Structure and Function of Caliciviral RNA Polymerases.

Caliciviruses are a leading agent of human and animal gastroenteritis and respiratory tract infections, which are growing concerns in immunocompromised individuals. However, no vaccines or therapeutics are yet available. Since the rapid rate of genetic evolution of caliciviruses is mainly due to the error-prone nature of RNA-dependent RNA polymerase (RdRp), this article focuses on recent studies of the structures and functions of RdRp from caliciviruses. It also provides recent advances in the interactions of RdRp with virion protein genome-linked (VPg) and RNA and the structural and functional features of its precursor.

Substrate specificity of Tulane virus protease.

Tulane virus (TV) is a cultivable calicivirus isolated from rhesus monkeys. In this study, we characterized the substrate specificity of TV protease in trans using recombinant proteases and TV polyprotein fragments containing the predicted proteolytic cleavage sites. Cleavage products have been obtained from 4 of the 5 fragments containing (573)Q-S(574) between the helicase and 3A-like protein, (712)E-A(713) between the 3A-like protein and Vpg, (802)E-G(803) between Vpg and the protease, and (976)E-G(977) between the protease and RdRp. We also characterized the enzymatic activities of the recombinant proteases of TV and Norwalk virus using synthetic fluorogenic peptide substrates. Under optimal conditions for enzymatic assays, partial cross-reactivities on reciprocal substrates were observed between TV and Norwalk virus proteases. The apparently shared substrate specificities between TV and Norwalk virus proteases suggested that the cultivable TV could be used as a model for in vivo evaluation of lead candidates of protease inhibitors for human norovirus.

Comparative site-directed mutagenesis in the catalytic amino acid triad in calicivirus proteases.

Calicivirus proteases cleave the viral precursor polyprotein encoded by open reading frame 1 (ORF1) into multiple intermediate and mature proteins. These proteases have conserved histidine (His), glutamic acid (Glu) or aspartic acid (Asp), and cysteine (Cys) residues that are thought to act as a catalytic triad (i.e. general base, acid and nucleophile, respectively). However, is the triad critical for processing the polyprotein? In the present study, we examined these amino acids in viruses representing the four major genera of Caliciviridae: Norwalk virus (NoV), Rabbit hemorrhagic disease virus (RHDV), Sapporo virus (SaV) and Feline calicivirus (FCV). Using single amino-acid substitutions, we found that an acidic amino acid (Glu or Asp), as well as the His and Cys in the putative catalytic triad, cannot be replaced by Ala for normal processing activity of the ORF1 polyprotein in vitro. Similarly, normal activity is not retained if the nucleophile Cys is replaced with Ser. These results showed the calicivirus protease is a Cys protease and the catalytic triad formation is important for protease activity. Our study is the first to directly compare the proteases of the four representative calicivirus genera. Interestingly, we found that RHDV and SaV proteases critically need the acidic residues during catalysis, whereas proteolytic cleavage occurs normally at several cleavage sites in the ORF1 polyprotein without a functional acid residue in the NoV and FCV proteases. Thus, the substrate recognition mechanism may be different between the SaV and RHDV proteases and the NoV and FCV proteases.

Comparison of the replication properties of murine and human calicivirus RNA-dependent RNA polymerases.

The human caliciviruses (CV), norovirus (NoV) and sapovirus (SaV), are major causes of outbreak gastroenteritis worldwide. To date, the investigation of human NoV and SaV replication cycles has been impeded as neither is culturable. Consequently, the recently discovered murine NoV (MNV) has been adopted as a surrogate replication model for the human CVs. In this study, we sought to compare the biochemical properties of the MNV RNA-dependent RNA polymerase (RdRp) with related human NoV and SaV-RdRps to address the suitability of MNV as a model for the human CVs. Three human NoV-RdRps (GII.b, GII.4 and GII.7), an MNV-RdRp and two human SaV-RdRps (GI and GII) were overexpressed in Escherichia coli, purified and their enzymatic activity and fidelity compared. Despite ~70% amino acid variation between the RdRp from the two different CV genera, the majority of the physiological characteristics of the RdRps were similar. All RdRps exhibited co-operative dimerisation and had optimal activity at 25°C, a pH range between 7 and 8, required 2-5 mM MnCl(2) and were inhibited with increasing NaCl concentrations. We observed RdRp activity at temperatures as low as 5°C and as high as 65°C. Using an in vitro fidelity assay, similar mutation rates were observed for the separate RdRps (1 × 10(-4)-1 × 10(-5)). This is the first report to compare the physiological, biochemical and mutational properties of the MNV-RdRp to those of the human CV-RdRps and it suggests that MNV may be directly applicable to the study of human NoV.

