is the first identified viral protein whose RNA cleavage-inducing function promotes virus assembly/budding.IMPORTANCE MERS-CoV represents a high public health threat. Because CoV nsp1 is a major viral virulence factor, uncovering the biological functions of MERS-CoV nsp1 could contribute to our understanding of MERS-CoV pathogenicity and spur development of medical countermeasures. Expressed MERS-CoV nsp1 suppresses host gene expression, but its biological functions for virus replication and effects on host gene expression in infected cells are largely unexplored. We found that nsp1 suppressed host gene expression in infected cells. Our data further demonstrated that nsp1, which was not detected in virus particles, promoted virus assembly or budding in a 293-derived cell line, leading to efficient virus replication. These data suggest that nsp1 plays an important role in MERS-CoV replication and possibly affects virus-induced diseases by promoting virus particle production in infected hosts. Our data, which uncovered an unexpected novel biological function of nsp1 in virus replication, contribute to further understanding of the MERS-CoV replication strategies.

What we know but do not understand about nidovirus helicases

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The ubiquitous nidovirus helicase is a multi-functional enzyme of superfamily 1.

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Its unique N-terminal domain is most similar to the Upf1 multinuclear zinc-binding domain.

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It has been implicated in replication, transcription, virion biogenesis, translation and post-transcriptional viral RNA processing.

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Four different classes of antiviral compounds targeting the helicase have been identified.

Helicases are versatile NTP-dependent motor proteins of monophyletic origin that are found in all kingdoms of life. Their functions range from nucleic acid duplex unwinding to protein displacement and double-strand translocation. This explains their participation in virtually every metabolic process that involves nucleic acids, including DNA replication, recombination and repair, transcription, translation, as well as RNA processing. Helicases are encoded by all plant and animal viruses with a positive-sense RNA genome that is larger than 7 kb, indicating a link to genome size evolution in this virus class. Viral helicases belong to three out of the six currently recognized superfamilies, SF1, SF2, and SF3. Despite being omnipresent, highly conserved and essential, only a few viral helicases, mostly from SF2, have been studied extensively. In general, their specific roles in the viral replication cycle remain poorly understood at present. The SF1 helicase protein of viruses classified in the order Nidovirales is encoded in replicase open reading frame 1b (ORF1b), which is translated to give rise to a large polyprotein following a ribosomal frameshift from the upstream ORF1a. Proteolytic processing of the replicase polyprotein yields a dozen or so mature proteins, one of which includes a helicase. Its hallmark is the presence of an N-terminal multi-nuclear zinc-binding domain, the nidoviral genetic marker and one of the most conserved domains across members of the order. This review summarizes biochemical, structural, and genetic data, including drug development studies, obtained using helicases originating from several mammalian nidoviruses, along with the results of the genomics characterization of a much larger number of (putative) helicases of vertebrate and invertebrate nidoviruses. In the context of our knowledge of related helicases of cellular and viral origin, it discusses the implications of these results for the protein's emerging critical function(s) in nidovirus evolution, genome replication and expression, virion biogenesis, and possibly also post-transcriptional processing of viral RNAs. Using our accumulated knowledge and highlighting gaps in our data, concepts and approaches, it concludes with a perspective on future research aimed at elucidating the role of helicases in the nidovirus replication cycle.

SARS-CoV ORF1b-encoded nonstructural proteins 12-16: replicative enzymes as antiviral targets

The SARS (severe acute respiratory syndrome) pandemic caused ten years ago by the SARS-coronavirus (SARS-CoV) has stimulated a number of studies on the molecular biology of coronaviruses. This research has provided significant new insight into many mechanisms used by the coronavirus replication-transcription complex (RTC). The RTC directs and coordinates processes in order to replicate and transcribe the coronavirus genome, a single-stranded, positive-sense RNA of outstanding length (∼27-32kilobases). Here, we review the up-to-date knowledge on SARS-CoV replicative enzymes encoded in the ORF1b, i.e., the main RNA-dependent RNA polymerase (nsp12), the helicase/triphosphatase (nsp13), two unusual ribonucleases (nsp14, nsp15) and RNA-cap methyltransferases (nsp14, nsp16). We also review how these enzymes co-operate with other viral co-factors (nsp7, nsp8, and nsp10) to regulate their activity. These last ten years of research on SARS-CoV have considerably contributed to unravel structural and functional details of one of the most fascinating replication/transcription machineries of the RNA virus world. This paper forms part of a series of invited articles in Antiviral Research on "From SARS to MERS: 10years of research on highly pathogenic human coronaviruses".

Coronavirus Genome Replication

Viruses belonging to the family Coronaviridae are unique among RNA viruses because of the unusually large size of their genome, which is of messenger- or positive- or plus-sense. It is ∼30,000 bases or 2–3 times larger than the genomes of most other RNA viruses. Coronaviruses belong to the order Nidovirales, the other three families being the Arteriviridae, Toroviridae and Roniviridae. (For a review of classification and evolutionary relatedness of Nidovirales see Gorbalenya et al. 2006.) This grouping is based on the arrangement and relatedness of open reading frames within their genomes and on the presence in infected cells of multiple subgenomic mRNAs that form a 3'-co-terminal, nested set with the genome. Among the Nidovirales, coronaviruses (and toroviruses) are unique in their possession of a helical nucleocapsid, which is unusual for plus-stranded but not minus-stranded RNA viruses; plus-stranded RNA-containing plant viruses in the Closteroviridae and in the Tobamovirus genus also possess helical capsids. Coronaviruses are very successful and have infected many species of animals, including bats, birds (poultry) and mammals, such as humans and livestock. Coronavirus species are classified into three groups, which were based originally on cross-reacting antibodies and more recently on nucleotide sequence relatedness (Gonzalez et al. 2003). There have been several reviews of coronaviruses published recently and the reader is referred to them for more extensive references (Enjuanes et al. 2006; Masters 2006; Pasternak et al. 2006; Sawicki and Sawicki 2005; Sawicki et al. 2007; Ziebuhr 2005).

Nidovirus transcription: how to make sense...?

