Correction to: Recommendations for the nomenclature of enteroviruses and rhinoviruses.

Unfortunately, one of the affiliations of author "A. E. Gorbalenya" was missed in original version. The affiliation is updated here.

Recommendations for the nomenclature of enteroviruses and rhinoviruses.

Enteroviruses (EVs) and rhinoviruses (RVs) are significant pathogens of humans and are the subject of intensive clinical and epidemiological research and public health measures, notably in the eradication of poliovirus and in the investigation and control of emerging pathogenic EV types worldwide. EVs and RVs are highly diverse in their antigenic properties, tissue tropism, disease associations and evolutionary relationships, but the latter often conflict with previously developed biologically defined terms, such as "coxsackieviruses", "polioviruses" and "echoviruses", which were used before their genetic interrelationships were understood. This has created widespread formatting problems and inconsistencies in the nomenclature for EV and RV types and species in the literature and public databases. As members of the International Committee for Taxonomy of Viruses (ICTV) Picornaviridae Study Group, we describe the correct use of taxon names for these viruses and have produced a series of recommendations for the nomenclature of EV and RV types and their abbreviations. We believe their adoption will promote greater clarity and consistency in the terminology used in the scientific and medical literature. The recommendations will additionally provide a useful reference guide for journals, other publications and public databases seeking to use standardised terms for the growing multitude of enteroviruses and rhinoviruses described worldwide.

ICTV Virus Taxonomy Profile: Picornaviridae.

The family Picornaviridae comprises small non-enveloped viruses with RNA genomes of 6.7 to 10.1 kb, and contains >30 genera and >75 species. Most of the known picornaviruses infect mammals and birds, but some have also been detected in reptiles, amphibians and fish. Many picornaviruses are important human and veterinary pathogens and may cause diseases of the central nervous system, heart, liver, skin, gastrointestinal tract or upper respiratory tract. Most picornaviruses are transmitted by the faecal-oral or respiratory routes. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the taxonomy of the Picornaviridae, which is available at www.ictv.global/report/picornaviridae.

Vaccinia virus G1 protein: absence of autocatalytic self-processing.

Vaccinia virus relies on a series of proteolytic cleavage events involving two viral proteins, I7 and G1, to complete its life cycle. Furthermore, G1 itself is cleaved during vaccinia virus infection. However, convincing evidence is lacking to show whether G1 participates in autoproteolysis or is a substrate of another protease. We employed both biochemical and cell-based approaches to investigate G1 cleavage. G1, when expressed in bacteria, rabbit reticulocyte lysates or HeLa cells, was not processed. Moreover, G1 was cleaved in infected cells, but only in the presence of virus late gene expression; cleavage was strongly inhibited by proteasome inhibitors. Thus, these results imply a more complex G1 cleavage reaction than previously envisaged.

Prevalence of neutralizing antibodies to Equine rhinitis A and B virus in horses and man.

Equine rhinitis viruses (ERVs) are the causative agents of mild to severe upper respiratory infections in horses worldwide. Immunologically, four serotypes of ERVs have been identified. Equine rhinitis A virus (ERAV) and Equine rhinitis B virus 1 (ERBV1) are the most frequent serotypes in Europe. Both viruses have a broad host range in cultured cells with ERAV being able to infect humans. Since there is neither information on the seroprevalence of ERAV and ERBV1 in Austria nor on the zoonotic potential of ERBV1, we investigated 200 horse and 137 veterinary sera for the presence of neutralizing antibodies relating to ERAV and ERBV1. One hundred and eighty (90%) and 173 (86%) horse sera neutralized ERAV and ERBV1, respectively. In contrast, only four (2.7%) and five (3.6%) human sera showed weak neutralizing activity to ERAV and ERBV1, respectively. These results indicate that ERAV and ERBV1 are widespread in the Austrian horse population; however, the risk of acquiring zoonotic infection among veterinarians appears low.

Foot-and-mouth disease virus leader proteinase: involvement of C-terminal residues in self-processing and cleavage of eIF4GI.