Norovirus proteinase-polymerase and polymerase are both active forms of RNA-dependent RNA polymerase.

In vitro mapping studies of the MD145 norovirus (Caliciviridae) ORF1 polyprotein identified two stable cleavage products containing the viral RNA-dependent RNA polymerase (RdRp) domains: ProPol (a precursor comprised of both the proteinase and polymerase) and Pol (the mature polymerase). The goal of this study was to identify the active form (or forms) of the norovirus polymerase. The recombinant ProPol (expressed as Pro(-)Pol with an inactivated proteinase domain to prevent autocleavage) and recombinant Pol were purified after synthesis in bacteria and shown to be active RdRp enzymes. In addition, the mutant His-E1189A-ProPol protein (with active proteinase but with the natural ProPol cleavage site blocked) was active as an RdRp, confirming that the norovirus ProPol precursor could possess two enzymatic activities simultaneously. The effects of several UTP analogs on the RdRp activity of the norovirus and feline calicivirus Pro(-)Pol enzymes were compared and found to be similar. Our data suggest that the norovirus ProPol is a bifunctional enzyme during virus replication. The availability of this recombinant ProPol enzyme might prove useful in the development of antiviral drugs for control of the noroviruses associated with acute gastroenteritis.

Calicivirus 3C-like proteinase inhibits cellular translation by cleavage of poly(A)-binding protein.

Caliciviruses are single-stranded RNA viruses that cause a wide range of diseases in both humans and animals, but little is known about the regulation of cellular translation during infection. We used two distinct calicivirus strains, MD145-12 (genus Norovirus) and feline calicivirus (FCV) (genus Vesivirus), to investigate potential strategies used by the caliciviruses to inhibit cellular translation. Recombinant 3C-like proteinases (r3CL(pro)) from norovirus and FCV were found to cleave poly(A)-binding protein (PABP) in the absence of other viral proteins. The norovirus r3CL(pro) PABP cleavage products were indistinguishable from those generated by poliovirus (PV) 3C(pro) cleavage, while the FCV r3CL(pro) products differed due to cleavage at an alternate cleavage site 24 amino acids downstream of one of the PV 3C(pro) cleavage sites. All cleavages by calicivirus or PV proteases separated the C-terminal domain of PABP that binds translation factors eIF4B and eRF3 from the N-terminal RNA-binding domain of PABP. The effect of PABP cleavage by the norovirus r3CL(pro) was analyzed in HeLa cell translation extracts, and the presence of r3CL(pro) inhibited translation of both endogenous and exogenous mRNAs. Translation inhibition was poly(A) dependent, and replenishment of the extracts with PABP restored translation. Analysis of FCV-infected feline kidney cells showed that the levels of de novo cellular protein synthesis decreased over time as virus-specific proteins accumulated, and cleavage of PABP occurred in virus-infected cells. Our data indicate that the calicivirus 3CL(pro), like PV 3C(pro), mediates the cleavage of PABP as part of its strategy to inhibit cellular translation. PABP cleavage may be a common mechanism among certain virus families to manipulate cellular translation.

Trans activity of the norovirus Camberwell proteinase and cleavage of the N-terminal protein encoded by ORF1.

The virus-encoded proteinase of Camberwell virus, a genogroup 2 norovirus, was synthesized in Escherichia coli. The purified proteinase had correct N and C termini and showed trans activity in cell-free assays. trans activity was also demonstrated in COS cells transfected with constructs encoding either the proteinase or a proteinase-polymerase fusion. The N-terminal protein of ORF1 was cleaved in COS cells, possibly at the site E(194)/S.

Polypeptide p41 of a Norwalk-like virus is a nucleic acid-independent nucleoside triphosphatase.

Southampton virus (SHV) is a member of the Norwalk-like viruses (NLVs), one of four genera of the family Caliciviridae. The genome of SHV contains three open reading frames (ORFs). ORF 1 encodes a polyprotein that is autocatalytically processed into six proteins, one of which is p41. p41 shares sequence motifs with protein 2C of picornaviruses and superfamily 3 helicases. We have expressed p41 of SHV in bacteria. Purified p41 exhibited nucleoside triphosphate (NTP)-binding and NTP hydrolysis activities. The NTPase activity was not stimulated by single-stranded nucleic acids. SHV p41 had no detectable helicase activity. Protein sequence comparison between the consensus sequences of NLV p41 and enterovirus protein 2C revealed regions of high similarity. According to secondary structure prediction, the conserved regions were located within a putative central domain of alpha helices and beta strands. This study reveals for the first time an NTPase activity associated with a calicivirus-encoded protein. Based on enzymatic properties and sequence information, a functional relationship between NLV p41 and enterovirus 2C is discussed in regard to the role of 2C-like proteins in virus replication.