Many positive-stranded RNA viruses use subgenomic mRNAs to express part of their genetic information. To produce structural and accessory proteins, members of the order Nidovirales (corona-, toro-, arteri- and roniviruses) generate a 3' co-terminal nested set of at least three and often seven to nine mRNAs. Coronavirus and arterivirus subgenomic transcripts are not only 3' co-terminal but also contain a common 5' leader sequence, which is derived from the genomic 5' end. Their synthesis involves a process of discontinuous RNA synthesis that resembles similarity-assisted RNA recombination. Most models proposed over the past 25 years assume co-transcriptional fusion of subgenomic RNA leader and body sequences, but there has been controversy over the question of whether this occurs during plus- or minus-strand synthesis. In the latter model, which has now gained considerable support, subgenomic mRNA synthesis takes place from a complementary set of subgenome-size minus-strand RNAs, produced by discontinuous minus-strand synthesis. Sense-antisense base-pairing interactions between short conserved sequences play a key regulatory role in this process. In view of the presumed common ancestry of nidoviruses, the recent finding that ronivirus and torovirus mRNAs do not contain a common 5' leader sequence is surprising. Apparently, major mechanistic differences must exist between nidoviruses, which raises questions about the functions of the common leader sequence and nidovirus transcriptase proteins and the evolution of nidovirus transcription. In this review, nidovirus transcription mechanisms are compared, the experimental systems used are critically assessed and, in particular, the impact of recently developed reverse genetic systems is discussed.

Coronavirus transcription: a perspective

At the VIth International Symposium on Corona and Related Viruses held in Quebec, Canada in 1994 we presented a new model for coronavirus transcription to explain how subgenome-length minus strands, which are used as templates for the synthesis of subgenomic mRNAs, might arise by a process involving discontinuous RNA synthesis. The old model explaining subgenomic mRNA synthesis, which was called leader-primed transcription, was based on erroneous evidence that only genome-length negative strands were present in replicative intermediates. To explain the discovery of subgenome-length minus strands, a related model, called the replicon model, was proposed: The subgenomic mRNAs would be produced initially by leader-primed transcription and then replicated into minus-strand templates that would in turn be transcribed into subgenomic mRNAs. We review the experimental evidence that led us to formulate a third model proposing that the discontinuous event in coronavirus RNA synthesis occurs during minus strand synthesis. With our model the genome is copied both continuously to produce minus-strand templates for genome RNA synthesis and discontinuously to produce minus-strand templates for subgenomic mRNA synthesis, and the subgenomic mRNAs do not function as templates for minus strand synthesis, only the genome does.

Regulation of relative abundance of arterivirus subgenomic mRNAs

The subgenomic (sg) mRNAs of arteriviruses (order Nidovirales) form a 5'- and 3'-coterminal nested set with the viral genome. Their 5' common leader sequence is derived from the genomic 5'-proximal region. Fusion of sg RNA leader and "body" segments involves a discontinuous transcription step. Presumably during minus-strand synthesis, the nascent RNA strand is transferred from one site in the genomic template to another, a process guided by conserved transcription-regulating sequences (TRSs) at these template sites. Subgenomic RNA species are produced in different but constant molar ratios, with the smallest RNAs usually being most abundant. Factors thought to influence sg RNA synthesis are size differences between sg RNA species, differences in sequence context between body TRSs, and the mutual influence (or competition) between strand transfer reactions occurring at different body TRSs. Using an Equine arteritis virus infectious cDNA clone, we investigated how body TRS activity affected sg RNA synthesis from neighboring body TRSs. Flanking sequences were standardized by head-to-tail insertion of several copies of an RNA7 body TRS cassette. A perfect gradient of sg RNA abundance, progressively favoring smaller RNA species, was observed. Disruption of body TRS function by mutagenesis did not have a significant effect on the activity of other TRSs. However, deletion of body TRS-containing regions enhanced synthesis of sg RNAs from upstream TRSs but not of those produced from downstream TRSs. The results of this study provide considerable support for the proposed discontinuous extension of minus-strand RNA synthesis as a crucial step in sg RNA synthesis.

Discontinuous and non-discontinuous subgenomic RNA transcription in a nidovirus

Arteri-, corona-, toro- and roniviruses are evolutionarily related positive-strand RNA viruses, united in the order Nidovirales. The best studied nidoviruses, the corona- and arteriviruses, employ a unique transcription mechanism, which involves discontinuous RNA synthesis, a process resembling similarity-assisted copy-choice RNA recombination. During infection, multiple subgenomic (sg) mRNAs are transcribed from a mirror set of sg negative-strand RNA templates. The sg mRNAs all possess a short 5' common leader sequence, derived from the 5' end of the genomic RNA. The joining of the non-contiguous 'leader' and 'body' sequences presumably occurs during minus-strand synthesis. To study whether toroviruses use a similar transcription mechanism, we characterized the 5' termini of the genome and the four sg mRNAs of Berne virus (BEV). We show that BEV mRNAs 3-5 lack a leader sequence. Surprisingly, however, RNA 2 does contain a leader, identical to the 5'-terminal 18 residues of the genome. Apparently, BEV combines discontinuous and non-discontinuous RNA synthesis to produce its sg mRNAs. Our findings have important implications for the understanding of the mechanism and evolution of nidovirus transcription.

Sequence requirements for RNA strand transfer during nidovirus discontinuous subgenomic RNA synthesis

Nidovirus subgenomic mRNAs contain a leader sequence derived from the 5' end of the genome fused to different sequences ('bodies') derived from the 3' end. Their generation involves a unique mechanism of discontinuous subgenomic RNA synthesis that resembles copy-choice RNA recombination. During this process, the nascent RNA strand is transferred from one site in the template to another, during either plus or minus strand synthesis, to yield subgenomic RNA molecules. Central to this process are transcription-regulating sequences (TRSs), which are present at both template sites and ensure the fidelity of strand transfer. Here we present results of a comprehensive co-variation mutagenesis study of equine arteritis virus TRSs, demonstrating that discontinuous RNA synthesis depends not only on base pairing between sense leader TRS and antisense body TRS, but also on the primary sequence of the body TRS. While the leader TRS merely plays a targeting role for strand transfer, the body TRS fulfils multiple functions. The sequences of mRNA leader-body junctions of TRS mutants strongly suggested that the discontinuous step occurs during minus strand synthesis.

