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A summary of this ICTV online (10th) report chapter has been published as an ICTV Virus Taxonomy Profile article in the Journal of General Virology, and should be cited when referencing this online chapter as follows:
Zell, R., Delwart, E., Gorbalenya, A.E., Hovi, T., King, A.M.Q., Knowles, N.J., Lindberg, A.M., Pallansch, M.A., Palmenberg, A.C., Reuter, G., Simmonds, P., Skern, T., Stanway, G., Yamashita, T. and ICTV Report Consortium, ICTV Virus Taxonomy Profile: Picornaviridae, Journal of General Virology, (In Press)
The Picornaviridae is a family of small, icosahedral viruses with single-stranded, highly diverse positive strand RNA genomes. Characteristic features of all members of the family are three capsid proteins with b-barrel folding, polyprotein processing by virus-encoded cysteine proteinase(s), and replication by an RNA-dependent RNA polymerase with YGDD sequence motif. The family comprises 35 genera containing 80 species, but many viruses are presently awaiting assignment. Picornaviruses may cause subclinical infections of humans and animals or conditions ranging from mild febrile illness to severe diseases of heart, liver and the central nervous system.
Table 1.Picornaviridae. Characteristics of the family Picornaviridae.
poliovirus 1 Mahoney (V01149), species Enterovirus C, genus Enterovirus
Non-enveloped, 30-32 nm virions comprising 60 protomers
6.7-10.1 kb of positive-sense, non-segmented RNA with a poly(A) tail
RNA synthesis occurs in reorganized cytoplasmic replication organelles containing non-structural proteins derived from the 2BC-P3 region of the encoded polyprotein; RNA structures at the 5' and 3' end of the genome direct initiation of RNA synthesis and uridylated 3B serves as primer for synthesis of both RNA strands
Directly from genomic RNA containing an internal ribosomal entry site (IRES)
Vertebrates (at least five of the seven classes)
Member of the order Picornavirales; 35 genera containing 80 species
Virions consist of a capsid, with no envelope, surrounding a core of ssRNA. Available crystal structures indicate that particles are 30-32 nm in diameter. Electron micrographs reveal no projections on virions of most picornaviruses, the virus particle appearing as an almost featureless sphere; however, kobuviruses show a surface structure which is distinct from small round structured viruses (astroviruses and caliciviruses) (Figure 1.Picornaviridae). The capsid is composed of 60 identical units (protomers). Those picornaviruses with four capsid proteins have three surface proteins, 1B, 1C and 1D, of 24-41 kDa, and an internal protein, 1A of 5.5-13.5 kDa; however, many picornaviruses have three capsid protein as 1AB (VP0) remains uncleaved. Total protomer is 80–97 kDa. Proteins 1A, 1B, 1C and 1D are also commonly named VP4, VP2, VP3, and VP1, respectively. Proteins 1B, 1C, 1D and the uncleaved 1AB each possess a core structure comprising an eight-stranded b-sandwich ("b-barrel"). Capsid protein (CP) sequences in many genera reveal similarities to those in the "rhv-like" superfamily of proteins, and may contain a conserved "inhibitor binding site" which, in the case of some rhino- and enteroviruses, has been demonstrated to bind active antivirals. The b-barrels pack together in the capsid with T=l, pseudo T=3, icosahedral symmetry; these structural features are shared by all members of the order Picornavirales with solved atomic structures, e.g. cricket paralysis virus (Dicistroviridae), infectious flacherie virus (Iflaviridae) and the comoviruses (cowpea mosaic virus, bean pod mottle virus and red clover mottle virus).
Genera differ in the external loops that interconnect the b-strands. These loops account for differences in surface relief of each genus (Figure 1.Picornaviridae) and in thickness of the capsid wall. Assembly occurs via pentameric intermediates (pentamer=five protomers). Proteins within each pentamer are held together by an internal network formed from the N-termini of the three major CPs, the C-termini lying on the outer capsid surface. In genera where the 1AB is cleaved in the complete virion, empty capsids, which are produced by some picornaviruses, are very similar to virions, except that 1A and 1B are normally replaced by the uncleaved precursor, 1AB.