Complete nucleotide sequence of the chiba virus genome and functional expression of the 3C-like protease in Escherichia coli.

We cloned the genome RNA of the Chiba virus (ChV; Hu/NLV/Chiba 407/1987/JP) and determined its complete nucleotide sequence. The genome is predicted to be a positive-sense, single-stranded RNA of 7697 bases, excluding a poly(A) tract. Comparison of the nucleotide and amino acid sequences with those of other members of the species Norwalk virus (NV) revealed that ChV belongs to genogroup I NV. The ChV genome contains three open reading frames (ORFs). A large 5'-terminal ORF (ORF1) encodes a polyprotein with 1785 amino acids that are likely processed into functional proteins, including RNA helicase, VPg, protease, and RNA-dependent RNA polymerase. ORF2 encodes the capsid protein with 544 amino acids, and a small 3'-terminal ORF (ORF3) encodes a basic protein with 208 amino acids. The amino acid sequences of five cleavage sites in ORF1 are highly conserved compared with those of other members of NV. When expressed in Escherichia coli, the glutathione-S-transferase (GST) fusion protein of the ChV protease connected via a short peptide containing a human rhinovirus 3C protease cleavage site was cleaved into GST and the protease; however, this cleavage did not occur when the Cys mutation was introduced into the putative active site of the protease. Moreover, the ChV protease recognized and cleaved the predicted proteolytic sites between VPg and protease and between protease and RNA polymerase. Therefore, the ChV protease expressed in E. coli retained an enzymatic activity and a substrate specificity similar to that of the human rhinovirus 3C protease.

Design and evaluation of a primer pair that detects both Norwalk- and Sapporo-like caliciviruses by RT-PCR.

A primer pair (p289/290) based on the RNA polymerase sequence of 25 prototype and currently circulating strains of human caliciviruses (HuCVs) was designed for the detection of both Norwalk-like caliciviruses (NLVs) and Sapporo-like caliciviruses (SLVs) by reverse transcription-polymerase chain reaction (RT-PCR). This primer pair produces RT-PCR products of 319 bp for NLVs and 331 bp for SLVs. The usefulness of this primer pair was shown by its detection of prototype NLVs (Norwalk, Snow Mountain, Hawaii and Mexico viruses) and SLVs (Sapporo/82, Hou/86, Hou/90 and Lon/92) and currently circulating strains of NLVs and SLVs in children and adults. This primer pair also detected more viruses in either NLV or SLV genera than previously designed primers. This primer pair is useful for broad detection of HuCVs for clinical and epidemiologic studies as well as for environmental monitoring.

Identification of further proteolytic cleavage sites in the Southampton calicivirus polyprotein by expression of the viral protease in E. coli.

Southampton virus (SV) is a human enteric calicivirus with a positive-sense RNA genome which encodes a protease as part of a large precursor polyprotein. Expression vectors based on pRSET were constructed carrying the entire 3C-like viral protease (3Cpro) sequence together with flanking sequences from a region of the viral genome 3'-distal to the putative helicase-encoding region. Expression from these vectors in E. coli resulted in discrete protein products with smaller than expected molecular sizes. This confirmed that an active viral protease was produced in E. coli and that the protease was capable of cleaving the expressed protein at defined sites. Expressed cleavage products surrounding the protease region of the viral polyprotein were separated by SDS-PAGE, transferred to PVDF membranes and subjected to N-terminal sequence analysis. Cleavage occurred at an EG dipeptide at the N terminus of the putative VPg (961E/GKNKG) and also at the protease/polymerase boundary (1280E/GGDKG). The N terminus of the protease was released from the VPg C terminus at an EA dipeptide in the sequence 1099E/APPTL. These studies demonstrate that SV enteric calicivirus encodes a 3C-like protease with a specificity similar to the picornaviral 3C protease and that the SV polyprotein is cleaved into at least six mature products.

The bovine Newbury agent-2 is genetically more closely related to human SRSVs than to animal caliciviruses.

The hypothesis that the enteric bovine calici-like virus Newbury agent (NA-2) belongs to the family Caliciviridae was examined by genome sequence analysis. Use of solid-phase immune electron microscopy allowed samples with good levels of virus to be identified and amplification of the genome was achieved by reverse transcription-polymerase chain reaction. Examination of a 216-amino-acid sequence in the RNA-dependent RNA polymerase gene and a 116-amino-acid sequence in the capsid gene showed that NA-2 had the closest deduced amino acid identity (77 to 80% for the polymerase region and 67 to 73% for the capsid region) to the morphologically indistinguishable human SRSVs (small round structured viruses) of genogroup 1, which are classified as members of the Caliciviridae. It had a weak relationship (<34.5% deduced amino acid identity) in both the polymerase and the capsid regions to animal caliciviruses, all of which have classical morphology. This is the first genomic data from a nonhuman virus with SRSV morphology. It confirms the hypothesis that the bovine enteric calici-like virus NA-2 is a member of the family Caliciviridae and endorses the observation to date that viruses with SRSV morphology are genomically distinct.