The RNA structures engaged in replication and transcription of the A59 strain of mouse hepatitis virus

In addition to the RI (replicative intermediate RNA) and native RF (replicative form RNA), mouse hepatitis virus-infected cells contained six species of RNA intermediates active in transcribing subgenomic mRNA. We have named these transcriptive intermediates (TIs) and native transcriptive forms (TFs) because they are not replicating genome-sized RNA. Based on solubility in high salt solutions, approximately 70% of the replicating and transcribing structures that accumulated in infected cells by 5-6 h post-infection were multi-stranded intermediates, the RI/TIs. The other 30% were in double-stranded structures, the native RF/TFs. These replicating and transcribing structures were separated by velocity sedimentation on sucrose gradients or by gel filtration chromatography on Sepharose 2B and Sephacryl S-1000, and migrated on agarose gels during electrophoresis, according to their size. Digestion with RNase T1 at 1-10 units/microgram RNA resolved RI/TIs into RF/TF cores and left native RF/TFs intact, whereas RNase A at concentrations of 0.02 microgram/microgram RNA or higher degraded both native RF/TFs and RI/TIs. Viral RI/TIs and native RF/TFs bound to magnetic beads containing oligo(dT)(25), suggesting that the poly(A) sequence on the 3' end of the positive strands was longer than any poly(U) on the negative strands. Kinetics of incorporation of [(3)H]uridine showed that both the RI and TIs were transcriptionally active and the labelling of RI/TIs was not the dead-end product of aberrant negative-strand synthesis. Failure originally to find TIs and TF cores was probably due to overdigestion with RNase A.

Subgenomic negative-strand RNA function during mouse hepatitis virus infection

Mouse hepatitis virus (MHV)-infected cells contain full-length and subgenomic-length positive- and negative-strand RNAs. The origin and function of the subgenomic negative-strand RNAs is controversial. In this report we demonstrate that the synthesis and molar ratios of subgenomic negative strands are similar in alternative host cells, suggesting that these RNAs function as important mediators of positive-strand synthesis. Using kinetic labeling experiments, we show that the full-length and subgenomic-length replicative form RNAs rapidly accumulate and then saturate with label, suggesting that the subgenomic-length negative strands are the principal mediators of positive-strand synthesis. Using cycloheximide, which preferentially inhibits negative-strand and to a lesser extent positive-strand synthesis, we demonstrate that cycloheximide treatment equally inhibits full-length and subgenomic-length negative-strand synthesis. Importantly, following treatment, previously transcribed negative strands remain in transcriptionally active complexes even in the absence of new negative-strand synthesis. These findings indicate that the subgenomic-length negative strands are the principal templates of positive-strand synthesis during MHV infection.

Characterization of an equine arteritis virus replicase mutant defective in subgenomic mRNA synthesis

Equine arteritis virus (EAV) is a positive-stranded RNA virus that synthesizes a 5'- and 3'-coterminal nested set of six subgenomic mRNAs. These mRNAs all contain a common leader sequence which is derived from the 5' end of the genome. Subgenomic mRNA transcription and genome replication are directed by the viral replicase, which is expressed in the form of two polyproteins and subsequently processed into smaller nonstructural proteins (nsps). During the recent construction of an EAV infectious cDNA clone (pEAV030 [L. C. van Dinten, J. A. den Boon, A. L. M. Wassenaar, W. J. M. Spaan, and E. J. Snijder, Proc. Natl. Acad. Sci. USA 94:991-996, 1997]), a mutant cDNA clone (pEAV030F) which carries a single replicase point mutation was obtained. This substitution (Ser-2429-->Pro) is located in the nsp10 subunit and renders the EAV030F virus deficient in subgenomic mRNA synthesis. To obtain more insight into the role of nsp10 in transcription and the nature of the transcriptional defect, we have now analyzed the EAV030F mutant in considerable detail. The Ser-2429-->Pro mutation does not affect the proteolytic processing of the replicase but apparently affects the function of nsp10 in transcription. Furthermore, our study showed that EAV030F still produces subgenomic positive and negative strands, albeit at a very low level. Both subgenomic positive-strand synthesis and negative-strand synthesis are equally affected by the Ser-2429-->Pro mutation, suggesting that nsp10 plays an important role in an early step of EAV mRNA transcription.

A new model for coronavirus transcription

Coronaviruses contain an unusually long (27-32,000 ribonucleotide) positive sense RNA genome that is polyadenylated at the 3' end and capped at the 5' end. In addition to the genome, infected cells contain subgenomic mRNAs that form a 3' co-terminal nested set with the genome. In addition to their common 3' ends, the genome and the subgenomic mRNAs contain an identical 5' leader sequence. The transcription mechanism that coronaviruses use to produce subgenomic mRNA is not known and has been the subject of speculation since sequencing of the subgenomic mRNAs showed they must arise by discontinuous transcription. The current model called leader-primed transcription has subgenomic mRNAs transcribed directly from genome-length negative strands. It was based on the failure to find in coronavirus infected cells subgenome-length negative strands or replication intermediates containing subgenome-length negative strands. Clearly, these structures exist in infected cells and are transcriptionally active. We proposed a new model for coronavirus transcription which we called 3' discontinuous extension of negative strands. This model predicts that subgenome-length negative strands would be derived directly by transcription using the genome RNA as a template. The subgenome-length templates would contain the common 5' leader sequence and serve as templates for the production of subgenomic mRNAs. Our findings include showing that: 1. Replication intermediates (RIs) containing subgenome-length RNA exist in infected cells and are separable from RIs with genome-length templates. The RFs with subgenome-length templates are not derived by RNase treatment of RIs with genome-length templates. 2. The subgenome-length negative strands are formed early in infection when RIs are accumulating and the rate of viral RNA synthesis is increasing exponentially. 3. Subgenome-length negative strands contain at their 3' ends a complementary copy of the 72 nucleotide leader RNA that is found in the genome only at their 5' end. 4. RIs with subgenomic templates serve immediately as templates for transcription of subgenomic mRNAs. Because subgenomic mRNAs are not replicated, i.e., copied into negative strands that in turn are used as templates for subgenomic mRNA synthesis, we propose that the subgenome-length negative strands must arise directly by transcription of the genome and acquire their common 3' anti-leader sequence after polymerase jumping from the intergenic regions to the leader sequence at the 5' end of the genome. This would make negative strand synthesis discontinuous and subgenomic mRNA synthesis continuous, which is the opposite of what was proposed in the leader primed model.

