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.

Ratification vote on taxonomic proposals to the International Committee on Taxonomy of Viruses (2015).

Changes to virus taxonomy approved and ratified by the International Committee on Taxonomy of Viruses in February 2015 are listed.

[The prevalence of the human rhinoviruses and coronaviruses circulating in the Moscow region during 2007-2012].

The rhinoviruses and coronaviruses are the most common causative agents of the acute upper respiratory tract infection in humans. They include several species that vary in the pathogenicity, some causing severe respiratory tract diseases. In this work, the species prevalence of rhinoviruses and coronaviruses was studied in 92 virus-positive clinical patients that were collected at the area of the Moscow region during the period from 2007 to 2012. Using the real-time PCR the virus circulation has been established for all species common in humans, including three rhinoviruses, HRV A, HRV B, and HRV C, and four coronaviruses, HCoV-NL63, HCoV-229E, HCoV-OC43, and HCoV-HKU1. For eight patients, the identity of the rhinoviruses, including 4 cases of HRV-C, 3 cases of HRV-A, and a single case of HRV-B, was corroborated using partial sequencing of the 5 non-coding regions and phylogenetic analysis. The viruses of HRV-C, HCoV-NL63, and HCoV-OC43 were prevalent in children with severe respiratory diseases.

The VIZIER project: preparedness against pathogenic RNA viruses.

Life-threatening RNA viruses emerge regularly, and often in an unpredictable manner. Yet, the very few drugs available against known RNA viruses have sometimes required decades of research for development. Can we generate preparedness for outbreaks of the, as yet, unknown viruses? The VIZIER (VIral enZymes InvolvEd in Replication) (http://www.vizier-europe.org/) project has been set-up to develop the scientific foundations for countering this challenge to society. VIZIER studies the most conserved viral enzymes (that of the replication machinery, or replicases) that constitute attractive targets for drug-design. The aim of VIZIER is to determine as many replicase crystal structures as possible from a carefully selected list of viruses in order to comprehensively cover the diversity of the RNA virus universe, and generate critical knowledge that could be efficiently utilized to jump-start research on any emerging RNA virus. VIZIER is a multidisciplinary project involving (i) bioinformatics to define functional domains, (ii) viral genomics to increase the number of characterized viral genomes and prepare defined targets, (iii) proteomics to express, purify, and characterize targets, (iv) structural biology to solve their crystal structures, and (v) pre-lead discovery to propose active scaffolds of antiviral molecules.

PCR assays for detection of human astroviruses: In silico evaluation and design, and in vitro application to samples collected from patients in the Netherlands.

BACKGROUND: Human astroviruses (HAstV) comprise three phylogenetically compact and non-adjacent groups of species including classical HAstV (HAstV-C) and the novel ones (HAstV-VA/HMO and HAstV-MLB). Of these, HAstV-C is known to be responsible for gastroenteritis while the novel HAstV are associated with cases of neurological disorders. Accurate detection of all known variants by (real-time) PCR is challenging because of the high intra- and intergroup genetic divergence of HAstV. OBJECTIVES: To evaluate published HAstV PCR assays in silico, design de novo real-time PCR assays that can detect and discriminate three groups of HAstV, and apply those to patient samples to analyse the prevalence of HAstV in stool and cerebrospinal fluid (CSF) specimens. STUDY DESIGN: In silico evaluation of published PCR assays and design of real-time PCR assays for detection of different subsets of HAstV was conducted within a common computational framework that used all astrovirus full genome sequences from GenBank. The newly designed real-time PCR assays were evaluated in vitro and applied to faecal samples (collected in January-May 2016) and cerebrospinal fluid specimens (2010-2016) from patients in the Netherlands. RESULTS: Quantitative in silico evaluation of published PCRs is provided. The newly designed real-time PCR assays can reliably assign all available HAstV genome sequences to one of the three phylogenetic groups in silico, and differentiate among HAstV-specific controls in vitro. A total of 556 samples were tested using these PCR assays. Fourteen fecal samples (2.5%) tested positive for HAstV, 3 of which could be identified as the novel HAstV-MLB variants. No novel HAstV were found in CSF specimens. CONCLUSION: Newly designed real-time PCR assays with improved detection of all known HAstV allowed the first-time identification of novel astroviruses from stool samples in the Netherlands.

Superfamily of UvrA-related NTP-binding proteins. Implications for rational classification of recombination/repair systems.

