Replication of the coronavirus genome requires continuous RNA synthesis, whereas transcription is a discontinuous process unique among RNA viruses. Transcription includes a template switch during the synthesis of subgenomic negative-strand RNAs to add a copy of the leader sequence. Coronavirus transcription is regulated by multiple factors, including the extent of base-pairing between transcription-regulating sequences of positive and negative polarity, viral and cell protein–RNA binding, and high-order RNA-RNA interactions. Coronavirus RNA synthesis is performed by a replication-transcription complex that includes viral and cell proteins that recognize cis-acting RNA elements mainly located in the highly structured 5′ and 3′ untranslated regions. In addition to many viral nonstructural proteins, the presence of cell nuclear proteins and the viral nucleocapsid protein increases virus amplification efficacy. Coronavirus RNA synthesis is connected with the formation of double-membrane vesicles and convoluted membranes. Coronaviruses encode proofreading machinery, unique in the RNA virus world, to ensure the maintenance of their large genome size.
Middle East respiratory syndrome coronavirus (MERS-CoV) is an emerging coronavirus infecting humans that is associated with acute pneumonia, occasional renal failure, and a high mortality rate and is considered a threat to public health. The construction of a full-length infectious cDNA clone of the MERS-CoV genome in a bacterial artificial chromosome is reported here, providing a reverse genetics system to study the molecular biology of the virus and to develop attenuated viruses as vaccine candidates. Following transfection with the cDNA clone, infectious virus was rescued in both Vero A66 and Huh-7 cells. Recombinant MERS-CoVs (rMERS-CoVs) lacking the accessory genes 3, 4a, 4b, and 5 were successfully rescued from cDNA clones with these genes deleted. The mutant viruses presented growth kinetics similar to those of the wild-type virus, indicating that accessory genes were not essential for MERS-CoV replication in cell cultures. In contrast, an engineered mutant virus lacking the structural E protein (rMERS-CoV-ΔE) was not successfully rescued, since viral infectivity was lost at early passages. Interestingly, the rMERS-CoV-ΔE genome replicated after cDNA clone was transfected into cells. The infectious virus was rescued and propagated in cells expressing the E protein in trans, indicating that this virus was replication competent and propagation defective. Therefore, the rMERS-CoV-ΔE mutant virus is potentially a safe and promising vaccine candidate to prevent MERS-CoV infection.IMPORTANCE Since the emergence of MERS-CoV in the Arabian Peninsula during the summer of 2012, it has already spread to 10 different countries, infecting around 94 persons and showing a mortality rate higher than 50%. This article describes the development of the first reverse genetics system for MERS-CoV, based on the construction of an infectious cDNA clone inserted into a bacterial artificial chromosome. Using this system, a collection of rMERS-CoV deletion mutants has been generated. Interestingly, one of the mutants with the E gene deleted was a replication-competent, propagation-defective virus that could only be grown in the laboratory by providing E protein in trans, whereas it would only survive a single virus infection cycle in vivo. This virus constitutes a vaccine candidate that may represent a balance between safety and efficacy for the induction of mucosal immunity, which is needed to prevent MERS-CoV infection.