Regulation of coronavirus mRNA transcription

Coronaviruses synthesize a nested set of six to eight subgenomic (sg) mRNAs in infected cells. These mRNAs are produced in different, but constant, molar ratios. It is unclear which factors control the different levels of sg mRNAs. To determine whether the intergenic sequence (IS) involved in sg mRNA synthesis could affect the transcription efficiencies of other ISs and in this way regulate transcription levels, we inserted multiple ISs at different positions into a mouse hepatitis virus defective interfering RNA. Quantitation of the sg RNAs produced by identical ISs in different sequence contexts led to the following conclusions: (i) transcription efficiency depends on the location of the IS in the defective interfering virus genome, (ii) downstream ISs have a negative effect on transcription levels from upstream ISs, and (iii) upstream ISs have little or no effect on downstream ISs. The observation that a downstream IS downregulates the amounts of sg RNA produced by an upstream IS explains why the smaller sg RNAs are, in general, produced in larger quantities than the larger sg RNAs. Our data are consistent with coronavirus transcription models in which ISs attenuate transcription. In these models, larger sg RNAs are synthesized in smaller amounts because they encounter more attenuating ISs during their synthesis.

Specific binding of host cellular proteins to multiple sites within the 3' end of mouse hepatitis virus genomic RNA

The initial step in mouse hepatitis virus (MHV) RNA replication is the synthesis of negative-strand RNA from a positive-strand genomic RNA template. Our approach to begin studying MHV RNA replication is to identify the cis-acting signals for RNA synthesis and the proteins which recognize these signals at the 3' end of genomic RNA of MHV. To determine whether host cellular and/or viral proteins interact with the 3' end of the coronavirus genome, an RNase T1 protection/gel mobility shift electrophoresis assay was used to examine cytoplasmic extracts from mock- and MHV-JHM-infected 17Cl-1 murine cells for the ability to form complexes with defined regions of the genomic RNA. We demonstrated the specific binding of host cell proteins to multiple sites within the 3' end of MHV-JHM genomic RNA. By using a set of RNA probes with deletions at either the 5' or 3' end or both ends, two distinct binding sites were located. The first protein-binding element was mapped in the 3'-most 42 nucleotides of the genomic RNA [3' (+42) RNA], and the second element was mapped within an 86-nucleotide sequence encompassing nucleotides 171 to 85 from the 3' end of the genome (171-85 RNA). A single potential stem-loop structure is predicted for the 3' (+)42 RNA, and two stem-loop structures are predicted for the 171-85 RNA. Proteins interacting with these two elements were identified by UV-induced covalent cross-linking to labeled RNAs followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis. The RNA-protein complex formed with the 3'-most 42 nucleotides contains approximately five host polypeptides, a highly labeled protein of 120 kDa and four minor species with sizes of 103, 81, 70, and 55 kDa. The second protein-binding element, contained within a probe representing nucleotides 487 to 85 from the 3' end of the genome, also appears to bind five host polypeptides, 142, 120, 100, 55, and 33 kDa in size, with the 120-kDa protein being the most abundant. The RNA-protein complexes observed with MHV-infected cells in both RNase protection/gel mobility shift and UV cross-linking assays were identical to those observed with uninfected cells. The possible involvement of the interaction of host proteins with the viral genome during MHV replication is discussed.

Regulation of transcription of coronaviruses

To study factors involved in regulation of transcription of coronaviruses, we constructed defective interfering (DI) RNAs containing sg RNA promoters at multiple positions. Analysis of the amounts of sg DI RNA produced by these DIs resulted in the following observations: (i) a downstream promoter downregulates an upstream promoter; (ii) an upstream promoter has little or no effect on the activity of a downstream promoter. Our data suggest that attenuation of upstream promoter activities by downstream promoter sequences plays an important role in regulating the amounts of sg RNAs produced by coronaviruses. Our observations are in accordance with the models proposed by Konings et al. and Sawicki and Sawicki.

Coronaviruses use discontinuous extension for synthesis of subgenome-length negative strands

We have developed a new model for coronavirus transcription, which we call discontinuous extension, to explain how subgenome-length negatives stands are derived directly from the genome. The current model called leader-primed transcription, which states that subgenomic mRNA is transcribed directly from genome-length negative-strands, cannot explain many of the recent experimental findings. For instance, subgenomic mRNAs are transcribed directly via transcription intermediates that contain subgenome-length negative-strand templates; however subgenomic mRNA does not appear to be copied directly into negative strands. In our model the subgenome-length negative strands would be derived using the genome as a template. After the polymerase had copied the 3'-end of the genome, it would detach at any one of the several intergenic sequences and reattach to the sequence immediately downstream of the leader sequence at the 5'-end of genome RNA. Base pairing between the 3'-end of the nascent subgenome-length negative strands, which would be complementary to the intergenic sequence at the end of the leader sequence at the 5'-end of genome, would serve to align the nascent negative strand to the genome and permit the completion of synthesis, i.e., discontinuous extension of the 3'-end of the negative strand. Thus, subgenome-length negative strands would arise by discontinuous synthesis, but of negative strands, not of positive strands as proposed originally by the leader-primed transcription model.

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.

