Postabsorption neutralization of poliovirus.

Nineteen neutralizing murine monoclonal antibodies against poliovirus type 1, including representatives reacting with each of the antigenic sites on the virion, were tested for their abilities to neutralize the virus either before or after attachment to susceptible cells. All antibodies neutralized unattached virus; six had reasonable titers of postabsorption neutralization (PAN). Experiments with antibodies lacking PAN activity showed that Fc-specific rabbit anti-mouse antibodies could confer PAN activity. PAN was shown to involve the prevention of the cell-mediated conversion of virus to 135S and 80S particles. Evidence that one of the PAN-positive antibodies probably bound bivalently to preabsorbed virions, whereas a PAN-negative antibody bound monovalently, is presented. Two PAN-positive antibodies were added to an excess of virus in suspension, and only one antibody caused the virus to aggregate.     

Inactivation of poliovirus by chloramine-T.

Since concern has recently been expressed about the presence of genotoxic substances due to chlorination of water and wastewater, chloramine-T (CAT) is proposed as an alternative disinfectant to chlorine. The viricidal properties of chlorine and CAT were compared. Kinetics of inactivation of poliovirus type 2 by chlorine and CAT in chlorine demand-free water were investigated by using a kinetic apparatus. Inactivation of the virus by chlorine and CAT occurred in two steps. The initial linear part of the inactivation curve followed a pseudo-first-order reaction with the virus. An obvious dose-response relationship was demonstrated with CAT. The rate of inactivation of the virus by CAT was faster in acid medium than in alkaline medium. Inactivation kinetic studies were performed at different temperatures, and the kinetic, Arrhenius, and thermodynamic parameters were evaluated. The rate of inactivation of poliovirus type 2 by chlorine was faster than that by CAT under identical conditions. A mechanism for the viral inactivation in acid conditions was proposed which led to a rate equation consistent with the experimental results. The results indicate that CAT may be an effective viricide against poliovirus type 2 in an acid medium.     

Reconcentration of poliovirus from sewage.

Virus can be adsorbed from effluents of sewage treatment plants on large-surface membranes. Subsequent elution of virus requires large volumes, which in turn requires reconcentration of virus for assay. However, reconcentration of such viral eluates on small adsorbent surfaces is difficult because certain soluble sewage components are adsorbed along with the virus on the initial virus adsorbent and are removed along with the virus by the eluent. Upon acidification of the initial eluate to reconcentrate the virus on smaller membrane surfaces, flocs are formed that interfere with the reconcentration process. To circumvent this problem, the interfering sewage components can be removed by activated carbon and ion-exchange resins. The virus is then readily reconcentrated on small membranes.     

Human poliovirus receptor gene expression and poliovirus tissue tropism in transgenic mice.

Expression of the human poliovirus receptor (PVR) in transgenic mice results in susceptibility to poliovirus infection. In the primate host, poliovirus infection is characterized by restricted tissue tropism. To determine the pattern of poliovirus tissue tropism in PVR transgenic mice, PVR gene expression and susceptibility to poliovirus infection were examined by in situ hybridization. PVR RNA is expressed in transgenic mice at high levels in neurons of the central and peripheral nervous system, developing T lymphocytes in the thymus, epithelial cells of Bowman's capsule and tubules in the kidney, alveolar cells in the lung, and endocrine cells in the adrenal cortex, and it is expressed at low levels in intestine, spleen, and skeletal muscle. After infection, poliovirus replication was detected only in neurons of the brain and spinal cord and in skeletal muscle. These results demonstrated that poliovirus tissue tropism is not governed solely by expression of the PVR gene nor by accessibility of cells to virus. Although transgenic mouse kidney tissue expressed poliovirus binding sites and was not a site of poliovirus replication, when cultivated in vitro, kidney cells developed susceptibility to infection. Identification of the changes in cultured kidney cells that permit poliovirus infection may provide information on the mechanism of poliovirus tissue tropism.     

Protein processing map of poliovirus.

Five previously unmapped proteins (5a, 7d, 8, 9b, and 10) were located on the proteolytic processing map of the polyprotein. One of the proteins, 9b, appears to be the sister fragment of a cleavage reaction (P3-9 leads to P3-9b + VPg). Two of the other newly mapped proteins, 8 and 10, have been identified as sister fragments of X-related proteins 3b and 5b; thus, P2-3b leads to P2-8 + P2-5b and P2-5b leads to P2-10 + P2-X. The remaining proteins, 5a and 7d, mapped in the 1b protein and appear to result from the cleavages P3-1b leads to P3-5a + P3-6b and P3-4b leads to P3-7d + P3-6b. These assignments account for over 95% of the total polioviral proteins and complete the mapping of the major processing pathways.     

Reconcentration of poliovirus from sewage.

Virus can be adsorbed from effluents of sewage treatment plants on large-surface membranes. Subsequent elution of virus requires large volumes, which in turn requires reconcentration of virus for assay. However, reconcentration of such viral eluates on small adsorbent surfaces is difficult because certain soluble sewage components are adsorbed along with the virus on the initial virus adsorbent and are removed along with the virus by the eluent. Upon acidification of the initial eluate to reconcentrate the virus on smaller membrane surfaces, flocs are formed that interfere with the reconcentration process. To circumvent this problem, the interfering sewage components can be removed by activated carbon and ion-exchange resins. The virus is then readily reconcentrated on small membranes.     

Polyadenylic acid on poliovirus RNA. III. In vitro addition of polyadenylic acid to poliovirus RNAs.