A superfamily of proteins encoded by bacterial, phage and eukaryotic genomes and performing a wide range of NTP-dependent functions was delineated by amino acid sequence comparison. The new superfamily brought together bacterial proteins UvrA, RecF, RecN, MutH and HexA, T4 phage gp46, T5 phage D13 protein, lambda phage EA59 protein and yeast Rad50 protein, all involved in recombination, repair and, in some cases, also in replication of respective genomes, and a family of bacterial and eukaryotic proteins implicated in active transport of various compounds, cell division and nodulation whose relationship to UvrA had been recognized previously. For some of the members of the new superfamily, NTPase activity or NTP-binding capacity have been demonstrated. All these proteins encompassed four distinct conserved sequence motifs, of which two constituted the NTP-binding pattern typical of a vast class of ATP and GTP-binding proteins, whereas the other two were unique for the new superfamily. The new superfamily was characterized by an unusually large span of length variation of polypeptide segments separating the two conserved motifs of the NTP-binding pattern. Sequence similarity was revealed, on the one hand, between the N-terminal NTP-binding domain of UvrA, recN, gp46 and D13, and on the other hand, between the C-terminal NTP-binding domain of UvrA, recF and EA59. Possible relationships between different pathways of DNA repair and recombination are briefly analyzed from the viewpoint of involvement of NTPases of different groups.

Genetic studies on the poliovirus 2C protein, an NTPase. A plausible mechanism of guanidine effect on the 2C function and evidence for the importance of 2C oligomerization.

Poliovirus RNA replication is known to be inhibited by millimolar concentrations of guanidine. A variety of guanidine-resistant (gr) and guanidine-dependent (gd) poliovirus strains were selected, and mutations responsible for the phenotypic alterations were mapped to distinct loci of the viral NTP-binding pattern containing protein 2C. Together with already published results, our data have demonstrated that the overwhelming majority of guanidine mutants of poliovirus 2C can be assigned to one of the two classes, N (with a change in Asn179) or M (with a change in Met187). As inferred from the structure/function relations in other NTP-binding proteins, both these "main" mutations should reside in a loop adjoining the so-called B motif known to interact with the Mg2+ involved in the NTP splitting. In classes M (always) and N (not infrequently), these B motif mutations were combined with mutations in, or close to, motif A (involved in binding of the NTP phosphate moieties) and/or motif C (another conserved element of a subset of NTP-binding proteins). These data strongly support the notion that the region of polypeptide 2C involved in the NTP utilization is affected by the guanidine mutations and by the presence of the drug itself. The mutations, however, never altered highly conserved amino acid residues assumed to be essential for the NTP binding or splitting. These facts and some other considerations led us to propose that guanidine affects coupling between the NTP binding and/or splitting, on the one hand, and the 2C function (related to conformational changes), on the other. Both N and M classes of mutants contain gr and gd variants, and the gr/gd interconversion as well as modulations of the guanidine phenotype can be caused by additional mutations within each class; sometimes, these additional substitutions are located far away from the "main" mutations. It is suggested that the target for guanidine action involves long-range tertiary interactions. Under conditions restrictive for the individual growth of each parent, efficient reciprocal intra-allelic complementation between guanidine-sensitive (gs) and gd strains (of M or N classes) was observed. The complementation occurred at the level of viral RNA synthesis. These data allowed us to propose that oligomerization of polypeptide 2C is an essential step in the replication of viral genome.

Self-splicing group I and group II introns encode homologous (putative) DNA endonucleases of a new family.

A new family of protein domains consisting of 50-80 amino acid residues is described. It is composed of nearly 40 members, including domains encoded by plastid and phage group I introns; mitochondrial, plastid, and bacterial group II introns; eubacterial genomes and plasmids; and phages. The name "EX1HH-HX3H" was coined for both domain and family. It is based on 2 most prominent amino acid sequence motifs, each encompassing a pair of highly conserved histidine residues in a specific arrangement: EX1HH and HX3H. The "His" motifs often alternate with amino- and carboxy-terminal motifs of a new type of Zn-finger-like structure CX2,4CX29-54[CH]X2,3[CH]. The EX1HH-HX3H domain in eubacterial E2-type bacteriocins and in phage RB3 (wild variant of phage T4) product of the nrdB group I intron was reported to be essential for DNA endonuclease activity of these proteins. In other proteins, the EX1HH-HX3H domain is hypothesized to possess DNase activity as well. Presumably, this activity promotes movement (rearrangement) of group I and group II introns encoding the EX1HH-HX3H domain and other gene targets. In the case of Escherichia coli restrictase McrA and possibly several related proteins, it appears to mediate the restriction of alien DNA molecules.