The leader proteinase (L(pro)) of foot-and-mouth disease virus frees itself from the nascent polyprotein, cleaving between its own C terminus and the N terminus of VP4 at the sequence Lys-Leu-Lys- downward arrow-Gly-Ala-Gly. Subsequently, the L(pro) impairs protein synthesis from capped mRNAs in the infected cell by processing a host protein, eukaryotic initiation factor 4GI, at the sequence Asn-Leu-Gly- downward arrow-Arg-Thr-Thr. A rabbit reticulocyte lysate system was used to examine the substrate specificity of L(pro) and the relationship of the two cleavage reactions. We show that L(pro) requires a basic residue at one side of the scissile bond to carry out efficient self-processing. This reaction is abrogated when leucine and lysine prior to the cleavage site are substituted by serine and glutamine, respectively. However, the cleavage of eIF4GI is unaffected by the inhibition of self-processing. Removal of the 18-amino acid C-terminal extension of L(pro) slowed eIF4GI cleavage; replacement of the C-terminal extension by unrelated amino acid sequences further delayed this cleavage. Surprisingly, wild-type L(pro) and the C-terminal variants all processed the polyprotein cleavage site in an intermolecular reaction at the same rate. However, when the polyprotein cleavage site was part of the same polypeptide chain as the wild-type Lb(pro), the rate of processing was much more rapid. These experiments strongly suggest that self-processing is an intramolecular reaction.

Extremely efficient cleavage of eIF4G by picornaviral proteinases L and 2A in vitro.

Certain picornaviruses encode proteinases which cleave the translation initiation factor eIF4G, a member of the eIF4F complex which recruits mRNA to the 40S ribosomal subunit during initiation of protein synthesis in eukaryotes. We have compared the efficiency of eIF4G cleavage in rabbit reticulocyte lysates during translation of mRNAs encoding the foot-and-mouth disease virus leader proteinase (Lpro) or the human rhinovirus 2Apro. Under standard translation conditions, Lpro cleaved 50% of eIF4G within 4 min after initiation of protein synthesis, whereas 2Apro required 15 min. At these times, the molar ratios of proteinase to eIF4G were 1:130 for Lpro and 1:12 for 2Apro, indicating a much more efficient in vitro cleavage than previously observed. The molar ratios are similar to those observed during viral infection in vivo.

Characterization of the active site thiol group of rhinovirus 2A proteinase.

Picornains 2A are cysteine proteases of picornaviruses, a virus family containing several human and animal pathogens. The pH dependencies of the alkylations of picornain 2A of rhinovirus type 2 with iodoacetamide and iodoacetate show two reactive thiol forms, namely the free thiolate ion at high pH and an imidazole assisted thiol group at low pH. Kinetic deuterium isotope effects do not support general base catalysis by the imidazole group, but rather the existence of a catalytically competent thiolate-imidazolium ion-pair. The nature of the ion-pair differs from that of papain, the paradigm of cysteine proteases. The ion-pair is confined to the same, unusually narrow pH range in which the enzyme exhibits catalytic activity.

Structural and biochemical features distinguish the foot-and-mouth disease virus leader proteinase from other papain-like enzymes.

The structures of the two leader protease (Lpro) variants of foot-and-mouth disease virus known to date were solved using crystals in which molecules were organized as molecular fibers. Such crystals diffract to a resolution of only approximately 3 A. This singular, pseudo-polymeric organization is present in a new Lpro crystal form showing a cubic packing. As molecular fiber formation appeared unrelated to crystallization conditions, we mutated the reactive cysteine 133 residue, which makes a disulfide bridge between adjacent monomers in the fibers, to serine. None of the intermolecular contacts found in the molecular fibers was present in crystals of this variant. Analysis of this Lpro structure, refined at 1.9 A resolution, enables a detailed definition of the active center of the enzyme, including the solvent organization. Assay of Lpro activity on a fluorescent hexapeptide substrate showed that Lpro, in contrast to papain, was highly sensitive to increases in the cation concentration and was active only across a narrow pH range. Examination of the Lpro structure revealed that three aspartate residues near the active site, not present in papain-like enzymes, are probably responsible for these properties.

Rhinovirus 2A proteinase mediated stimulation of rhinovirus RNA translation is additive to the stimulation effected by cellular RNA binding proteins.

