The human poliovirus receptor. Receptor-virus interaction and parameters of disease specificity.

The host range of poliovirus is determined by the expression of the hPVR, a member of the immunoglobulin superfamily. We characterized hPVR proteins biochemically and found them to be complex-type glycoproteins. The outermost V-like domain of three extracellular domains harbors the PVR function. A panel of single or multiple amino acid exchanges were introduced throughout this domain in order to localize regions involved in virus-receptor interactions. Putative contact amino acids were found to reside in the C'C"D and DE regions. Binding and uptake of poliovirus paralleled virus replication in all mutants tested suggesting that virus binding was affected without abrogating the ability to mediate subsequent events in the infection. Although the primate PVR is essential in conferring susceptibility to poliovirus infection, certain strains can induce neurological disease in rodents. Mouse neurovirulent PV isolates of divergent serotypical origin each provoked a distinctive, characteristic neurological syndrome upon intracerebral infection of wild-type mice. We analyzed clinical and histopathological features of diffuse encephalomyelitis caused by these PV strains and compared the condition with poliomyelitis in mice transgenic for the hPVR. Diffuse PV encephalomyelitis in wild-type mice could be distinguished clinically and histopathologically from hPVR-mediated poliomyelitis in trangenic mice. We localized the determinants of mouse neurovirulence of PV1(LS-a), a derivative of PV1 (Mahoney), in a portion of the viral genome encompassing parts of the capsid protein VP1 as well as the nonstructural protein 2A. Mouse neuropathogenicity could possibly be conferred by reduced particle stability of PV1(LS-a) inasmuch as we found particles to be thermolabile.

Mouse neurovirulence determinants of poliovirus type 1 strain LS-a map to the coding regions of capsid protein VP1 and proteinase 2Apro.

Poliovirus type 1 strain LS-a [PV1(LS-a)] is a OV variant adapted to mice by multiple passages through mouse and monkey tissues. To investigate the molecular basis underlying mouse neurovirulence of PV1(LS-a), a cDNA of the viral genome containing nucleotides 112 to 7441 was cloned, and the nucleotide sequence was determined. Compared with that of the mouse avirulent progenitor PV1(Mahoney), 54 nucleotide changes were found in the genome of the PV1(LS-a) virus, resulting in 20 amino acid substitutions in the virus polyprotein. Whereas the nucleotide changes were scattered throughout the genome, the amino acid substitutions were largely clustered in the capsid proteins and, to a certain extent, in the virus proteinase 2Apro. By in vitro mutagenesis, PV1(LS-a)-specific capsid mutations were introduced into a cDNA clone of PV1(Mahoney). We show that neither the individual amino acid mutations nor combinations of mutations in the region encoding VP1 conferred to PV1(Mahoney) the mouse-adapted phenotype of PV1(LS-a). Chimeric cDNA studies demonstrated that a recombinant type 1 virus containing the PV1(LS-a) sequence from nucleotide 2470 to nucleotide 3625 displayed a neurovirulent phenotype in mice. Further dissection of this region revealed that mouse neurovirulence of PV1(LS-a) was determined by multiple mutations in regions encoding both viral proteinase 2Apro and capsid protein VP1. The mouse neurovirulent viruses, PV1(LS-a), W1-M/LS-Pf [nucleotides 496 to 3625 from PV1(LS-a)], and W1-M/LS-NP [nucleotides 2470 to 3625 from PV1(LS-a)], showed increased sensitivity to heat treatment at 45 degrees C for 1 h. Surprisingly, the thermolabile phenotype was also displayed by a recombinant of PV1(Mahoney) carrying a PV1(LS-a) DNA fragment encoding the N-terminal portion of 2Apro. This suggests that base substitutions in the region encoding 2Apro affected capsid stability, thereby contributing to the neurovirulence of the virus in mice.

Construction and characterization of a poliovirus/rhinovirus antigenic hybrid.

In order to study the properties of foreign antigenic sites expressed on poliovirus a hybrid was constructed in which neutralization antigenic site IA of poliovirus type 1 strain Mahoney [PV1(M)] was replaced by neutralization immunogenic site IA (NImIA) of human rhinovirus 14 (HRV14). The resulting hybrid was viable, but growth was impaired in comparison to PV1(M). The hybrid expressed both PV1(M) and HRV14 antigenic determinants. When inoculated into rabbits it elicited neutralizing antibodies against both PV1(M) and HRV14. Furthermore, the hybrid was efficiently neutralized by polyclonal antisera specific for either PV1(M) or HRV14 and by three out of five monoclonal antibodies directed to NImIA. The monoclonal antibodies also blocked binding of the hybrid to the cellular receptor for poliovirus. One of them is thought to neutralize rhinovirus in this manner, and it appears that NImIA is expressed in a sufficiently favorable context on the hybrid for the same mechanism to be effective. This can be interpreted to mean that the interactions between the parental viruses and their respective cellular receptors are very similar.

Catalysis of poliovirus VP0 maturation cleavage is not mediated by serine 10 of VP2.

The maturation of the poliovirus capsid occurs as the result of a single unexplained proteolytic event during which 58 to 59 copies of the 60 VP0 capsid protein precursors are cleaved. An autocatalytic mechanism for cleavage of VP0 to VP4 and VP2 was proposed by Arnold et al. (E. Arnold, M. Luo, G. Vriend, M. G. Rossman, A. C. Palmenberg, G. D. Parks, M. J. Nicklin, and E. Wimmer, Proc. Natl. Acad. Sci. USA 84:21-25, 1987) in which serine 10 of VP2 is activated by virion RNA to catalyze VP4-VP2 processing. The hypothesis rests on the observation that a hydrogen bond was observed between serine 10 of VP2 (S2010) and the carboxyl terminus of VP4 in three mature picornaviral atomic structures: rhinovirus 14, mengovirus, and poliovirus type 1 (Mahoney). We constructed mutant viruses with cysteine (S2010C) or alanine (S2010A) replacing serine 10 of VP2; these exhibited normal proteolytic processing of VP0. While our results do not exclude an autocatalytic mechanism for the maturation cleavage, they do eliminate the conserved S2010 residue as the catalytic amino acid.