The nsp2 replicase proteins of murine hepatitis virus and severe acute respiratory syndrome coronavirus are dispensable for viral replication

The positive-stranded RNA genome of the coronaviruses is translated from ORF1 to yield polyproteins that are proteolytically processed into intermediate and mature nonstructural proteins (nsps). Murine hepatitis virus (MHV) and severe acute respiratory syndrome coronavirus (SARS-CoV) polyproteins incorporate 16 protein domains (nsps), with nsp1 and nsp2 being the most variable among the coronaviruses and having no experimentally confirmed or predicted functions in replication. To determine if nsp2 is essential for viral replication, MHV and SARS-CoV genome RNA was generated with deletions of the nsp2 coding sequence (MHVDeltansp2 and SARSDeltansp2, respectively). Infectious MHVDeltansp2 and SARSDeltansp2 viruses recovered from electroporated cells had 0.5 to 1 log10 reductions in peak titers in single-cycle growth assays, as well as a reduction in viral RNA synthesis that was not specific for any positive-stranded RNA species. The Deltansp2 mutant viruses lacked expression of both nsp2 and an nsp2-nsp3 precursor, but cleaved the engineered chimeric nsp1-nsp3 cleavage site as efficiently as the native nsp1-nsp2 cleavage site. Replication complexes in MHVDeltansp2-infected cells lacked nsp2 but were morphologically indistinguishable from those of wild-type MHV by immunofluorescence. nsp2 expressed in cells by stable retroviral transduction was specifically recruited to viral replication complexes upon infection with MHVDeltansp2. These results demonstrate that while nsp2 of MHV and SARS-CoV is dispensable for viral replication in cell culture, deletion of the nsp2 coding sequence attenuates viral growth and RNA synthesis. These findings also provide a system for the study of determinants of nsp targeting and function.     

Exchange of the Coronavirus Replicase Polyprotein Cleavage Sites Alters Protease Specificity and Processing