The internal ribosome entry site (IRES) of enteroviruses, and especially human rhinoviruses (HRV), functions very inefficiently in rabbit reticulocyte lysates, but can be stimulated by addition of HeLa cell extracts. Two HeLa cell activities have been identified: the A-type activity is due to polypyrimidine tract binding protein and the B-type to unr. In addition HRV and enterovirus IRES function requires a third RNA binding protein, poly(rC) binding protein 2, but this is present in reticulocyte lysates in non-limiting amounts. IRES activity can also be stimulated by the cleavage of initiation factor eIF4G mediated by either HRV 2A protease, or foot-and-mouth disease virus (FMDV) L protease. This raises the question of whether this stimulation is independent of that effected by the three RNA binding proteins, or whether cleaved eIF4G functionally mimics one or more of these proteins. It is shown here that the stimulation of HRV IRES activity resulting from cleavage of eIF4G is additive with the stimulation effected by HeLa cell A- and B-type activities. It is proposed that the role of the RNA binding proteins is to maintain or attain the appropriate 3-dimensional structure of the IRES RNA element, whereas the function of eIF4G is to deliver the 40S ribosomal subunit to the correct site on the IRES, a function which, for reasons not yet fully understood, is fulfilled more efficiently by the C-terminal cleavage product of eIF4G than by the intact factor.

The structures of picornaviral proteinases.

Picornaviruses are a family of positive-strand RNA viruses the members of which include poliovirus, hepatitis A virus, rhinovirus, foot-and-mouth disease virus and encephalomyocarditis virus. The genetic information contained in the single-stranded, positive sense RNA genome is expressed as a single protein of around 2000 amino acids. This primary product of protein synthesis, designated the polyprotein, is subsequently cleaved into the mature viral proteins by proteinases present within it. The properties of the three defined proteolytic activities present in the picornaviruses are reviewed and the three-dimensional structures of the hepatitis A 3C proteinase and the leader proteinase of foot-and-mouth disease virus as well as a model of the structure of the HRV2 2A proteinase are compared with those of chymotrypsin, papain and streptomyces griseus A proteinase, respectively.

The structure of the 2A proteinase from a common cold virus: a proteinase responsible for the shut-off of host-cell protein synthesis.

The crystal structure of the 2A proteinase from human rhinovirus serotype 2 (HRV2-2A(pro)) has been solved to 1.95 A resolution. The structure has an unusual, although chymotrypsin-related, fold comprising a unique four-stranded beta sheet as the N-terminal domain and a six-stranded beta barrel as the C-terminal domain. A tightly bound zinc ion, essential for the stability of HRV2-2A(pro), is tetrahedrally coordinated by three cysteine sulfurs and one histidine nitrogen. The active site consists of a catalytic triad formed by His18, Asp35 and Cys106. Asp35 is additionally involved in an extensive hydrogen-bonding network. Modelling studies reveal a substrate-induced fit that explains the specificity of the subsites S4, S2, S1 and S1'. The structure of HRV2-2A(pro) suggests the mechanism of the cis cleavage and its release from the polyprotein.

Characterization of the translation-dependent step during iron-regulated decay of transferrin receptor mRNA.

Iron regulates the stability of the mRNA encoding the transferrin receptor (TfR). When iron is scarce, iron regulatory proteins (IRPs) stabilize TfR mRNA by binding to the 3'-untranslated region. High levels of iron induce degradation of TfR mRNA; the translation inhibitor cycloheximide prevents this. To distinguish between cotranslational mRNA decay and a trans effect of translation inhibitors, we designed a reporter system exploiting the properties of the selectable marker gene thymidine kinase (TK). The 3'-untranslated region of human transferrin receptor, which contains all elements necessary for iron-dependent regulation of mRNA stability, was fused to the TK cDNA. In stably transfected mouse fibroblasts, the expression of the reporter gene was perfectly regulated by iron. Introduction of stop codons in the TK coding sequence or insertion of stable stem-loop structures in the leader sequence did not affect on the iron-dependent regulation of the reporter mRNA. This implies that global translation inhibitors stabilize TfR mRNA in trans. Cycloheximide prevented the destabilization of TfR mRNA only in the presence of active IRPs. Inhibition of IRP inactivation by cycloheximide or by the specific proteasome inhibitor MG132 correlated with the stabilization of TfR mRNA. These observations suggest that inhibition of translation by cycloheximide interferes with the rate-limiting step of iron-induced TfR mRNA decay in a trans-acting mechanism by blocking IRP inactivation.

Structure of the foot-and-mouth disease virus leader protease: a papain-like fold adapted for self-processing and eIF4G recognition.

