Poliovirus


Poliovirus, the causative agent of polio, is a serotype of the species Enterovirus C, in the family of Picornaviridae. There are [|three poliovirus serotypes], numbered 1, 2, and 3.
Poliovirus is composed of an RNA genome and a protein capsid. The genome is a single-stranded positive-sense RNA genome that is about 7500 nucleotides long. The viral particle is about 30 nm in diameter with icosahedral symmetry. Because of its short genome and its simple composition—only a strand of RNA and a nonenveloped icosahedral protein coat encapsulating it—poliovirus is widely regarded as the simplest significant virus.
Poliovirus is one of the most well-characterized viruses, and has become a useful model system for understanding the biology of RNA viruses.

Replication cycle

Poliovirus infects human cells by binding to an immunoglobulin-like receptor, CD155 on the cell surface. Interaction of poliovirus and CD155 facilitates an irreversible conformational change of the viral particle necessary for viral entry. Following attachment to the host cell membrane, entry of the viral nucleic acid was thought to occur one of two ways: via the formation of a pore in the plasma membrane through which the RNA is then "injected" into the host cell cytoplasm, or via virus uptake by receptor-mediated endocytosis. Recent experimental evidence supports the latter hypothesis and suggests that poliovirus binds to CD155 and is taken up by endocytosis. Immediately after internalization of the particle, the viral RNA is released.
Poliovirus is a positive-stranded RNA virus. Thus, the genome enclosed within the viral particle can be used as messenger RNA and immediately translated by the host cell. On entry, the virus hijacks the cell's translation machinery, causing inhibition of cellular protein synthesis in favor of virus-specific protein production. Unlike the host cell's mRNAs, the 5' end of poliovirus RNA is extremely long—over 700 nucleotides—and highly structured. This region of the viral genome is called an internal ribosome entry site. This region consists of many secondary structures and 3 or 4 domains. Domain 3 is a self folding RNA element that contains conserved structural motifs in various stable stem loops linked by two four-way junctions. As IRES consists of many domains, these domains themselves consist of many loops that contribute to modified translation without a 5’ end cap by hijacking ribosomes. The interaction loop of domain 3 is known as GNRA tetraloop. The residues of adenosines A180 and A181 in the GUAA tetraloop form hydrogen bonds via non canonical base pairing interactions with the base pairs of the receptors C230/G242 and G231/C241, respectively. Genetic mutations in this region prevent viral protein production. The first IRES to be discovered was found in poliovirus RNA.
Poliovirus mRNA is translated as one long polypeptide. This polypeptide is then autocleaved by internal proteases into about 10 individual viral proteins. Not all cleavages occur with the same efficiency. Therefore, the amounts of proteins produced by the polypeptide cleavage vary: for example, smaller amounts of 3Dpol are produced than those of capsid proteins, VP1–4. These individual viral proteins are:
Image:Poliovirus genome.png|thumb|right|upright=1.5|The genomic structure of poliovirus type 1
  • 3Dpol, an RNA dependent RNA polymerase whose function is to make multiple copies of the viral RNA genome
  • 2Apro and 3Cpro/3CDpro, proteases which cleave the viral polypeptide
  • VPg, a small protein that binds viral RNA and is necessary for synthesis of viral positive and negative strand RNA
  • 2BC, 2B, 2C, 3AB, 3A, 3B proteins which comprise the protein complex needed for virus replication.
  • VP0, which is further cleaved into VP2 and VP4, VP1 and VP3, proteins of the viral capsid
After translation, transcription and genome replication which involve a single process, synthesis of is realized. For the infecting RNA to be replicated, multiple copies of RNA must be transcribed and then used as templates for RNA synthesis. Replicative intermediates, which are an association of RNA molecules consisting of a template RNA and several growing RNAs of varying length, are seen in both the replication complexes for RNAs and RNAs. For synthesis of each negative-strand and positive-strand RNAs, VPg protein in the poliovirus works as a primer. RNA-dependent RNA polymerase of the poliovirus adds two uracil nucleotides to VPg protein utilizing the poly tail at the 3′-end of the +ssRNA genome as a pattern for synthesis of the negative-strand antigenomic RNA. To initiate this −ssRNA synthesis, the tyrosine hydroxyl of VPg is needed. But for the initiation of positive strand RNA synthesis, CRE-dependent VPg uridylylation is needed. Which means that VPg is once more utilized as a primer however this time it adds the two uridine triphosphates using a cis-acting replication element as a template.
The CRE of poliovirus is identified as an unachieved base-paired stem and a final loop consisting of 61 nt. The CRE is found in enteroviruses. It is a highly preserved secondary RNA structural element and bedded in the genome's polyprotein-coding region. The complex can be translocated to the 5' region of the genome that have no coding activity, at least 3.7-kb distant from the initial location. This process can occurs without negatively influencing activity. CRE copies do not influence replication negatively. Uridylylation process of VPg that takes place at CRE needs the presence of 3CDpro that is an RNA binding protein. It is attached to the CRE directly and specifically. Because of its presence VPg can bind the CRE properly and primary production proceeds without problems.
Some of the RNA molecules are used as templates for further RNA synthesis, some function as mRNA, and some are destined to be the genomes of progeny virions.
In the assembly of new virus particles, including, respectively:
  • Five copies each of VP0, VP3, and VP1 whose N termini and VP4 form interior surface of capsid, assemble into a 'pentamer' and 12 pentamers form a procapsid.
  • Each procapsid acquires a copy of the virus genome, with VPg still attached at the 5' end.
Fully assembled poliovirus leaves the confines of its host cell by lysis 4 to 6 hours following initiation of infection in cultured mammalian cells. The mechanism of viral release from the cell is unclear, but each dying cell can release up to 10,000 polio virions.
Drake demonstrated that poliovirus is able to undergo multiplicity reactivation. That is, when polioviruses were irradiated with UV light and allowed to undergo multiple infections of host cells, viable progeny could be formed even at UV doses that inactivated the virus in single infections. Poliovirus can undergo genetic recombination when at least two viral genomes are present in the same host cell. Kirkegaard and Baltimore presented evidence that RNA-dependent RNA polymerase catalyzes recombination by a copy choice mechanism in which the RdRP switches between ssRNA templates during negative strand synthesis. Recombination in RNA viruses appears to be an adaptive mechanism for repairing genome damage.

