Host range determinants located on the interior of the poliovirus capsid. The EMBO journal The inability of certain poliovirus strains to infect mice can be overcome by the expression of human poliovirus receptors in mice or by the presence of a particular amino acid sequence of the B-C loop of the viral capsid protein VP1. We have identified changes in an additional capsid structure that permit host-restricted poliovirus strains to infect mice. Variants of the mouse-virulent P2/Lansing strain were constructed containing amino acid changes, deletions and insertions in the B-C loop of VP1. These variants were attenuated in mice, demonstrating the importance of the B-C loop sequence in host range. Passage of two of the B-C loop variants in mice led to the selection of viruses that were substantially more virulent. The increased neurovirulence of these strains was mapped to two different suppressor mutations in the N-terminus of VP1. Whereas the B-C loop of VP1 is highly exposed on the surface of the capsid, near the five-fold axis of symmetry, the suppressor mutations are in the interior of the virion, near the three-fold axis. Introduction of the suppressor mutations into the genome of the mouse-avirulent P1/Mahoney strain resulted in neurovirulent viruses, demonstrating that the P2/Lansing B-C loop sequence is not required to infect mice. Because the internal host range determinants are in a structure known to be important in conformational transitions of the virion, the host range of poliovirus may be determined by the ability of virions to undergo transitions catalyzed by cell receptors. 10.1002/j.1460-2075.1991.tb08046.x

Production of infectious poliovirus from cloned cDNA is dramatically increased by SV40 transcription and replication signals. Semler B L,Dorner A J,Wimmer E Nucleic acids research Sub-genomic cDNA clones representing the entire genomic RNA of poliovirus Type 1 (Mahoney) have been isolated in E. coli. Construction of a complete cDNA copy of the poliovirus genome in the EcoRI site of plasmid vector pBR325 from these clones is described. Introduction of plasmid DNA containing the complete cDNA copy of polio RNA into cultured primate cells by transfection produces infectious poliovirus. The virus produced by such a transfection appears to be identical to wild type poliovirus. Isolation of a polio recombinant plasmid containing SV40 transcription and replication signals is also described. Transfection of COS-1 cells with this plasmid yields greater than 1,600 plaque-forming units (PFU) per microgram of input DNA. 10.1093/nar/12.12.5123

Inhibition of cellular protein secretion by poliovirus proteins 2B and 3A. The EMBO journal Poliovirus RNA replication occurs on the surface of membranous vesicles that proliferate throughout the cytoplasm of the infected cell. Since at least some of these vesicles are thought to originate within the secretory pathway of the host cell, we examined the effect of poliovirus infection on protein transport through the secretory pathway. We found that transport of both plasma membrane and secretory proteins was inhibited by poliovirus infection early in the infectious cycle. Transport inhibition did not require viral RNA replication or the inhibition of host cell translation by poliovirus. The viral proteins 2B and 3A were each sufficient to inhibit transport in the absence of viral infection. The intracellular localization of a secreted protein in the presence of 3A with the endoplasmic reticulum suggested that 3A directly blocks transport from the endoplasmic reticulum to the Golgi apparatus. 10.1002/j.1460-2075.1995.tb07071.x

Cloned poliovirus complementary DNA is infectious in mammalian cells. Racaniello V R,Baltimore D Science (New York, N.Y.) A complete, cloned complementary DNA copy of the RNA genome of poliovirus was constructed in the Pst I site of the bacterial plasmid pBR322. Cultured mammalian cells transfected with this hybrid plasmid produced infectious poliovirus. Cells transfected with a plasmid which lacked the first 115 bases of the poliovirus genome did not produce virus. 10.1126/science.6272391