The leader protease of foot-and-mouth disease virus, as well as cleaving itself from the nascent viral polyprotein, disables host cell protein synthesis by specific proteolysis of a cellular protein: the eukaryotic initiation factor 4G (eIF4G). The crystal structure of the leader protease presented here comprises a globular catalytic domain reminiscent of that of cysteine proteases of the papain superfamily, and a flexible C-terminal extension found intruding into the substrate-binding site of an adjacent molecule. Nevertheless, the relative disposition of this extension and the globular domain to each other supports intramolecular self-processing. The different sequences of the two substrates cleaved during viral replication, the viral polyprotein (at LysLeuLys/GlyAlaGly) and eIF4G (at AsnLeuGly/ArgThrThr), appear to be recognized by distinct features in a narrow, negatively charged groove traversing the active centre. The structure illustrates how the prototype papain fold has been adapted to the requirements of an RNA virus. Thus, the protein scaffold has been reduced to a minimum core domain, with the active site being modified to increase specificity. Furthermore, surface features have been developed which enable C-terminal self-processing from the viral polyprotein.

A structural model of picornavirus leader proteinases based on papain and bleomycin hydrolase.

The leader (L) proteinases of aphthoviruses (foot-and-mouth disease viruses) and equine rhinovirus serotypes 1 and 2 cleave themselves from the growing polyprotein. This cleavage occurs intramolecularly between the C terminus of the L proteinases and the N terminus of the subsequent protein VP4. The foot-and-mouth disease virus enzyme has been shown, in addition, to cleave at least one cellular protein, the eukaryotic initiation factor 4G. Mechanistically, inhibitor studies and sequence analysis have been used to classify the L proteinases as papain-like cysteine proteinases. However, sequence identity within the L proteinases themselves is low (between 18% and 32%) and only 14% between the L proteinases and papain. Secondary structure predictions, sequence alignments that take into account the positions of the essential catalytic residues, and structural considerations have been used in this study to investigate more closely the relationships between the L proteinases and papain. In spite of the low sequence identities, the analyses strongly suggest that the L proteinases of foot-and-mouth disease virus and of equine rhinovirus 1 have a similar overall fold to that of papain. Regions in the L proteinases corresponding to all five alpha-helices and seven beta-sheets of papain could be identified. Further comparisons with the proteinase bleomycin hydrolase, which also displays a papain topology in spite of important differences in size and amino acid sequence, support these conclusions and suggest how a C-terminal extension, present in all three L proteinases, and predicted to be an alpha-helix, might enable C-terminal self-processing to occur.

Mutational analyses support a model for the HRV2 2A proteinase.

The proteinase 2A of human rhinovirus 2 is a cysteine proteinase which contains a tightly bound Zn ion thought to be required for structural integrity. A three-dimensional model for human rhinovirus type 2 proteinase 2A (HRV2 2A) was established using sequence alignments with small trypsin-like Ser-proteinases and, for certain regions, elastase. The model was tested by expressing selected proteinase 2A mutants in bacteria and examining the effect on both intramolecular ("cis") and intermolecular ("trans") activities. The HRV2 proteinase 2A is proposed to have a two domain structure, with the catalytic site and substrate binding region on one face of the molecule and a Zn-binding motif on the opposite face. Residues Gly 123, Gly 124, Thr 121, and Cys 101 are proposed to be involved in the architecture of the substrate binding pocket and to provide the correct environment for the catalytic triad of His 18, Asp 35, and Cys 106. Residues Tyr 85 and Tyr 86 are thought to participate in substrate recognition. The presence of an extensive C-terminal helix, in which Asp 132, Arg 134, Phe 130, and Phe 136 play important roles, explains why mutations in this region are generally detrimental to proteinase activity. The proposed Zn-binding motif comprises Cys 52, Cys 54, Cys 112, and His 114. Exchange of these residues inactivates the enzyme. Furthermore, as measured by atom emission spectroscopy, Zn was absent from purified preparations of proteinase 2A in which His 114 had been replaced by Asn. The absence of disulphide bridges was confirmed by subjecting highly purified HRV2 proteinase 2A to one- and two-step alkylation procedures.

elF4G and its proteolytic cleavage products: effect on initiation of protein synthesis from capped, uncapped, and IRES-containing mRNAs.