Coronavirus nonstructural proteins 1 to 3 are processed by one or two papain-like proteases (PLP1 and PLP2) at specific cleavage sites (CS1 to -3). Murine hepatitis virus (MHV) PLP2 and orthologs recognize and cleave at a position following a p4-Leu-X-Gly-Gly-p1 tetrapeptide, but it is unknown whether these residues are sufficient to result in processing by PLP2 at sites normally cleaved by PLP1. We demonstrate that exchange of CS1 and/or CS2 with the CS3 p4-p1 amino acids in engineered MHV mutants switches specificity from PLP1 to PLP2 at CS2, but not at CS1, and results in altered protein processing and virus replication. Thus, the p4-p1 residues are necessary for PLP2 processing but require a specific protein or cleavage site context for optimal PLP recognition and cleavage.Coronaviruses are positive-strand RNA viruses that translate their first open reading frames (ORF1a and ORF1b) into polyproteins that are processed by viral proteases into intermediate and mature nonstructural proteins (nsp1 to -16) (Fig. ​(Fig.11 A) (4, 7, 17, 20). nsp1, -2, and -3 are liberated at cleavage sites (CSs) between nsp1-2 (CS1), nsp2-3 (CS2), and nsp3-4 (CS3) by one or two papain-like protease (PLP) activities encoded within nsp3 (1, 2, 12, 13, 15) (Fig. ​(Fig.1B).1B). Murine hepatitis virus (MHV) and human coronavirus 229E (HCoV-229E) use two PLPs (PLP1 and PLP2) to process at CS1 to -3, while severe acute respiratory syndrome coronavirus (SARS-CoV) and avian infectious bronchitis virus (IBV) use a single PLP each (PLpro and PLP2, respectively) (10, 20, 25, 26). The factors determining the evolution and use of one versus two PLPs by different coronaviruses for processing of nsp1, -2, and -3 are unknown. Mutations at MHV CSs or within PLP1 alter replication and protein processing in surprising ways (8, 13). Loss of processing at MHV CS1 and CS2 by CS deletion or mutation results in changes in the timing and extent of virus replication. Inactivation of MHV PLP1 is more detrimental for virus replication than deletion of CS1 and CS2 or than inactivation of PLP1 combined with the CS deletions, even though not all of the mutant viruses process at CS1 or CS2 or display similar protein processing phenotypes. In contrast to MHV results, the HCoV-229E PLP1 and PLP2 have both been shown to process at CS1 and CS2, albeit at different efficiencies (Fig. ​(Fig.1B)1B) (24). Finally, the single SARS-CoV PLP2 homolog (PLpro) mediates efficient processing at CS1 to -3, each of which has an upstream position 4-Leu-X-Gly-Gly-position 1 (p4-LXGG-p1) amino acid motif implicated in PLpro processing (10, 16, 18). MHV possesses a p4-LXGG-p1 sequence only at CS3 and is cleaved by PLP2. These results suggest that p4-LXGG-p1 may be the critical determinant of recognition by PLP2/PLpro, but this hypothesis has not been tested in studies of replicating virus. Thus, it remains unknown whether the differences in PLP/CS recognition and processing are determined by the proximal p4-p1 residues (22).Open in a separate windowFIG. 1.MHV replicase organization, coronavirus PLP-mediated processing, and experimental design of cleavage site replacement viruses. (A) ORF1 of MHV genome RNA is shown, with overlapping ORF1a and ORF1b. The ORF1ab polyprotein is shown with nonstructural proteins (nsp1 to -16) indicated by vertical lines and numbers. Viral papain-like protease domains in nsp3 are shown as a white box containing black letters (PLP1) and a black box containing white letters (PLP2), and the nsp5 protease (3CLpro) is indicated as a gray box with a white number. Cleavage sites for PLP1 (CS1 and CS2 [shown as white arrowheads]), PLP2 (CS3 [shown as a black arrowhead]), and nsp5 (CS4 to -14 [shown as gray arrowheads]) are indicated. (B) The organization of nsp1 to nsp4 is shown for representative coronaviruses. PLPs are indicated, with the hatched box in IBV indicating a probable catalytically inactive remnant of PLP1. Processing events that were confirmed as occurring in vitro or during infection are shown by arrows with solid lines and large arrowheads, indicating single or dominant protease activity. The dashed lines and small arrowheads indicate minor or secondary cleavage activities. The CS amino acid sequences from position 4 (p4) to p1′ are shown for each CS, with a space and arrow representing the site of proteolytic processing. (C) The CS substitution viruses were engineered to replace the original CS amino acid sequences at CS1 and/or CS2 with that of the CS3 amino acid sequence p4-LKGG-p1. Both CS substitutions were also engineered into a catalytically inactive PLP1 (P1ko) background. PLPs are shown as numbers in boxes within nsp3. Engineered catalytically inactivated PLP1 is shown as a hatched box. Arrowheads indicate cleavage events of the WT virus and are linked to the enzyme predicted to mediate processing at the CS, as indicated by white boxes containing black characters (PLP1) or black boxes containing white characters (PLP2). The p4 through p1 amino acid residues for each CS are shown below each diagram. White and black vertical bars show the respective predicted PLP1 and PLP2 cleavage sites. Engineered substitutions are indicated in bold characters. Asterisks indicate engineered mutant genomes that could not be recovered as infectious virus.In this study, we used MHV as a model to test whether PLP/CS specificities could be switched by an exchange of CS amino acid sequences and to determine the impact of CS exchange on protein processing and virus replication. Replacement of the CS3 p4-LKGG-p1 at CS2, but not at CS1, was sufficient for a switch in protease specificity from PLP1 to PLP2. Some combinations of CS exchange could not be recovered with inactive PLP1, and recovered mutant viruses had altered protein processing and/or impaired growth compared to the wild type (WT). The results confirm that p4-LXGG-p1 amino acid sequences are necessary determinants of cleavage by PLP2 but also indicate that a larger cleavage site or a different protein context is required for efficient recognition and processing. Finally, the results support the conclusion that complex relationships with respect to the timing and extent of PLP/CS interactions are essential for successful replication and, likely, for virus fitness.     