The engineering of a full-length infectious cDNA clone and a functional replicon of the severe acute respiratory syndrome coronavirus (SARS-CoV) Urbani strain as bacterial artificial chromosomes (BACs) is described in this study. In this system, the viral RNA was expressed in the cell nucleus under the control of the cytomegalovirus promoter and further amplified in the cytoplasm by the viral replicase. Both the infectious clone and the replicon were fully stable in Escherichia coli. Using the SARS-CoV replicon, we have shown that the recently described RNA-processing enzymes exoribonuclease, endoribonuclease, and 2-O-ribose methyltransferase were essential for efficient coronavirus RNA synthesis. The SARS reverse genetic system developed as a BAC constitutes a useful tool for the study of fundamental viral processes and also for developing genetically defined vaccines.The etiologic agent causing severe acute respiratory syndrome (SARS) is a novel coronavirus (CoV) (8,10,(16)(17)(18)21). This virus causes a life-threatening respiratory disease for which no fully efficacious therapy is available. SARS-CoV is a member of group 2 of the Coronaviridae family within the order Nidovirales (13), which is composed of enveloped, singlestranded, positive-sense RNA viruses relevant in animal and human health (5, 9). Two-thirds of the 29.7-kb SARS-CoV genome carries the replicase gene, which comprises two overlapping open reading frames, ORF 1a and ORF 1b, the latter being translated by a ribosomal frameshift mechanism (29). Translation of both ORFs results in the synthesis of two polyproteins that are processed by viral proteinases to release the components of the replication-transcription complex (36,37). Besides containing RNA-dependent RNA polymerase, RNA helicase, and proteases (4,12,15,23,37), which are all common to positive-strand RNA viruses, the CoV replicase was recently predicted to contain a variety of RNA-processing enzymes that are extremely rare or absent in other RNA viruses, including endoribonuclease (NendoU), 3Ј-to-5Ј exoribonuclease (ExoN), 2Ј-O-ribose methyltransferase (2Ј-O-MT), ADP ribose 1ЈЈ-phosphatase, and, in a subset of group 2 coronaviruses, cyclic phosphodiesterase (25, 36). These enzymatic activities might be involved in the replication of the largest known RNA virus genome and in the production of an extensive set of 5Ј-and 3Ј-coterminal subgenomic RNAs (11,14,25,36).The study of CoV molecular biology has been profoundly advanced by the recent construction of full-length cDNA clones (3,6,26,27,(32)(33)(34) and self-replicating RNAs, or replicons (2,28,30). Due to the large size of the CoV RNA genome and the instability of some CoV replicase gene sequences in bacteria, cDNA clones and replicons have been engineered using bacterial artificial chromosomes (BACs) (3), in vitro ligation of CoV cDNA fragments (32), and vaccinia virus as a vector for the propagation of CoV full-length cDNAs (27). Recently, a SARS-CoV full-length cDNA clone has been generated by the approach of using the in vitro li...
Coronavirus transcription leads to the synthesis of a nested set of mRNAs with a leader sequence derived from the 5 end of the genome. The mRNAs are produced by a discontinuous transcription in which the leader is linked to the mRNA coding sequences. This process is regulated by transcription-regulating sequences (TRSs) preceding each mRNA, including a highly conserved core sequence (CS) with high identity to sequences present in the virus genome and at the 3 end of the leader (TRS-L). The role of TRSs was analyzed by reverse genetics using a full-length infectious coronavirus cDNA and site-directed mutagenesis of the CS. The canonical CS-B was nonessential for the generation of subgenomic mRNAs (sgmRNAs), but its presence led to transcription levels at least 10 3 -fold higher than those in its absence. The data obtained are compatible with a transcription mechanism including three steps: (i) formation of 5-3 complexes in the genomic RNA, (ii) base-pairing scanning of the nascent negative RNA strand by the TRS-L, and (iii) template switching during synthesis of the negative strand to complete the negative sgRNA. This template switch takes place after copying the CS sequence and was predicted in silico based on high base-pairing score between the nascent negative RNA strand and the TRS-L and minimum ⌬G.Transmissible gastroenteritis virus (TGEV) is a member of the Coronaviridae family, included in the Nidovirales order (10). TGEV is an enveloped virus with a single-stranded, positive-sense 28.5-kb RNA genome (28) for which infectious cDNA clones have been engineered (1,12,41). About the 5Ј two-thirds of the entire RNA comprises open reading frames (ORFs) 1a and 1ab encoding the replicase (rep). The 3Ј onethird of the genome includes the genes encoding the structural and nonstructural proteins, in the order 5Ј-S-3a-3b-E-M-N-7-3Ј (9).Coronavirus transcription is based on RNA-dependent RNA synthesis. The result of this process is the generation of a nested set of six to eight mRNAs of various sizes, depending on the coronavirus strain. These mRNAs are 5Ј-and 3Ј-coterminal with the genome. The largest mRNA is the genomic RNA (gRNA), which also serves as the mRNA for the rep1a and rep1b genes. A leader sequence of 93 nucleotides (nt), derived from the 5Ј end of the genome, is fused to the 5Ј end of the mRNA coding sequence (body) by a discontinuous transcription mechanism (18,32).Sequences at the 5Ј end of each gene represent signals that regulate the discontinuous transcription of subgenomic mRNAs (sgmRNAs). These are the transcription-regulating sequences (TRSs) that include a core sequence (CS; 5Ј-CUA AAC-3Ј), highly conserved in all TGEV genes, and the 5Ј and 3Ј flanking sequences (5Ј TRS and 3Ј TRS, respectively) that modulate transcription (2). Previous studies using TGEV minigenomes have shown that the CS was required for transcription and that the synthesis of sgmRNAs only proceeds when this CS is located in an appropriate sequence context (2).Two major models have been proposed to explain the discontinuous tra...