Subgenomic RNA synthesis directed by a synthetic defective interfering RNA of mouse hepatitis virus: a study of coronavirus transcription initiation

We have used a full-length cDNA clone of a mouse hepatitis virus strain A59 defective interfering (DI) RNA, pMIDI-C, and cassette mutagenesis to study the mechanism of coronavirus subgenomic mRNA synthesis. Promoter sequences closely resembling those of subgenomic mRNAs 3 and 7 were inserted into MIDI-C. Both subgenomic RNA promoters gave rise to the synthesis of a subgenomic DI RNA in virus-infected and DI RNA-transfected cells. From a mutagenic analysis of the promoters we concluded the following. (i) The extent of base pairing between the leader RNA and the intergenic promoter sequence does not control subgenomic RNA abundance. (ii) Promoter recognition does not rely on base pairing only. Presumably, transcription initiation requires recognition of the promoter sequence by the transcriptase. (iii) Fusion of leader and body sequences takes place at multiple--possibly random--sites within the intergenic promoter sequence. A model is presented in which, prior to elongation, the leader RNA is trimmed by a processive 3'-->5' nuclease.

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.

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.

An in vitro system for the leader-primed transcription of coronavirus mRNAs

We have developed an in vitro transcription system which can utilize exogenous leader RNA for mouse hepatitis virus (MHV) 'leader-primed' mRNA transcription. Cytoplasmic extracts containing viral proteins and template RNA were prepared by lysolecithin permeabilization of MHV-infected cells. Synthetic leader RNA which differed in sequence from the endogenous leader RNA was added to the extracts and demonstrated to be incorporated into MHV mRNAs. Irrespective of the size of leader RNAs added, the exogenous leader RNA was joined to the endogenous mRNA at the same site, which corresponds to a UCUAA pentanucleotide repeat region. Only leader RNAs containing the pentanucleotide sequences could be utilized for transcription. Mismatches between the intergenic site and the exogenous leader sequence within the pentanucleotide repeat region were corrected in the in vitro system. This in vitro system thus established a novel mechanism of leader-primed transcription using exogenous RNA in trans, and suggests the involvement of a specific ribonuclease activity during coronavirus mRNA synthesis.

Minus-strand copies of replicating coronavirus mRNAs contain antileaders

The 5' leader sequence on mRNAs of the porcine transmissible gastroenteritis coronavirus was determined and found to be 90 nucleotides in length. An oligodeoxynucleotide with a sequence from within the leader was used as a probe in Northern analysis on RNA from infected cells, and an antileader (a minus-strand copy of the leader sequence) was shown to be present on all mRNA minus-strand species. RNase protection analysis showed the antileader to be approximately the same length as the leader. The kinetics of antileader appearance was the same as that for the appearance of minus-strand RNA species. This, along with a demonstration that viral mRNAs become packaged, gives further support to the idea that coronavirus mRNAs can undergo replication via subgenomic mRNA-length replicative intermediates, and that input mRNAs from infecting virions may serve as initial templates for their own replication. In this sense, then, coronaviruses behave in part like RNA viruses with segmented genomes.

Genetic basis for the pathogenesis of transmissible gastroenteritis virus

Intracellular RNAs of an avirulent small-plaque (SP) transmissible gastroenteritis virus variant and the parent virulent Miller strain of transmissible gastroenteritis virus were compared. Northern RNA blotting showed that the Miller strain contained eight intracellular RNA species. RNAs 1, 2(S), 5, 6(M), 7(N), and 8 were similar in size for both viruses; however, the SP variant lacked subgenomic RNAs 3 and 4. Instead, the SP virus contained an altered RNA species (delta 4) that was slightly smaller than RNA 4. S1 nuclease protection experiments showed a deletion of approximately 450 nucleotides in the SP genome downstream of the peplomer S gene. Sequencing of cDNA clones confirmed that SP virus contained a 462-nucleotide deletion, eliminating the transcriptional recognition sequences for both RNAs 3 and 4. These RNAs encode open reading frames A and B, respectively. An alternative consensus recognition sequence was not readily apparent for the delta 4 RNA species of SP virus. Since open reading frame A is missing in SP virus, it is not essential for a productive infection. The status of the potential protein encoded by open reading frame B is not clear, because it may be missing or just truncated. Nevertheless, these genes appear to be the contributing entities for transmissible gastroenteritis virus virulence, SP morphology, tissue tropism, and/or persistence in swine leukocytes.

Bovine coronavirus mRNA replication continues throughout persistent infection in cell culture

The existence of viral mRNA replicons was demonstrated in cells infected with the bovine coronavirus by showing a minus-strand counterpart and a corresponding replicative intermediate for each subgenomic mRNA species. mRNA replication is thus a universal property of coronaviruses, since this is now the third coronavirus for which it has been demonstrated. During the acute phase of infection (first 48 h), minus and plus strands accumulated at the same rate initially, but maximal accumulation of minus strands peaked earlier than that for plus strands, indicating that minus- and plus-strand levels are differentially regulated. In addition, packaged (input) mRNAs appeared to serve as templates for their own early replication. mRNA replication continued throughout establishment and maintenance of persistent infection (studied for 120 days), which is consistent with our hypothesis that mRNA replication contributes mechanistically to virus persistence. A replication-defective (potentially interfering) species of RNA existed transiently (beginning at day 2 and ending before day 76 postinfection), but because of its transient nature it cannot be considered essential to the long-term maintenance of virus persistence.

Genetics of mouse hepatitis virus transcription: identification of cistrons which may function in positive and negative strand RNA synthesis

A panel of 26 temperature-sensitive mutants of MHV-A59 were selected by mutagenesis with either 5-fluorouracil or 5-azacytidine. Complementation analysis revealed the presence of one RNA+ and five RNA- complementation groups. None of the RNA- complementation groups transcribed detectable levels of positive- or negative-stranded RNA at the restrictive temperature. Temperature shift experiments after the onset of mRNA synthesis revealed at least two classes of RNA- mutants. RNA- complementation groups A, B, D, and E were blocked in the ability to release infectious virus and transcribe mRNA and genome, while group C mutants continued to release infectious virus and transcribe both mRNA and genome. Temperature shift experiments at different times postinfection suggest that the group C mutants encode a function required early in viral transcription which affects the overall rate of positive strand synthesis. Analysis of steady state levels of negative strand RNA after the shift indicate that the group C mutants were probably blocked in the ability to synthesize additional minus strand RNA under conditions in which the group E mutants continued low levels of minus strand synthesis. These data suggest that at least four cistrons may be required for positive strand synthesis while the group C cistron functions during minus strand synthesis.