<Figure 1 near here>
The molecular weight of picornavirus virions ranges from 8 x 106 - 9 x 106 with a sedimentation rate (S20w) of 140-165S (for empty particles S20w is 70-80S). Their buoyant density in CsCl is 1.33-1.45 g cm-3, depending on the genus. Some species are unstable below pH 7; many are less stable at low ionic strength than at high ionic strength. Virions are insensitive to ether, chloroform, or non-ionic detergents. Viruses are inactivated by light when grown with, or in the presence of photodynamic dyes such as neutral red or proflavin. Thermal stability varies with viruses as does stabilization by divalent cations.
Virions contain one molecule of positive-sense ssRNA, 6.7-10.1 kb in size, and possessing a single long ORF; canine picodicistroviruses (genus Dicipivirus), however, display two ORFs, translation of each is directed by a separate internal ribosomal entry site (IRES). A poly(A) tail, heterogeneous in length, is located after the 3′-terminal heteropolymeric sequence. A small protein, VPg (c. 2.2 to 3.9 kDa), is linked covalently to the 5′-terminus. The untranslated regions (UTRs) at both termini contain regions of secondary structure which are essential to genome function. The long 5′-UTR (0.5-1.5 kb) includes a 5′-terminal domain involved in replication (e.g. the poliovirus "clover-leaf") and an IRES of 220-450 nt upstream of the translational start site; most picornaviral IRES elements can be assigned to one of several types (I to V, IGR-IRES), according to their secondary structure. Between the 5′-terminal domain and the IRES there may be one, or more, pseudoknots. A poly(C) tract is found in the 5'-UTR of foot-and-mouth disease viruses, encephalomyocarditis viruses and possibly porcine teschoviruses. The 3′-UTR, which may also contain a pseudoknot, ranges from 25 to nearly 800 nt in length.
In addition to the major CPs, 1A, 1B, 1C and 1D, and 3B (VPg), described above, small amounts of 1AB (VP0) are commonly seen in lieu of one or more copies of 1A and 1B. Protein 1A is small in hepatoviruses, and 1AB is uncleaved in members of the Ampivirus, Aquamavirus, Avihepatovirus, Avisivirus, Gallivirus, Kobuvirus, Kunsagivirus, Limnipivirus, Megrivirus, Mischivirus, Oscivirus, Parechovirus, Pasivirus, Passerivirus, Potamipivirus, Rosavirus, Sakobuvirus, Salivirus, Sicinivirus genera, and a number of unclassified picornaviruses. The orthologous proteins 1B, 1C, 1D, 2C, 3C and 3D are conserved in all picornaviruses and may be used for sequence alignments between genera, whereas 1A, 2A, 2B, 3A and 3B are highly divergent among the picornavirus genera. The viral proteinases are as follows (Figure 2.Picornaviridae): 3Cpro, a chymotrypsin-like cysteine protease encoded by all picornaviruses, performs most of the cleavages; 2Apro related to 3Cpro is responsible for few cleavages in enteroviruses, and possibly sapeloviruses and raboviruses; Lpro residing in a leader protein is a papain-related cysteine protease that releases itself from polyprotein in aphthoviruses, erboviruses and possibly mosaviruses. Also, the 2A of aphthoviruses, aquamaviruses, avihepatoviruses, avisiviruses, cardioviruses, cosaviruses, erboviruses, hunniviruses, kunsagiviruses, limnipiviruses, mischiviruses, mosaviruses, members of the species Parechovirus B, C and D, pasiviruses, potamipiviruses, rosaviruses, senecaviruses, teschoviruses, torchiviruses and of a number of unclassified picornaviruses contains a NPG↓P motif that mediates cotranslational termination-reinitiation of RNA translation (↓ = co-translational stop-go site) and acts only in cis (2Anpgp). Conserved sequence motifs are found in the 2C helicase (Walker A motif: GxxGxGKS), 3C proteinase (GxCGx10-15GxH) and 3D polymerase (KDE, DxxxxD, PSG, YGDD, FLKR).