Infection by different coronaviruses (CoVs) causes alterations in the transcriptional and translational patterns, cell cycle, cytoskeleton, and apoptosis pathways of the host cells. In addition, CoV infection may cause inflammation, alter immune and stress responses, and modify the coagulation pathways. The balance between the up- and downregulated genes could explain the pathogenesis caused by these viruses. We review specific aspects of CoV-host interactions. CoV genome replication takes place in the cytoplasm in a membrane-protected microenvironment and may control the cell machinery by locating some of their proteins in the host cell nucleus. CoVs initiate translation by cap-dependent and cap-independent mechanisms. CoV transcription involves a discontinuous RNA synthesis (template switching) during the extension of a negative copy of the subgenomic mRNAs. The requirement for base-pairing during transcription has been formally demonstrated in arteriviruses and CoVs. CoV N proteins have RNA chaperone activity that may help initiate template switching. Both viral and cellular proteins are required for replication and transcription, and the role of selected proteins is addressed.
The generation of subgenomic mRNAs in coronavirus involves a discontinuous mechanism of transcription by which the common leader sequence, derived from the genome 5 terminus, is fused to the 5 end of the mRNA coding sequence (body). Transcription-regulating sequences (TRSs) precede each gene and include a conserved core sequence (CS) surrounded by relatively variable sequences (5 TRS and 3 TRS). Regulation of transcription in coronaviruses has been studied by reverse-genetics analysis of the sequences immediately flanking a unique CS in the Transmissible gastroenteritis virus genome (CS-S2), located inside the S gene, that does not lead to detectable amounts of the corresponding mRNA, in spite of its canonical sequence. The transcriptional inactivity of CS-S2 was genome position independent. The presence of a canonical CS was not sufficient to drive transcription, but subgenomic synthesis requires a minimum base pairing between the leader TRS (TRS-L) and the complement of the body TRS (cTRS-B) provided by the CS and its adjacent nucleotides. A good correlation was observed between the free energy of TRS-L and cTRS-B duplex formation and the levels of subgenomic mRNA S2, demonstrating that base pairing between the leader and body beyond the CS is a determinant regulation factor in coronavirus transcription. In TRS mutants with increasing complementarity between TRS-L and cTRS-B, a tendency to reach a plateau in ⌬G values was observed, suggesting that a more precise definition of the TRS limits might be proposed, specifically that it consists of the central CS and around 4 nucleotides flanking 5 and 3 the CS. Sequences downstream of the CS exert a stronger influence on the template-switching decision according to a model of polymerase strand transfer and template switching during minus-strand synthesis.Transmissible gastroenteritis virus (TGEV) is a member of the Coronaviridae family, included in the Nidovirales order (7). TGEV is an enveloped virus with a single-stranded, positivesense 28.5-kb RNA genome (27). About the 5Ј two-thirds of the entire RNA comprises open reading frames (ORFs) 1a and 1ab, which encode the replicase (rep). The 3Ј one-third of the genome includes the genes encoding structural and nonstructural proteins (5Ј-S-3a-3b-E-M-N-7-3Ј). Engineering of the TGEV genome to study fundamental viral processes, such as transcription, has been possible by the construction of TGEV infectious cDNA clones (1,8,40).Coronavirus transcription, and in general transcription in the Nidovirales order, is an RNA-dependent RNA synthesis that includes a discontinuous step during the synthesis of subgenomic mRNAs (sgmRNAs) (16,30). This transcription process ultimately generates a nested set of sgmRNAs that are 5Ј-and 3Ј-coterminal with the virus genome. The common 5Ј-terminal leader sequence of 93 nucleotides (nt), derived from the genome 5Ј terminus, is fused to the 5Ј end of the mRNA coding sequence (body) by a discontinuous transcription mechanism. Sequences preceding each gene represent signals for the discontinuo...