Related domains in yeast tRNA ligase, bacteriophage T4 polynucleotide kinase and RNA ligase, and mammalian myelin 2',3'-cyclic nucleotide phosphohydrolase revealed by amino acid sequence comparison.

Related domains containing the purine NTP-binding sequence pattern have been revealed in two enzymes involved in tRNA processing, yeast tRNA ligase and phage T4 polynucleotide kinase, and in one of the major proteins of mammalian nerve myelin sheath, 2',3'-cyclic nucleotide 3'-phosphohydrolase (CNPase). It is suggested that, similarly to the tRNA processing enzymes, CNPase possesses polynucleotide kinase activity, in addition to the phosphohydrolase one. It is speculated that CNPase may be an authentic mammalian polynucleotide kinase recruited as a structural component of the myelin sheath, analogously to the eye lens crystallins. Significant sequence similarity was revealed also between the N-terminal regions of yeast tRNA ligase and phage T4 RNA ligase. A tentative scheme of the domainal organizations for the three complex enzymes is proposed. According to this model, tRNA ligase contains at least three functional domains, in the order: N-ligase-kinase-phosphohydrolase-C, whereas polynucleotide kinase and CNPase encompass only the two C-terminal domains in the same order.

Autogenous translation regulation by Escherichia coli ATPase SecA may be mediated by an intrinsic RNA helicase activity of this protein.

The seven conserved motifs typical of the helicase superfamily II have been identified in the sequences of Escherichia coli protein SecA, an ATPase mediating protein translocation across the inner membrane of the bacterium, and its Bacillus subtilis homolog Div. It is hypothesized that SecA and Div possess an RNA helicase activity and may couple ATP hydrolysis both to membrane translocation of proteins, and to hairpin unwinding in their own mRNAs, leading to the known autogenous regulation of translation.

An insect picornavirus may have genome organization similar to that of caliciviruses.

Computer-assisted analysis of the amino acid sequence of the product encoded by the sequenced 3' portion of the cricket paralysis virus (CrPV), an insect picornavirus, genome showed that this protein is homologous not to the RNA-directed RNA polymerases, as originally suggested, but to the capsid proteins of mammalian picornaviruses. Alignment of the CrPV protein sequence with those of picornavirus and calicivirus capsid proteins demonstrated that the sequenced portion of the insect picornavirus genome encodes the C-terminal part of VP3 and the entire VP1. Thus CrPV seems to have a genome organization distinct from that of other picornaviruses but closely resembling that of caliciviruses, with the capsid proteins encoded in the 3' part of the genome. On the other hand, the tentative phylogenetic trees generated from the VP3 alignment revealed grouping of CrPV with hepatitis A virus, a true picornavirus, not with caliciviruses. Thus CrPV may be a picornavirus with a calicivirus-like genome organization. Different options for CrPV genome expression are discussed.

Endonuclease (R) subunits of type-I and type-III restriction-modification enzymes contain a helicase-like domain.

A statistically significant amino acid sequence similarity is demonstrated between the endonuclease (R) subunit of EcoK restriction-modification (R-M) enzyme, and RNA and DNA helicases of the so-called 'DEAD' family. It is further shown that all three known sequences of R subunits of type-I and type-III R-M enzymes contain the conserved amino acid sequence motifs typical of the previously described helicase superfamily II [(1989) Nucleic Acids Res. 17, 4713-4730]. A hypothesis is proposed that these enzymes may exert helicase activity possibly required for local unwinding of DNA in the cleavage sites.

A new superfamily of putative NTP-binding domains encoded by genomes of small DNA and RNA viruses.

Statistically significant similarity was revealed between amino acid sequences of NTP-binding pattern-containing domains which are among the most conserved protein segments in dissimilar groups of ss and dsDNA viruses (papova-, parvo-, geminiviruses and P4 bacteriophage), and RNA viruses (picorna-, como- and nepoviruses) with small genomes. Within the aligned domains of 100-120 amino acid residues, three highly conserved sequence segments have been identified, i.e. 'A' and 'B' motifs of the NTP-binding pattern, and a third, C-terminal motif 'C', not described previously. The sequence of the 'B' motif in the proteins of the new superfamily is unusually variable, with substitutions, in some of the members, of the Asp residue conserved in other NTP-binding proteins. The 'C' motif is characterized by an invariant Asn residue preceded by a stretch of hydrophobic residues. As the new superfamily included a well studied DNA and RNA helicase, T antigen of SV40, helicase function could be tentatively assigned also to the other related viral putative NTP-binding proteins. On the other hand, the possibility of different and/or multiple functions for some of these proteins is discussed.