<Figure 2 near here>
Some picornaviruses carry a sphingosine-like molecule ("pocket factor") in a cavity ("pocket") located inside 1D. Protein 1A, where present, generally has a molecule of myristic acid covalently attached to the amino terminal glycine. No myristoylation signal is found in the N-terminal VP4 and VP0 sequence of avihepatoviruses, dicipiviruses, kobuviruses, parechoviruses and tremoviruses.
None of the viral proteins are glycosylated.
The virion RNA is infectious (Colter et al., 1957, Alexander et al., 1958) and serves as both the genome and the viral mRNA. Initiation of protein synthesis is stimulated by the IRES. Translation of the single ORF produces the polyprotein precursor (216–277 kDa) to the structural proteins (derived from the P1 region of the genome) and the non-structural proteins (from the P2 and P3 regions) (Figure 2.Picornaviridae). In many viruses P1 is preceded by a leader protein (L). In dicipiviruses ORF1 encodes the precursor of the structural proteins (corresponding to the P1 region), whereas ORF2 encodes the functional protein precursor (P2 and P3 regions). The polyprotein is cleaved to functional proteins by virus-encoded proteinases. Intermediates are denoted by letter combinations (e.g. 3CD, the uncleaved precursor of 3C and 3D). Picornaviruses exhibit a modular genome organization (Figure 3.Picornaviridae). Certain genetic elements of the 5'- and 3'-UTR and gene regions are thought to have been exchanged between the genera. There may be one or more gene regions encoding various 2A proteins. Beside 2Apro and the aphthovirus-like 2Anpgp, 2A may have H-box/NC sequence motifs [avihepatoviruses, avisiviruses, galliviruses, kobuviruses, megriviruses, parechoviruses, passeriviruses, potamipiviruses, sakobuviruses, saliviruses, siciniviruses, tremoviruses and several unassigned picornaviruses; (Hughes and Stanway 2000)] or similarity to the AIG1-type guanine binding domain, a P-loop NTPase with GxxGxGKS motif (avihepatoviruses, avisiviruses); their function in virus replication is unclear. The 2B and 3A gene regions vary greatly among the genera, although functionally they may be homologous. Some intermediates are stable and serve functions distinct from those of their cleavage products (e.g. cleavage of poliovirus P1 by 3CDpro, not by 3Cpro). Where it occurs, the cleavage of 1AB, which accompanies RNA encapsidation, is thought to be autocatalytic, but the precise mechanism is unknown.
<Figure 3 near here>
A typical picornavirus genome layout may be represented by the following:
Where “[” and “]” define the extent of the polyprotein-coding region, “/” represents primary cleavages and “-” represents the final cleavages. Where a particular polypeptide is present only in some members of the genus it can be shown between parentheses. This schema can also be used to indicate some protein functions or amino acid motifs where they differ between viruses (e.g. 2Apro or 2Anpgp or 2AH-box/NC or 2ANTPase). There may be multiple copies of a particular genomic regions in the picornavirus genome including repeated copies of one particular region (e.g. three 3B’s in the FMDV genome) or different types of a particular region (e.g. two different 2A motifs in Ljungan virus of the genus Parechovirus and three different 2A motifs in the duck hepatitis A virus genome of the genus Avihepatovirus).
Replication of viral RNA occurs in tight association with reorganized cytoplasmic membraneous structures. These complexes termed replication organelles contain proteins derived from the whole of the 2BC-P3 region of the polyprotein, including the polymerase (3Dpol, an RNA chain-elongating enzyme), and 2C (an ATPase containing a nucleotide binding sequence motif). The poliovirus and coxsackievirus 3Cpro component has been shown to be required for binding to the 5′-terminal RNA cloverleaf. The small virus-encoded protein, VPg, acts as a transcription primer for both positive and negative strand RNA synthesis. Prior to transcription two uridine residues are covalently linked to the conserved tyrosine at position 3 in VPg to form VPgpUpUOH via a templating mechanism involving a cis-acting replication element (cre) and the virus 3D polymerase. The cre is a stem loop containing the sequence “AAAC” in the loop and is found at various places in the genome depending on virus species/genus. Many compounds that specifically inhibit replication have been described. Mutants resistant to, or dependent on, drugs have been reported. Genetic recombination, complementation, and phenotypic mixing occur. Defective particles, carrying deletions in the CPs or L, have been produced experimentally but have not been observed in natural virus populations.