1H, 13C, 15N resonance assignments of murine hepatitis virus nonstructural protein 3a

Nonstructural protein (nsp) 3 is the largest of 16 nsps translated from the murine hepatitis virus (MHV) genome. The N-terminal most domain of nsp3, nsp3a, has been identified by reverse genetics as a likely binding partner of MHV nucleocapsid protein. Here we report the backbone and side chain resonance assignments of MHV nsp3a (residues 1-114).     

High fidelity of murine hepatitis virus replication is decreased in nsp14 exoribonuclease mutants

Replication fidelity of RNA virus genomes is constrained by the opposing necessities of generating sufficient diversity for adaptation and maintaining genetic stability, but it is unclear how the largest viral RNA genomes have evolved and are maintained under these constraints. A coronavirus (CoV) nonstructural protein, nsp14, contains conserved active-site motifs of cellular exonucleases, including DNA proofreading enzymes, and the severe acute respiratory syndrome CoV (SARS-CoV) nsp14 has 3'-to-5' exoribonuclease (ExoN) activity in vitro. Here, we show that nsp14 ExoN remarkably increases replication fidelity of the CoV murine hepatitis virus (MHV). Replacement of conserved MHV ExoN active-site residues with alanines resulted in viable mutant viruses with growth and RNA synthesis defects that during passage accumulated 15-fold more mutations than wild-type virus without changes in growth fitness. The estimated mutation rate for ExoN mutants was similar to that reported for other RNA viruses, whereas that of wild-type MHV was less than the established rates for RNA viruses in general, suggesting that CoVs with intact ExoN replicate with unusually high fidelity. Our results indicate that nsp14 ExoN plays a critical role in prevention or repair of nucleotide incorporation errors during genome replication. The established mutants are unique tools to test the hypothesis that high replication fidelity is required for the evolution and stability of large RNA genomes.     

Genetic analysis of Murine hepatitis virus nsp4 in virus replication

Coronavirus replicase polyproteins are translated from the genomic positive-strand RNA and are proteolytically processed by three viral proteases to yield 16 mature nonstructural proteins (nsp1 to nsp16). nsp4 contains four predicted transmembrane-spanning regions (TM1, -2, -3, and -4), demonstrates characteristics of an integral membrane protein, and is thought to be essential for the formation and function of viral replication complexes on cellular membranes. To determine the requirement of nsp4 for murine hepatitis virus (MHV) infection in culture, engineered deletions and mutations in TMs and intervening soluble regions were analyzed for effects on virus recovery, growth, RNA synthesis, protein expression, and intracellular membrane modifications. In-frame partial or complete deletions of nsp4; deletions of TM1, -2, and -3; and alanine substitutions of multiple conserved, clustered, charged residues in nsp4 resulted in viruses that were nonrecoverable, viruses highly impaired in growth and RNA synthesis, and viruses that were nearly wild type in replication. The results indicate that nsp4 is required for MHV replication and that while putative TM1, -2, and -3 and specific charged residues may be essential for productive virus infection, putative TM4 and the carboxy-terminal amino acids K(398) through T(492) of nsp4 are dispensable. Together, the experiments identify important residues and regions for studies of nsp4 topology, function, and interactions.     

Cleavage between replicase proteins p28 and p65 of mouse hepatitis virus is not required for virus replication

The p28 and p65 proteins of mouse hepatitis virus (MHV) are the most amino-terminal protein domains of the replicase polyprotein. Cleavage between p28 and p65 has been shown to occur in vitro at cleavage site 1 (CS1), (247)Gly downward arrow Val(248), in the polyprotein. Although critical residues for CS1 cleavage have been mapped in vitro, the requirements for cleavage have not been studied in infected cells. To define the determinants of CS1 cleavage and the role of processing at this site during MHV replication, mutations and deletions were engineered in the replicase polyprotein at CS1. Mutations predicted to allow cleavage at CS1 yielded viable virus that grew to wild-type MHV titers and showed normal expression and processing of p28 and p65. Mutant viruses containing predicted noncleaving mutations or a CS1 deletion were also viable but demonstrated delayed growth kinetics, reduced peak titers, decreased RNA synthesis, and small plaques compared to wild-type controls. No p28 or p65 was detected in cells infected with predicted noncleaving CS1 mutants or the CS1 deletion mutant; however, a new protein of 93 kDa was detected. All introduced mutations and the deletion were retained during repeated virus passages in culture, and no phenotypic reversion was observed. The results of this study demonstrate that cleavage between p28 and p65 at CS1 is not required for MHV replication. However, proteolytic separation of p28 from p65 is necessary for optimal RNA synthesis and virus growth, suggesting important roles for these proteins in the formation or function of viral replication complexes.     