The primary structure and expression of the second open reading frame of the polymerase gene of the coronavirus MHV-A59; a highly conserved polymerase is expressed by an efficient ribosomal frameshifting mechanism

Sequence analysis of a substantial part of the polymerase gene of the murine coronavirus MHV-A59 revealed the 3' end of an open reading frame (ORF1a) overlapping with a large ORF (ORF1b; 2733 amino acids) which covers the 3' half of the polymerase gene. The expression of ORF1b occurs by a ribosomal frameshifting mechanism since the ORF1a/ORF1b overlapping nucleotide sequence is capable of inducing ribosomal frameshifting in vitro as well as in vivo. A stem-loop structure and a pseudoknot are predicted in the nucleotide sequence involved in ribosomal frameshifting. Comparison of the predicted amino acid sequence of MHV ORF1b with the amino acid sequence deduced from the corresponding gene of the avian coronavirus IBV demonstrated that in contrast to the other viral genes this ORF is extremely conserved. Detailed analysis of the predicted amino acid sequence revealed sequence elements which are conserved in many DNA and RNA polymerases.

Coronavirus transcription: subgenomic mouse hepatitis virus replicative intermediates function in RNA synthesis

Both genomic and subgenomic replicative intermediates (RIs) and replicative-form (RF) structures were found in 17CL1 mouse cells that had been infected with the A59 strain of mouse hepatitis virus (MHV), a prototypic coronavirus. Seven species of RNase-resistant RF RNAs, whose sizes were consistent with the fact that each was derived from an RI that was engaged in the synthesis of one of the seven MHV positive-strand RNAs, were produced by treatment with RNase A. Because the radiolabeling of the seven RF RNAs was proportional to that of the corresponding seven positive-strand RNAs, the relative rate of synthesis of each of the MHV positive-strand RNAs may be controlled by the relative number of each of the size classes of RIs that are produced. In contrast to alphavirus, which produced its subgenome-length RF RNAs from genome-length RIs, MHV RF RNAs were derived from genome- and subgenome-length RIs. Only the three largest MHV RF RNAs (RFI, RFII, and RFIII) were derived from the RIs that migrated slowest on agarose gels. The four smallest RF RNAs (RFIV, RFV, RFVI, and RFVII) were derived from RIs that migrated in a broad region of the gel that extended from the position of 28S rRNA to the position of the viral single-stranded MHV mRNA-3. Because all seven RIs were labeled during very short pulses with [3H]uridine, we concluded that the subgenome-length RIs are transcriptionally active. These findings, with the recent report of the presence of subgenome-length negative-strand RNAs in cells infected with porcine transmissible gastroenteritis virus (P. B. Sethna, S.-L. Hung, and D. A. Brian, Proc. Natl. Acad. Sci. USA 86: 5626-5630, 1989), strongly suggest that coronaviruses utilize a novel replication strategy that employs the synthesis of subgenomic negative strands to produce subgenomic mRNAs.

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.

Inhibition of murine coronavirus RNA synthesis by hydroxyguanidine derivatives

A series of hydroxyguanidine derivatives, which are substituted salicylaldehyde Schiff-bases of 1-amino-3- hydroxyguanidine tosylate, were tested for the inhibition of RNA synthesis of mouse hepatitis virus (MHV). It was shown that these compounds could selectively inhibit virus-specific RNA synthesis. Every aspect of viral RNA synthesis, including synthesis of negative-stranded RNA, subgenomic mRNA transcription and genomic RNA replication, was inhibited to roughly the same extent. These compounds are the first known inhibitors of coronaviral RNA synthesis and should prove useful for understanding the mechanism of viral RNA synthesis.

Identification of a domain required for autoproteolytic cleavage of murine coronavirus gene A polyprotein

The 5'-most gene of the murine coronavirus genome, gene A, is presumed to encode viral RNA-dependent RNA polymerase. It has previously been shown that the N-terminal portion of this gene product is cleaved into a protein of 28 kilodaltons (p28). To further understand the mechanism of synthesis of the p28 protein, cDNA clones representing the 5'-most 5.3 kilobases of murine coronavirus mouse hepatitis virus strain JHM were sequenced and subcloned into pT7 vectors from which RNAs were transcribed and translated in vitro. The sequence was found to encode a single long open reading frame continuing from near the 5' terminus of the genome. Although p28 is encoded from the first 1 kilobase at the 5' end of the genome, translation of in vitro-transcribed RNAs indicated that this protein was not detected unless the product of the entire 5.3-kilobase region was synthesized. Translation of RNAs of 3.9 kilobases or smaller yielded proteins which contained the p28 sequence, but p28 was not cleaved. This suggests that the sequence in the region between 3.9 and 5.3 kilobases from the 5' end of the genomic RNA is essential for proteolytic cleavage and contains autoproteolytic activity. The p28 protein could not be cleaved from the smaller primary translation products of gene A, even in the presence of the larger autocleaving protein. Cleavage of the p28 protein was inhibited by addition of the protease inhibitor ZnCl2. This study thus identified a protein domain essential for autoproteolytic cleavage of the gene A polyprotein.

Coronavirus subgenomic minus-strand RNAs and the potential for mRNA replicons

The genome of the porcine transmissible gastroenteritis coronavirus is a plus-strand, polyadenylylated, infectious RNA molecule of approximately 20 kilobases. During virus replication, seven subgenomic mRNAs are generated by what is thought to be a leader-priming mechanism to form a 3'-coterminal nested set. By using radiolabeled, strand-specific, synthetic oligodeoxynucleotide probes in RNA blot hybridization analyses, we have found a minus-strand counterpart for the genome and for each subgenomic mRNA species in the cytoplasm of infected cells. Subgenomic minus strands were found to be components of double-stranded replicative forms and in numbers that surpass full-length antigenome. We propose that subgenomic mRNA replication, in addition to leader-primed transcription, is a significant mechanism of mRNA synthesis and that it functions to amplify mRNAs. It is a mechanism of amplification that has not been described for any other group of RNA viruses. Subgenomic replicons may also function in a manner similar to genomes of defective interfering viruses to lead to the establishment of persistent infections, a universal property of coronaviruses.