Rhinovirus 2A and foot-and-mouth disease virus Lb proteinases stimulate the translation of uncapped messages and those carrying the rhinovirus and enterovirus Internal Ribosome Entry Segments (IRESes) by a mechanism involving the cleavage of host cell proteins. Here, we investigate this mechanism using an artificial dicistronic RNA containing the human rhinovirus IRES as intercistronic spacer. Because both proteinases cleave eukaryotic initiation factor 4G (eIF4G), we examined whether the cleavage products of eIF4G could stimulate uncapped or IRES-driven translation. Addition of intact eIF4F to translation extracts inhibited IRES-driven translation and reduced the translation stimulation observed in reactions pre-treated with Lb proteinase. Prolonged incubation of translation extracts with Lb proteinase removed all endogenous eIF4G and a substantial amount of the primary C- and N-terminal cleavage products. The translation of all mRNAs was reduced in such extracts. Capped mRNA translation was rescued by the addition of intact eIF4F. In contrast, addition of pre-cleaved eIF4F stimulated translation of uncapped or IRES-bearing messages to the levels seen upon proteinase addition. Furthermore, fractions containing the C-terminal, but not N-terminal, cleavage product of eIF4G stimulated translation moderately. These results demonstrate that the Lb and 2A proteinases stimulate translation of uncapped RNAs and those carrying IRESes by the production of cleavage products of eIF4G that enhance translation and by the removal of intact eIF4G that interferes with this stimulation.

The eIF4G-eIF4E complex is the target for direct cleavage by the rhinovirus 2A proteinase.

The 2A proteinases (2Apro) of certain picornaviruses induce the cleavage of the eIF4G subunit of the cap-binding protein complex, eIF4F. Several reports have demonstrated that 2Apro of rhinovirus and coxsackievirus B4 cleave eIF4G directly. However, it was suggested that in poliovirus infection, the 2Apro induces the activation of a cellular proteinase which in turn cleaves eIF4G. Furthermore, it is not clear whether eIF4G is cleaved as part of the eIF4F complex or as an individual polypeptide. To address these issues, recombinant eIF4G was purified from Sf9 insect cells and tested for cleavage by purified rhinovirus 2Apro. Here we report that eIF4G alone is a relatively poor substrate for cleavage by the rhinovirus 2Apro. However, an eIF4G-eIF4E complex is cleaved efficiently by the 2Apro, suggesting that eIF4F is a preferred substrate for cleavage by rhinovirus 2Apro. Furthermore, 2Apr drastically reduced the translation of a capped mRNA. An eIF4G-eIF4E complex, but not eIF4G alone, was required to restore translation.

Molecular characterization of a tissue-polypeptide-specific-antigen epitope and its relationship to human cytokeratin 18.

Tissue-polypeptide-specific antigen (TPS) from the human colon adenocarcinoma cell line WiDr was purified using the monoclonal antibody M3 as a probe. Upon SDS/polyacrylamide gradient gel electrophoresis, several TPS-positive bands were detected (corresponding to 13 kDa, 22 kDa and a doublet at 42 kDa). The 13-kDa moiety was purified about 30,000-fold by a 5-step protocol. The electro-phoretically homogeneous component was obtained in a 7% yield of the total TPS activity of the crude extract. N-terminal sequence analysis showed the presence of an N-terminally truncated molecule and identified the 13-kDa TPS component as a fragment of human cytokeratin 18, with a major from starting at position 284 of the parent molecule. Laser-desorption mass spectrometry showed the presence of one major component with a molecular mass corresponding to a C-terminal end close to position 396 (which gives 12776 Da for the form with non-truncated N-terminus). The M3 antibody was also used to screen a human prostate cDNA lambda gt11 library. Four identical phage clones were detected, each producing a fusion protein with beta-galactosidase and the M3-positive component. PCR amplification showed the presence of an approximately 1200-bp insert, and sequence analysis revealed it to contain a 996-nucleotide fragment corresponding to residues 103-429 of human cytokeratin 18 (plus a non-coding human desmin artifact fragment). Smaller fragments, engineered by PCR and expressed as fusion proteins using the pET3xc vector in Escherichia coli, showed that the M3 epitope is localized to cytokeratin 18, residues 322-340. Two other TPS-active monoclonal antibodies were localized to cytokeratin 18 with similar techniques, ascribing an epitope (to M21) to residues 414-429 and another (to M24) to residues 139-297. Combined, the results demonstrate that TPS reactivity is derived from specific epitopes of human cytokeratin 18.