Attenuation of Mouse Hepatitis Virus by Deletion of the LLRKxGxKG Region of Nsp1

Coronaviruses are a family of large positive-sense RNA viruses that are responsible for a wide range of important veterinary and human diseases. Nsp1 has been shown to have an important role in the pathogenetic mechanisms of coronaviruses in vivo. To assess the function of a relatively conserved domain (LLRKxGxKG) of MHV nsp1, a mutant virus, MHV-nsp1-27D, with a 27 nts (LLRKxGxKG) deletion in nsp1, was constructed using a reverse genetic system with a vaccinia virus vector. The mutant virus had similar growth kinetics to MHV-A59 wild-type virus in 17CI-1 cells, but was highly attenuated in vivo. Moreover, the mutant virus completely protected C57BL/6 mice from a lethal MHV-A59 challenge. To further analyze the mechanism of the attenuation of the mutant virus, changes in reporter gene expression were measured in nsp1- or nsp1-27D-expressing cells; the results showed that nsp1 inhibited reporter gene expression controlled by different promoters, but that this inhibition was reduced for nsp1-27D. The research in vivo and in vitro suggests that the LLRKxGxKG region of nsp1 may play an important role in this process.     

X-ray Structural and Functional Studies of the Three Tandemly Linked Domains of Non-structural Protein 3 (nsp3) from Murine Hepatitis Virus Reveal Conserved Functions

Murine hepatitis virus (MHV) has long served as a model system for the study of coronaviruses. Non-structural protein 3 (nsp3) is the largest nsp in the coronavirus genome, and it contains multiple functional domains that are required for coronavirus replication. Despite the numerous functional studies on MHV and its nsp3 domain, the structure of only one domain in nsp3, the small ubiquitin-like domain 1 (Ubl1), has been determined. We report here the x-ray structure of three tandemly linked domains of MHV nsp3, including the papain-like protease 2 (PLP2) catalytic domain, the ubiquitin-like domain 2 (Ubl2), and a third domain that we call the DPUP (domain preceding Ubl2 and PLP2) domain. DPUP has close structural similarity to the severe acute respiratory syndrome coronavirus unique domain C (SUD-C), suggesting that this domain may not be unique to the severe acute respiratory syndrome coronavirus. The PLP2 catalytic domain was found to have both deubiquitinating and deISGylating isopeptidase activities in addition to proteolytic activity. A computationally derived model of MHV PLP2 bound to ubiquitin was generated, and the potential interactions between ubiquitin and PLP2 were probed by site-directed mutagenesis. These studies extend substantially our structural knowledge of MHV nsp3, providing a platform for further investigation of the role of nsp3 domains in MHV viral replication.     

Identification of mouse hepatitis virus papain-like proteinase 2 activity

Mouse hepatitis virus (MHV) is a 31-kb positive-strand RNA virus that is replicated in the cytoplasm of infected cells by a viral RNA-dependent RNA polymerase, termed the replicase. The replicase is encoded in the 5'-most 22 kb of the genomic RNA, which is translated to produce a polyprotein of >800 kDa. The replicase polyprotein is extensively processed by viral and perhaps cellular proteinases to give rise to a functional replicase complex. To date, two of the MHV replicase-encoded proteinases, papain-like proteinase 1 (PLP1) and the poliovirus 3C-like proteinase (3CLpro), have been shown to process the replicase polyprotein. In this report, we describe the cloning, expression, and activity of the third MHV proteinase domain, PLP2. We show that PLP2 cleaves a substrate encoding the first predicted membrane-spanning domain (MP1) of the replicase polyprotein. Cleavage of MP1 and release of a 150-kDa intermediate, p150, are likely to be important for embedding the replicase complex in cellular membranes. Using an antiserum (anti-D11) directed against the C terminus of the MP1 domain, we verified that p150 encompasses the MP1 domain and identified a 44-kDa protein (p44) as a processed product of p150. Pulse-chase experiments showed that p150 is rapidly generated in MHV-infected cells and that p44 is processed from the p150 precursor. Protease inhibitor studies revealed that unlike 3CLpro activity, PLP2 activity is not sensitive to cysteine protease inhibitor E64d. Furthermore, coexpression studies using the PLP2 domain and a substrate encoding the MP1 cleavage site showed that PLP2 acts efficiently in trans. Site-directed mutagenesis studies confirmed the identification of cysteine 1715 as a catalytic residue of PLP2. This study is the first to report enzymatic activity of the PLP2 domain and to demonstrate that three distinct viral proteinase activities process the MHV replicase polyprotein.     