Specific interaction between coronavirus leader RNA and nucleocapsid protein

Northwestern blot analysis in the presence of competitor RNA was used to examine the interaction between the mouse hepatitis virus (MHV) nucleocapsid protein (N) and virus-specific RNAs. Our accompanying article demonstrates that anti-N monoclonal antibodies immunoprecipitated all seven MHV-specific RNAs as well as the small leader-containing RNAs from infected cells. In this article we report that a Northwestern blotting protocol using radiolabeled viral RNAs in the presence of host cell competitor RNA can be used to demonstrate a high-affinity interaction between the MHV N protein and the virus-specific RNAs. Further, RNA probes prepared by in vitro transcription were used to define the sequences that participate in such high-affinity binding. A specific interaction occurs between the N protein and sequences contained with the leader RNA which is conserved at the 5' end of all MHV RNAs. We have further defined the binding sites to the area of nucleotides 56 to 65 at the 3' end of the leader RNA and suggest that this interaction may play an important role in the discontinuous nonprocessive RNA transcriptional process unique to coronaviruses.

Primary structure and translation of a defective interfering RNA of murine coronavirus

An intracellular defective-interfering (DI) RNA, DIssE, of mouse hepatitis virus (MHV) obtained after serial high multiplicity passage of the virus was cloned and sequenced. DIssE RNA 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. The DIssE sequence contains one large continuous open reading frame. Two protein products from this open reading frame were identified both by in vitro translation and in DI-infected cells. Sequence comparison of DIssE and the corresponding parts of the parental virus genome revealed that 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. The 5' end of DIssE RNA was heterogeneous with respect to the number of UCUAA repeats within the leader sequence. The parental MHV genomic RNA appears to have extensive and stable secondary structures at the regions where DI RNA rearrangements occurred. These data suggest that MHV DI RNA may have been generated as a result of the discontinuous and nonprocessive manner of MHV RNA synthesis.

Synthesis of virus-specific RNA in permeabilized murine coronavirus-infected cells

We have developed a permeabilized cell system for assaying mouse hepatitis virus-specific RNA polymerase activity. This activity was characterized as to its requirements for mono- and divalent cations, requirements for an exogenous energy source, and pH optimum. This system faithfully reflects MHV-specific RNA synthesis in the intact cell, with regard to both its time of appearance during the course of infection and the products synthesized. The system is efficient and the RNA products were identical to those observed in intact MHV-infected cells as judged by agarose gel electrophoresis and hybridization. Permeabilized cells appear to be an ideal system for studying coronavirus RNA synthesis since they closely mimic in vivo conditions while allowing much of the experimental flexibility of truly cell-free systems.

RNA recombination of murine coronaviruses: recombination between fusion-positive mouse hepatitis virus A59 and fusion-negative mouse hepatitis virus 2

It has previously been shown that the murine coronavirus mouse hepatitis virus (MHV) undergoes RNA recombination at a relatively high frequency in both tissue culture and infected animals. Thus far, all of the recombination sites had been localized at the 5' half of the RNA genome. We have now performed a cross between MHV-2, a fusion-negative murine coronavirus, and a temperature-sensitive mutant of the A59 strain of MHV, which is fusion positive at the permissive temperature. By selecting fusion-positive viruses at the nonpermissive temperature, we isolated several recombinants containing multiple crossovers in a single genome. Some of the recombinants became fusion negative during the plaque purification. The fusion ability of the recombinants parallels the presence or absence of the A59 genomic sequences encoding peplomers. Several of the recombinants have crossovers within 3' end genes which encode viral structural proteins, N and E1. These recombination sites were not specifically selected with the selection markers used. This finding, together with results of previous recombination studies, indicates that RNA recombination can occur almost anywhere from the 5' end to the 3' end along the entire genome. The data also show that the replacement of A59 genetic sequences at the 5' end of gene C, which encodes the peplomer protein, with the fusion-negative MHV-2 sequences do not affect the fusion ability of the recombinant viruses. Thus, the crucial determinant for the fusion-inducing capability appears to reside in the more carboxyl portion of the peplomer protein.

Defective-interfering particles of murine coronavirus: mechanism of synthesis of defective viral RNAs

The mechanism of synthesis of the defective viral RNAs in cells infected with defective-interfering (DI) particles of mouse hepatitis virus was studied. Two DI-specific RNA species, DIssA of genomic size and DIssE of subgenomic size, were detected in DI-infected cells. Purified DI particles, however, were found to contain predominantly DIssA and only a trace amount of DIssE RNA. Despite its negligible amount, the DIssE RNA in virions appears to serve as the template for the synthesis of DIssE RNA in infected cells. This conclusion was supported by two studies. First, the uv target size for DIssE RNA synthesis is significantly smaller than that for DIssA. Second, when purified DIssE RNA was transfected into cells which had been infected with a helper virus, DIssE RNA could replicate itself and became a predominant RNA species in the infected cells. Thus, DIssE RNA was not synthesized from the genomic RNA of DI particles. By studying the relationship between virus dilution and the amount of intracellular viral RNA synthesis, we have further shown that DIssE RNA synthesis requires a helper function, but it does not utilize the leader sequence of the helper virus. In contrast, DIssA synthesis appears to be helper-independent and can replicate itself. Thus DIssA codes for a functional RNA polymerase.