Coronavirus (CoV) RNA synthesis includes the replication of the viral genome, and the transcription of sgRNAs by a discontinuous mechanism. Both processes are regulated by RNA sequences such as the 5' and 3' untranslated regions (UTRs), and the transcription regulating sequences (TRSs) of the leader (TRS-L) and those preceding each gene (TRS-Bs). These distant RNA regulatory sequences interact with each other directly and probably through protein-RNA and protein-protein interactions involving viral and cellular proteins. By analogy to other plus-stranded RNA viruses, such as polioviruses, in which translation and replication switch involves a cellular factor (PCBP) and a viral protein (3CD) it is conceivable that in CoVs the switch between replication and transcription is also associated with the binding of proteins that are specifically recruited by the replication or transcription complexes. Complexes between RNA motifs such as TRS-L and the TRS-Bs located along the CoV genome are probably formed previously to the transcription start, and most likely promote template-switch of the nascent minus RNA to the TRS-L region. Many cellular proteins interacting with regulatory CoV RNA sequences are members of the heterogeneous nuclear ribonucleoprotein (hnRNP) family of RNA-binding proteins, involved in mRNA processing and transport, which shuttle between the nucleus and the cytoplasm. In the context of CoV RNA synthesis, these cellular ribonucleoproteins might also participate in RNA-protein complexes to bring into physical proximity TRS-L and distant TRS-B, as proposed for CoV discontinuous transcription. In this review, we summarize RNA-RNA and RNA-protein interactions that represent modest examples of complex quaternary RNA-protein structures required for the fine-tuning of virus replication. Design of chemically defined replication and transcription systems will help to clarify the nature and activity of these structures.
Coronavirus (CoV) nonstructural protein 14 (nsp14) is a 60-kDa protein encoded by the replicase gene that is part of the replication-transcription complex. It is a bifunctional enzyme bearing 3=-to-5= exoribonuclease (ExoN) and guanine-N7-methyltransferase (N7-MTase) activities. ExoN hydrolyzes single-stranded RNAs and double-stranded RNAs (dsRNAs) and is part of a proofreading system responsible for the high fidelity of CoV replication. nsp14 N7-MTase activity is required for viral mRNA cap synthesis and prevents the recognition of viral mRNAs as "non-self" by the host cell. In this work, a set of point mutants affecting different motifs within the ExoN domain of nsp14 was generated, using transmissible gastroenteritis virus as a model of Alphacoronavirus. Mutants lacking ExoN activity were nonviable despite being competent in both viral RNA and protein synthesis. A specific mutation within zinc finger 1 (ZF-C) led to production of a viable virus with growth and viral RNA synthesis kinetics similar to that of the parental virus. Mutant recombinant transmissible gastroenteritis virus (TGEV) ZF-C (rTGEV-ZF-C) caused decreased cytopathic effect and apoptosis compared with the wild-type virus and reduced levels of dsRNA accumulation at late times postinfection. Consequently, the mutant triggered a reduced antiviral response, which was confirmed by evaluating different stages of the dsRNA-induced antiviral pathway. The expression of beta interferon (IFN-), tumor necrosis factor (TNF), and interferon-stimulated genes in cells infected with mutant rTGEV-ZF-C was reduced compared to the levels seen with the parental virus. Overall, our data revealed a potential role for CoV nsp14 in modulation of the innate immune response. IMPORTANCEThe innate immune response is the first line of antiviral defense that culminates in the synthesis of interferon and proinflammatory cytokines to control viral replication. CoVs have evolved several mechanisms to counteract the innate immune response at different levels, but the role of CoV-encoded ribonucleases in preventing activation of the dsRNA-induced antiviral response has not been described to date. The introduction of a mutation in zinc finger 1 of the ExoN domain of nsp14 led to production of a virus that induced a weak antiviral response, most likely due to the accumulation of lower levels of dsRNA in the late phases of infection. These observations allowed us to propose a novel role for CoV nsp14 ExoN activity in counteracting the antiviral response, which could serve as a novel target for the design of antiviral strategies.
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