Murine coronaviruses encoding nsp2 at different genomic loci have altered replication, protein expression, and localization

Partial or complete deletion of several coronavirus nonstructural proteins (nsps), including open reading frame 1a (ORF1a)-encoded nsp2, results in viable mutant proteins with specific replication defects. It is not known whether expression of nsps from alternate locations in the genome can complement replication defects. In this report, we show that the murine hepatitis virus nsp2 sequence was tolerated in ORF1b with an in-frame insertion between nsp13 and nsp14 and in place of ORF4. Alternate encoding or duplication of the nsp2 gene sequence resulted in differences in nsp2 expression, processing, and localization, was neutral or detrimental to replication, and did not complement an ORF1a Δnsp2 replication defect. The results suggest that wild-type genomic organization and expression of nsps are required for optimal replication.     

Coronavirus non-structural protein 1 is a major pathogenicity factor: implications for the rational design of coronavirus vaccines

Attenuated viral vaccines can be generated by targeting essential pathogenicity factors. We report here the rational design of an attenuated recombinant coronavirus vaccine based on a deletion in the coding sequence of the non-structural protein 1 (nsp1). In cell culture, nsp1 of mouse hepatitis virus (MHV), like its SARS-coronavirus homolog, strongly reduced cellular gene expression. The effect of nsp1 on MHV replication in vitro and in vivo was analyzed using a recombinant MHV encoding a deletion in the nsp1-coding sequence. The recombinant MHV nsp1 mutant grew normally in tissue culture, but was severely attenuated in vivo. Replication and spread of the nsp1 mutant virus was restored almost to wild-type levels in type I interferon (IFN) receptor-deficient mice, indicating that nsp1 interferes efficiently with the type I IFN system. Importantly, replication of nsp1 mutant virus in professional antigen-presenting cells such as conventional dendritic cells and macrophages, and induction of type I IFN in plasmacytoid dendritic cells, was not impaired. Furthermore, even low doses of nsp1 mutant MHV elicited potent cytotoxic T cell responses and protected mice against homologous and heterologous virus challenge. Taken together, the presented attenuation strategy provides a paradigm for the development of highly efficient coronavirus vaccines.     

Analysis of murine hepatitis virus strain A59 temperature-sensitive mutant TS-LA6 suggests that nsp10 plays a critical role in polyprotein processing

Coronaviruses are the largest RNA viruses, and their genomes encode replication machinery capable of efficient replication of both positive- and negative-strand viral RNAs as well as enzymes capable of processing large viral polyproteins into putative replication intermediates and mature proteins. A model described recently by Sawicki et al. (S. G. Sawicki, D. L. Sawicki, D. Younker, Y. Meyer, V. Thiel, H. Stokes, and S. G. Siddell, PLoS Pathog. 1:e39, 2005), based upon complementation studies of known temperature-sensitive (TS) mutants of murine hepatitis virus (MHV) strain A59, proposes that an intermediate comprised of nsp4 to nsp10/11 ( approximately 150 kDa) is involved in negative-strand synthesis. Furthermore, the mature forms of nsp4 to nsp10 are thought to serve as cofactors with other replicase proteins to assemble a larger replication complex specifically formed to transcribe positive-strand RNAs. In this study, we introduced a single-amino-acid change (nsp10:Q65E) associated with the TS-LA6 phenotype into nsp10 of the infectious clone of MHV. Growth kinetic studies demonstrated that this mutation was sufficient to generate the TS phenotype at permissive and nonpermissive temperatures. Our results demonstrate that the TS mutant variant of nsp10 inhibits the main protease, 3CLpro, blocking its function completely at the nonpermissive temperature. These results implicate nsp10 as being a critical factor in the activation of 3CLpro function. We discuss how these findings challenge the current hypothesis that nsp4 to nsp10/11 functions as a single cistron in negative-strand RNA synthesis and analyze recent complementation data in light of these new findings.     