Temporal regulation of bovine coronavirus RNA synthesis

The structure and synthesis of bovine coronavirus (BCV)-specific intracellular RNA were studied. A genome-size RNA and seven subgenomic RNAs with molecular weights of approximately 3.3 X 10(6), 3.1 X 10(6), 2.6 X 10(6), 1.1 X 10(6), 1.0 X 10(6), 0.8 X 10(6) and 0.6 X 10(6) were detected. Comparisons of BCV intracellular RNAs with those of mouse hepatitis virus (MHV) demonstrated the presence of an additional RNA for BCV, species 2a, of 3.1 X 10(6) daltons. BCV RNAs contain a nested-set structure similar to that of other coronaviruses. This nested-set structure would suggest that the new RNA has a capacity to encode a protein of approximately 430 amino acids. Kinetic studies demonstrated that the synthesis of subgenomic mRNAs and genomic RNA are differentially regulated. At 4 to 8 h post-infection (p.i.), subgenomic RNAs are synthesized at a maximal rate and represent greater than 90% of the total viral RNA synthesized, whereas genome-size RNA accounts for only 7%. Later in infection, at 70 to 72 h p.i., genome-size RNA is much more abundant and accounts for 88% of total RNA synthesized. Immunoprecipitations of [35S]methionine-pulse-labeled viral proteins demonstrated that viral protein synthesis occurs early in the infection, concurrent with the peak of viral subgenomic RNA synthesis. Western blot analysis suggests that these proteins are stable since the proteins are present at high level as late as 70 to 72 h p.i. The kinetics of production of virus particles coincides with the synthesis of genomic RNA. These studies thus indicate that there is a differential temporal regulation of the synthesis of genomic RNA and subgenomic mRNAs, and that the synthesis of genomic RNA is the rate-limiting step regulating the production of virus particles.

Temperature-sensitive mutants of mouse hepatitis virus type 3 (MHV-3): isolation, biochemical and genetic characterization

Mouse hepatitis virus 3 (MHV-3) is highly hepatotropic in sensitive mice. Temperature-sensitive mutants (ts mutants) induced by N-methyl-N'-nitrosoguanidine and 5-fluorouracil were isolated. Twelve mutants which were able to induce the formation of syncytia at 33 degrees C but not at the restrictive temperature (39.5 degrees C) were selected for detailed study. No viral RNA synthesis was detected after infection at the restrictive temperature with six of the mutants (RNA-) whereas six others were RNA+, although they displayed RNA synthesis which was generally reduced. No differences have been detected in the size of the genome or the viral-intracellular RNA species found in wild type virus or ts mutant infected cells at permissive temperature. The pattern of virus-induced proteins analyzed after immunoprecipitation by SDS-PAGE was similar in wild type virus and RNA+ mutant infected cells at 39.5 degrees C. Complementation experiments between ts mutants enabled us to distinguish five groups. Three of the groups contained RNA- mutants and two of them RNA+. Plaques made by mutants in one group displayed characteristic features that distinguished them from the wild type.

Sequence and translation of the murine coronavirus 5'-end genomic RNA reveals the N-terminal structure of the putative RNA polymerase

A 28-kilodalton protein has been suggested to be the amino-terminal protein cleavage product of the putative coronavirus RNA polymerase (gene A) (M.R. Denison and S. Perlman, Virology 157:565-568, 1987). To elucidate the structure and mechanism of synthesis of this protein, the nucleotide sequence of the 5' 2.0 kilobases of the coronavirus mouse hepatitis virus strain JHM genome was determined. This sequence contains a single, long open reading frame and predicts a highly basic amino-terminal region. Cell-free translation of RNAs transcribed in vitro from DNAs containing gene A sequences in pT7 vectors yielded proteins initiated from the 5'-most optimal initiation codon at position 215 from the 5' end of the genome. The sequence preceding this initiation codon predicts the presence of a stable hairpin loop structure. The presence of an RNA secondary structure at the 5' end of the RNA genome is supported by the observation that gene A sequences were more efficiently translated in vitro when upstream noncoding sequences were removed. By comparing the translation products of virion genomic RNA and in vitro transcribed RNAs, we established that our clones encompassing the 5'-end mouse hepatitis virus genomic RNA encode the 28-kilodalton N-terminal cleavage product of the gene A protein. Possible cleavage sites for this protein are proposed.

In vitro replication of mouse hepatitis virus strain A59

An in vitro replication system for mouse hepatitis virus (MHV) strain A59 was developed using lysolecithin to produce cell extracts. In extracts of MHV-infected cells, radiolabeled UMP was incorporated at a linear rate for up to 1 h into RNA, which hybridized to MHV-specific cDNA probes and migrated in denaturing formaldehyde-agarose gels to the same position as MHV genomic RNA. The incorporation of [32P]UMP into genome-sized RNA in vitro correlated with the observed increase of [3H]uridine incorporation in MHV-infected cells labeled in vivo. Incorporation of [32P]UMP into genome-sized RNA was inhibited when extracts were incubated with puromycin. The addition to the assay of antiserum to the MHV-A59 nucleocapsid protein N inhibited synthesis of genome-sized RNA by 90% compared with the addition of preimmune serum. In contrast, antiserum to the E1 or E2 glycoproteins did not significantly inhibit RNA replication. In vitro-synthesized RNA banded in cesium chloride gradients as a ribonucleoprotein complex with the characteristic density of MHV nucleocapsids isolated from virions. These experiments suggest that ongoing protein synthesis is necessary for replication of MHV genomic RNA and indicate that the N protein plays an important role in MHV replication.

Analysis of intracellular small RNAs of mouse hepatitis virus: evidence for discontinuous transcription

We have previously shown the presence of multiple small leader-containing RNA species in mouse hepatitis virus (MHV)-infected cells. In this paper, we have analyzed the origin, structure, and mechanism of synthesis of these small RNAs. Using cDNA probes specific for leader RNA and genes A, D, and F, we demonstrate that subsets of these small RNAs were derived from the various viral genes. These subsets have discrete and reproducible sizes, varying with the gene from which they are derived. The size of each subset correlates with regions of secondary structure, whose free energy ranges from -1.6 to -77.1 kcal/mol, in each of the mRNAs examined. In addition, identical subsets were detected on the replicative intermediate (RI) RNA, suggesting that they represent functional transcriptional intermediates. The biological significance of these small RNAs is further supported by the detection of leader-containing RNAs of 47, 50, and 57 nucleotides in length, which correspond to the crossover sites in two MHV recombinant viruses. These data, coupled with the high frequency of RNA recombination during MHV infection, suggest that the viral polymerase may pause in or around regions of secondary structure, thereby generating pools of free leader-containing RNA intermediates which can reassociate with the template, acting as primers for the synthesis of full-length or recombinant RNAs. These data suggest that MHV transcription uses a discontinuous and nonprocessive mechanism in which RNA polymerase allows the partial RNA products to be dissociated from the template temporarily during the process of transcription.