Origin and serotypes

Poliovirus is structurally similar to other human enteroviruses, which also use immunoglobulin-like molecules to recognize and enter host cells. Phylogenetic analysis of the RNA and protein sequences of poliovirus suggests that it may have evolved from a C-cluster Coxsackie A virus ancestor through a mutation in the capsid. The distinct speciation of poliovirus probably occurred as a result of a change in cellular receptor specificity from intercellular adhesion molecule-1 to CD155, leading to a change in pathogenicity and allowing the virus to infect nerve tissue.
The mutation rate in the virus is relatively high even for an RNA virus, with a synonymous substitution rate of substitutions/site/year and a
non-synonymous substitution rate of substitutions/site/year. Base distribution within the genome is not random; adenosine is less common than expected at the 5' end and higher at the 3' end. Codon use is not random; codons ending in adenosine are favoured, and those ending in cytosine or guanine are avoided. Codon use differs between the three genotypes, and appears to be driven by mutation rather than selection.
The three serotypes of poliovirus, PV-1, PV-2, and PV-3, each have a slightly different capsid protein. Capsid proteins define cellular receptor specificity and virus antigenicity. PV-1 is the most common form encountered in nature, but all three forms are extremely infectious. As of March 2020, wild PV-1 is highly localized to regions in Pakistan and Afghanistan. Certification of the eradication of indigenous transmission of wild PV-2 occurred in September 2015, after last being detected in 1999, and in October 2019 for wild PV-3 after last being detected in 2012. However, circulating vaccine-derived poliovirus of all three serotypes continues to circulate and cause paralysis, having been detected in 32 countries in 2023.
Specific strains of each serotype are used to prepare vaccines against polio. Inactive polio vaccine is prepared by formalin inactivation of three wild, virulent reference strains: Mahoney or Brunenders, MEF-1/Lansing, and Saukett/Leon. Oral polio vaccine contains live attenuated strains of the three serotypes of poliovirus. Passaging the virus strains in monkey kidney epithelial cells introduces mutations in the viral IRES, and hinders the ability of the virus to infect nerve tissue.
Polioviruses were formerly classified as a distinct species belonging to the genus Enterovirus in the family Picornaviridae. In 2008, Poliovirus ceased to be recognized as a species, and the three serotypes were assigned to the species Human enterovirus C in the genus Enterovirus in the family Picornaviridae. The type species of the genus Enterovirus was changed from Poliovirus to.