Putative papain-related thiol proteases of positive-strand RNA viruses. Identification of rubi- and aphthovirus proteases and delineation of a novel conserved domain associated with proteases of rubi-, alpha- and coronaviruses.

A computer-assisted comparative analysis of the amino acid sequences of (putative) thiol proteases encoded by the genomes of several diverse groups of positive-stranded RNA viruses and distantly related to the family of cellular papain-like proteases is presented. A high level of similarity was detected between the leader protease of foot-and-mouth-disease virus and the protease of murine hepatitis coronavirus which cleaves the N-terminal p28 protein from the polyprotein. Statistically significant alignment of a portion of the rubella virus polyprotein with cellular papain-like proteases was obtained, leading to tentative identification of the papain-like protease as the enzyme mediating processing of the non-structural proteins of this virus. Specific grouping between the sequences of the proteases of alpha-viruses, and poty- and bymoviruses was revealed. It was noted that papain-like proteases of positive-stranded RNA viruses are much more variable both in their sequences and in genomic locations than chymotrypsin-related proteases found in the same virus class. A novel conserved domain of unknown function has also been identified which flanks the papain-like proteases of alpha-, rubi- and coronaviruses.

Poliovirus-encoded proteinase 3C: a possible evolutionary link between cellular serine and cysteine proteinase families.

Here we demonstrate significant similarities between the amino acid sequences of trypsin (a serine protease) and the N-terminal piece of a specific fragment of the poliovirus polyprotein encompassing the sequence of the viral proteinase 3C, and also between cathepsin H (a cysteine protease) and the C-terminal piece of the same fragment. A coherent alignment of the sequences of the 3 proteases was obtained, in which the principal catalytically active residues occupy identical positions. A hypothesis is proposed that the viral enzyme may provide an evolutionary link between serine and cysteine protease families.

Tentative identification of RNA-dependent RNA polymerases of dsRNA viruses and their relationship to positive strand RNA viral polymerases.

Amino acid sequence stretches similar to the four most conserved segments of positive strand RNA viral RNA-dependent RNA polymerases have been identified in proteins of four dsRNA viruses belonging to three families, i.e. P2 protein of bacteriophage phi 6 (Cystoviridae), RNA 2 product of infectious bursa disease virus (Birnaviridae), lambda 3 protein of reovirus, and VP1 of bluetongue virus (Reoviridae). High statistical significance of the observed similarity was demonstrated, allowing identification of these proteins as likely candidates for RNA-dependent RNA polymerases. Based on these observations, and on the previously reported sequence similarity between the RNA polymerases of a yeast dsRNA virus and those of positive strand RNA viruses, a possible evolutionary relationship between the two virus classes is discussed.

Sobemovirus genome appears to encode a serine protease related to cysteine proteases of picornaviruses.

A putative serine protease was identified among non-structural proteins of southern bean mosaic virus (SBMV) by sequence comparison with cellular and viral proteases. The predicted SBMV protease displayed a significant similarity to cysteine proteases of picornaviruses, providing a possible evolutionary link between the two enzyme classes. It is suggested that SBMV follows the general expression strategy characteristic of other positive-strand RNA viruses containing 5'-terminal covalently linked proteins (VPg), i.e. generation of functional proteins by polyprotein processing.

Two early genes of bacteriophage T5 encode proteins containing an NTP-binding sequence motif and probably involved in DNA replication, recombination and repair.

It is demonstrated, by computer-assisted analysis, that T5 bacteriophage early genes D10 and D13 encode proteins containing the purine NTP-binding sequence motif. The D10 gene product is shown to be a member of a recently characterized superfamily of (putative) DNA and RNA helicases. The D13 gene product is related at a statistically significant level, to the gene 46 product of bacteriophage T4 which is a component of an exonuclease involved in phage DNA replication, recombination and repair. A lower but also significant degree of sequence similarity was detected between the gene D12 product of T5 and the gene 47 product of T4, the second component of the same nuclease. It is hypothesized that both D10 and D13 gene products of T5 might be NTPases, possibly DNA-dependent, mediating NTP-consuming steps during phage DNA replication, recombination and/or repair.