Chimeric Exchange of Coronavirus nsp5 Proteases (3CLpro) Identifies Common and Divergent Regulatory Determinants of Protease Activity

Human coronaviruses (CoVs) such as severe acute respiratory syndrome CoV (SARS-CoV) and Middle East respiratory syndrome CoV (MERS-CoV) cause epidemics of severe human respiratory disease. A conserved step of CoV replication is the translation and processing of replicase polyproteins containing 16 nonstructural protein domains (nsp''s 1 to 16). The CoV nsp5 protease (3CLpro; Mpro) processes nsp''s at 11 cleavage sites and is essential for virus replication. CoV nsp5 has a conserved 3-domain structure and catalytic residues. However, the intra- and intermolecular determinants of nsp5 activity and their conservation across divergent CoVs are unknown, in part due to challenges in cultivating many human and zoonotic CoVs. To test for conservation of nsp5 structure-function determinants, we engineered chimeric betacoronavirus murine hepatitis virus (MHV) genomes encoding nsp5 proteases of human and bat alphacoronaviruses and betacoronaviruses. Exchange of nsp5 proteases from HCoV-HKU1 and HCoV-OC43, which share the same genogroup, genogroup 2a, with MHV, allowed for immediate viral recovery with efficient replication albeit with impaired fitness in direct competition with wild-type MHV. Introduction of MHV nsp5 temperature-sensitive mutations into chimeric HKU1 and OC43 nsp5 proteases resulted in clear differences in viability and temperature-sensitive phenotypes compared with MHV nsp5. These data indicate tight genetic linkage and coevolution between nsp5 protease and the genomic background and identify differences in intramolecular networks regulating nsp5 function. Our results also provide evidence that chimeric viruses within coronavirus genogroups can be used to test nsp5 determinants of function and inhibition in common isogenic backgrounds and cell types.     

Severe acute respiratory syndrome coronavirus nsp1 suppresses host gene expression, including that of type I interferon, in infected cells

The severe acute respiratory syndrome coronavirus (SARS-CoV) nsp1 protein has unique biological functions that have not been described in the viral proteins of any RNA viruses; expressed SARS-CoV nsp1 protein has been found to suppress host gene expression by promoting host mRNA degradation and inhibiting translation. We generated an nsp1 mutant (nsp1-mt) that neither promoted host mRNA degradation nor suppressed host protein synthesis in expressing cells. Both a SARS-CoV mutant virus, encoding the nsp1-mt protein (SARS-CoV-mt), and a wild-type virus (SARS-CoV-WT) replicated efficiently and exhibited similar one-step growth kinetics in susceptible cells. Both viruses accumulated similar amounts of virus-specific mRNAs and nsp1 protein in infected cells, whereas the amounts of endogenous host mRNAs were clearly higher in SARS-CoV-mt-infected cells than in SARS-CoV-WT-infected cells, in both the presence and absence of actinomycin D. Further, SARS-CoV-WT replication strongly inhibited host protein synthesis, whereas host protein synthesis inhibition in SARS-CoV-mt-infected cells was not as efficient as in SARS-CoV-WT-infected cells. These data revealed that nsp1 indeed promoted host mRNA degradation and contributed to host protein translation inhibition in infected cells. Notably, SARS-CoV-mt infection, but not SARS-CoV-WT infection, induced high levels of beta interferon (IFN) mRNA accumulation and high titers of type I IFN production. These data demonstrated that SARS-CoV nsp1 suppressed host innate immune functions, including type I IFN expression, in infected cells and suggested that SARS-CoV nsp1 most probably plays a critical role in SARS-CoV virulence.