Serotypes are classified, depending on genus, by cross-protection, neutralization of infectivity, complement-fixation, specific ELISA using a capture format or immunodiffusion. Some serotypes can be identified using hemagglutination-inhibition. Serotypes have been determined for most members of the enteroviruses, aphthoviruses, cardioviruses, erboviruses and teschoviruses but are increasingly replaced by genotypes (commonly referred to as ‘types’) in clinical or diagnostic practice. The genera are antigenically unrelated where investigated.
Most picornaviruses for which the natural hosts have been identified are specific for one, or a very few host species [exceptions are foot-and-mouth disease virus (FMDV) and encephalomyocarditis virus (EMCV)]. Members of most species can be grown in cell culture. Resistant host cells (e.g., mouse cells in the case of the primate-specific polioviruses) can often be infected (for a single round) by transfection with naked, infectious RNA. Transmission is horizontal, mainly by fecal-oral, fomite or airborne routes. Transmission by arthropod vectors is not known, although EMCV has been isolated from mosquitoes and ticks and poliovirus from flies; therefore mechanical transmission may be possible.
Infection is generally cytolytic, but persistent infections are common with some species and reported with others. Poliovirus infected cells undergo extensive vacuolation as membranes are reorganized into viral replication complexes. Infection may be accompanied by rapid inhibition of cap-dependent translation of cellular mRNAs (2Apro of poliovirus and Lpro of aphthovirus are each powerful inhibitors), mRNA synthesis, and the cellular secretory pathway (poliovirus 2B and 3A have been implicated).
A picornavirus species is a class of phylogenetically related types or strains which would normally be expected to share (i) a significant degree of amino acid identity of P1, 2C, 3C and 3D proteins, (ii) monophyly in phylogenetic trees, (iii) essentially identical genome maps, and (iv) a significant degree of compatibility in proteolytic processing, replication, encapsidation and genetic recombination.
Members of a genus would normally be expected to have homologous IRES structures and proteins; their sequences cluster on the same branch in phylogenetic trees (monophyly). All known picornavirus genera differ by (i) genome maps that exhibit distinctive features in comparison to their closest relatives, (ii) significant divergence (number of differences per site between sequences) of the orthologous proteins exceeding 66% of P1cap and 64% of 2Chel, 3Cpro and 3Dpol [these values are based on current sequence data and may vary with additional data available in future], (iii) lack of detectable homology of proteins L (if present), 2B, 3A, 3B. If these rules do not apply, a novel species or genus may be proposed.
To distinguish virus names from species names where they have been the same, the Picornaviridae Study Group recommends that viruses be assigned a type number, e.g. encephalomyocarditis virus is now be known as encephalomyocarditis virus-1 (EMCV-1); this currently affects some virus names in the following genera: Aphthovirus and Sapelovirus. It is recommended that strain designations should include information on host species, lab-specific ID number, country of sampling, year of sampling, e.g. seal/ABC1234/USA/2015.
Picorna: an acronym from poliovirus, insensitivity to ether, coxsackievirus, orphan virus, rhinovirus, ribonucleic acid; also, from the prefix "pico" which designates a very small unit of measurement (equivalent to 10-12) and RNA to designate very small RNA viruses.
Viruses of each picornavirus genus are phylogenetically distinct from members of other genera in those genome regions which are orthologous, i.e. P1cap (Figure 4A.Picornaviridae), 2Chel, 3CD (Figure 4B.Picornaviridae). Divergence between the members of a genus may be as high as 67% for the P1 polyprotein and 64% for 2C, 3C and 3D proteins. Divergence between the members of different genera is usually higher.