Phylogenetic analysis of the Caliciviruses.

A phylogenetic portrait of the genus Calicivirus in the family Caliciviridae was developed based upon published sequences and newly characterized calicivirus (CV) strains, including additional Sapporo-like HuCV strains in pediatric diarrhea stool specimens from South Africa, the United Kingdom, and the United States. Distance and parsimony methods were applied to nucleotide and amino acid sequences of human and animal calicivirus 3D RNA-dependent RNA polymerase (approximately 470nt) and capsid hypervariable regions (approximately 1,200nt) to generate phylogenetic trees. Pairwise amino acid identity in the 3D region among the Sapporo-like strains ranged from 61% to 100%. Human and animal caliciviruses (HuCVs and AnCVs) separated into five genogroups: small round-structured viruses (SRSV), Sapporo-like, and hepatitis E virus (HEV)-like HuCVs and rabbit-, and vesicular exanthema of swine virus (VESV)-like AnCVs, each with a distinct genome organization. Each genogroup, including the Sapporo-like HuCVs, subdivided further into subgenogroups. The capsid region trees had higher levels of confidence than the 3D region trees and limited conclusions about genogroups could be drawn from the 3D region analyses. This analysis suggested that CVs include five potential virus subfamilies.

Sensitive detection of human Caliciviridae by RT-PCR.

A semi-nested reverse transcriptase-polymerase chain reaction (RT-PCR) was developed for the detection of human Caliciviridae. The method was evaluated on faecal samples from patients with gastroenteritis sent to the Norwegian National Institute of Public Health for routine diagnosis by direct electron microscopy (EM). Of 166 samples, 49 were found to contain Caliciviridae by EM, while 7 samples contained other viruses. A total of 74 samples was positive by PCR, including all the samples with EM detectable Caliciviridae, while specimens containing other agents were negative. Phylogenetic analysis of RNA sequences from 14 Norwegian samples indicated that the viruses present in Norway are evenly distributed when compared to sequences of human Caliciviridae from other countries. The PCR primers should therefore be useful for samples from other regions. The phylogenetic analysis did not cluster viruses with a calici-like morphology, but mingled them with sequences from Norwalk-like viruses, indicating that the two morphological types do not represent separate genogroups.

Identification and characterization of a 3C-like protease from rabbit hemorrhagic disease virus, a calicivirus.

Expression studies conducted in vitro and in Escherichia coli led to the identification of a protease from rabbit hemorrhagic disease virus (RHDV). The gene coding for this protease was found to be located in the central part of the genome preceding the putative RNA polymerase gene. It was demonstrated that the protease specifically cuts RHDV polyprotein substrates both in cis and in trans. Site-directed mutagenesis experiments revealed that the RHDV protease closely resembles the 3C proteases of picornaviruses with respect to the amino acids directly involved in the catalytic activity as well as to the role played by histidine as part of the substrate binding pocket.

Human enteric Caliciviridae: a new prevalent small round-structured virus group defined by RNA-dependent RNA polymerase and capsid diversity.

Sequence comparison of the RNA-dependent RNA polymerases of small round-structured viruses (SRSVs) from 10 recent U.K. outbreaks of gastroenteritis revealed significant genetic variation. Computer analyses indicated that these viruses can be divided into two discrete groups. SRSV group I contains the previously characterized antigenic type 1 Norwalk and type 3 Southampton viruses. The amino acid sequences of the RNA polymerase, capsid and ORF3 of these two viruses are relatively similar (about 92%, 69% and 72% amino acid identity, respectively). A representative member of group II SRSVs, Bristol virus, was subjected to a detailed genetic analysis. Bristol virus is a recent antigenic type 2 isolate from a U.K. hospital outbreak of gastroenteritis. Using a single clinical sample the 3'-terminal 3881 nucleotide cDNA sequence [excluding the poly(A) tail] of this virus was determined. Analysis of the sequence revealed significant differences from those of group I viruses with the RNA polymerase region, capsid and ORF3 showing only about 62%, 43% and 30% amino acid identity respectively with the equivalent proteins of the Norwalk and Southampton viruses. These data suggest that the morphologically identical SRSVs belong to at least two genetically distinct groups.