<Figures 4A, 4B near here>
Presence of 1-3 domains with detectable similarity to the rhv-like superfamily with characteristic folding ("b-barrel") in the capsid proteins is common to most members of the order Picornavirales. Likewise, a 'replication block' comprising a RNA-helicase domain (P-loop NTPase), a peptidase C-like proteinase and a RNA-dependent RNA polymerase 1 domain (RT-like superfamily) is also present in all members of Picornavirales and many unclassified picorna-like viruses. Capsid proteins and proteins of the replication block show various degree of similarity. The presence of a small genome-linked protein which is also the replication primer is also common to many small positive-strand RNA viruses. A genome organization with a single open reading frame and CP-encoding gene region at the 5'-end and the gene region encoding the replication block proteins at the 3'-end is common to members of the Picornaviridae and Iflaviridae.
crohi-like virus [bat/Cameroon/2014]
bovine picornavirus [cattle/TCH6]
harrier picornavirus 1 [MR-01/HUN/201]
lesavirus 1 [Mis101308/2012]
lesavirus 2 [Nai108015/2012]
livupivirus A1 [newt/II-5-Pilis/2014/HUN]
Miniopterus fuliginosus picornavirus [BtMf-PicoV-1/Sax2011]
chicken orivirus 1 [chicken/Pf-CHK1/2013/HUN]
chicken orivirus 2 [Pf-CHK1/OrV-A2
porcine picornavirus Japan [Tottori-WOL]
Rhinolophus affinis picornavirus [bat/China/2010]
Rhinolophus ferrumequinum picornavirus [BtRf-PicoV-2/YN2012]
rodent picornavirus [rodent/Ds/PicoV/IM2014]
rodent picornavirus [rodent/Rn/PicoV/SX2015_1]
rodent picornavirus [rodent/CK/PicoV/Tibet2014]
Sapelo-like bat picornavirus [NC16A]
Sapelo-like bat picornavirus [LMH22A]
Sapelo-like bat picornavirus [MH9F]
Sapelo-like bat picornavirus [SK17F]
Sapelo-like bat picornavirus [TLC5F]
Sapelo-like bat picornavirus [TLC21F]
Sapelo-like bat picornavirus [BtRh-PicoV/SC2013]
Sapelo-like bat picornavirus [BtMf-PicoV-2/SAX2011]
Sapelo-like bat picornavirus [BtMf-PicoV/FJ2012]
Sapelo-like bat picornavirus [BtMf-PicoV-1/GD2012]
Sapelo-like bat picornavirus [BtRf-PicoV-1/YN2012]
Sapelo-like bat picornavirus [BtRlep-PicoV/FJ2012]
Sapelo-like bat picornavirus [BtRa-PicoV/JS2013]
Sapelo-like bat picornavirus [BtNv-PicoV/SC2013]
Sapelo-like bat picornavirus [BtVs-PicoV/SC2013]
Sapelo-like bat picornavirus [BtMa-PicoV/FJ2012]
Sapelo-like bat picornavirus [BtRs-PicoV/YN2010]
Sapelo-like bat picornavirus [Eidolon helvum/Cameroon/ 2014]
Sapelo-like bat picornavirus [CAM/Sap-P24/2013]
Sapelo-like Ia io picornavirus
Sapelo-like bovine picornavirus [Bo-11-39/2009/JPN]
Sapelo-like bovine picornaviruses
California sea lion sapelovirus 
canine sapelovirus [dog/Hong Kong/325F/2008]
Sapelo-like pigeon picornavirus A [pigeon/Norway/03/603-7/2003]
Sapelo-like pigeon picornavirus B [pigeon/Norway/03/641/ 2003]
Sapelo-like pigeon picornavirus B [pigeon/GAL-7/2010/Hungary]
Sapelo-like quail picornavirus [quail/Hungary/2010]
tortoise rafivirus [tortoise/UF4/USA/2009]
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