A crude RNA polymerase preparation was made from HeLa cells infected for 3 h with poliovirus. All virus-specific RNA species labeled in vitro (35S RNA, replicative intermediate RNA [RI], and double-stranded RNA [dsRNA]) would bind to poly(U) filters and contained RNase-resistant stretches of poly(A) which could be analyzed by electrophoresis in polyacrylamide gels. After incubation for 45 min with [3-H]ATP in the presence of the other three nucleoside triphosphates, the labeled poly(A) on the RI and dsRNA migrated on gels as relatively homogenous peaks approximately 200 nucleotides in length. In contrast, the poly(A) from the 35S RNA had a heterogeneous size distribution ranging from 50 to 250 nucleotides. In the absence of UTP, CTP, and GTP, the size of the newly labeled poly(A) on the dsRNA and RI RNA was the same as it was in the presence of all four nucleoside triphosphates. However the poly(A) on the 35S RNA lacked the larger sequences seen when the other three nucleoside triphosphates were present. When [3-H]ATP was used as the label in infected and uninfected extracts, heterogeneous single-stranded RNA sedimenting at less than 28S was also labeled. This heterogeneous RNA probably represents HeLa cytoplasmic RNA to which small lengths of poly(A) (approximately 15 nucleotides) had been added. These results indicate that in the in vitro system poly(A) can be added to both newly synthesized and preexisting RNA molecules. Furthermore, an enzyme capable of terminal addition of poly(A) exists in both infected and uninfected extracts.     

Post-eradication poliovirus facility-associated community risks.

Minimizing the risk of poliovirus transmission from the poliovirus facility to an increasingly susceptible community is crucial when global poliovirus transmission and OPV use stops. Community risks of exposure to wild poliovirus as well as Sabin strains are highest from facility personnel who are unknowingly contaminated or infected. Immunization with OPV or IPV prevents poliomyelitis, but neither vaccine fully inhibits silent infection of the gut. Facility environments maintained at low relative humidity (<50%) may reduce poliovirus survival and inhalation risk. Circulating antibodies reduce personnel infection risks from injection or virus entry through breaks in skin or mucous membranes. Community exposure risk through inhalation of contaminated air effluent is likely low in most modern facilities. Community risks through ingestion of liquid effluents are facility-specific and may range from high to low. This assessment of community risks, when combined with assessments of facility-specific hazards and the consequences of wild or Sabin poliovirus transmission, provides the foundation for effective risk management.     

Carboxy-terminal analysis of poliovirus proteins: termination of poliovirus RNA translation and location of unique poliovirus polyprotein cleavage sites.

The carboxy-terminal amino acids of a number of poliovirus proteins were determined by carboxypeptidase A analysis. The nonstructural proteins P3-2, P3-4b and their precursor. P3-1b, were found to be coterminal with a sequence of -Ser-Phe-COOH. As these proteins are coded for at the extreme 3' end of the viral RNA, it is possible to establish the termination site of translation at nucleotide 7,361, 73 nucleotides before the start of the polyadenylic acid tract of the RNA. Two additional nonstructural proteins, P2-X and its precursor, P2-3b, were also found to be coterminal with a sequence of -Phe-Gln-COOH. This result confirms the existence of at least one Gln-Gly proteolytic cleavage site. These Gln-Gly cleavage sites are predicted from the nucleotide sequence to be ubiquitous throughout the poliovirus genome. The only exceptions are the cleavage sites at the carboxy termini of the structural protein VP4 and VP1. Carboxypeptidase A analysis of VP1 establishes a terminal sequence of -Thr-Tyr-COOH, and similar analysis of VP4 shows Asn to be the terminal amino acid residue, observations that prove the existence of the exceptional C-terminal amino acids. In none of the analyzed cases has C-terminal trimming after cleavage been observed.     

A chimeric poliovirus/CD4 receptor confers susceptibility to poliovirus on mouse cells.

The human poliovirus receptor consists of three extracellular immunoglobulinlike domains, a transmembrane domain, and an intracytoplasmic domain. The amino-terminal variable-type domain (V domain) of the human poliovirus receptor is necessary and sufficient for its function as a viral receptor (H.-C. Selinka, A. Zibert, and E. Wimmer, Proc. Natl. Acad. Sci. USA 88:3598-3602, 1991). In this paper, data are presented showing that transfer of the putative poliovirus receptor-binding domain to a truncated receptor for the human immunodeficiency virus results in a functional receptor for poliovirus. After expression in mouse cells, this chimeric protein confers susceptibility to poliovirus. Thus, unlike human immunodeficiency virus, poliovirus can enter mouse cells by way of a truncated CD4 receptor if the specific binding domain for poliovirus is provided.     

Relationship between poliovirus neutralization and aggregation.

The interaction of mono- and polyclonal neutralizing antibodies with poliovirus was studied. In all cases, neutralization was due to antibody-mediated virus aggregation, and the unpolymerized virions accounted for the residual infectivity. The effect of papain on previously neutralized virus was to deaggregate the virus to fully infective single virions. With some antibodies, the amount of aggregated virus regressed in the region of greatest antibody excess, even though the virus remained fully neutralized. Under these conditions, noninfective, unaggregated immune complexes were formed. A mutant resistant to one of the monoclonal antibodies was selected. The mutant virions were still bound but no longer aggregated or neutralized by the selecting antibodies.     

Inactivation of poliovirus in digested sludge.

The effect of anaerobically digested sludge on poliovirus during incubation at temperatures between 28 and 4 C was studied. Although virus was fully recoverable from sludge, its infectivity decreased in proportion to the time and temperature of incubation. The rate ranged from greater than 1 log per day at 28 C to about 1 log every 5 days at 4 C. The mechanism of inactivation was studied at the lower temperature where the sedimentation coefficients of most inactivated particles were not detectably modified. The ribonucleic acid (RNA) of these particles appeared to have been nicked and had an average sedimentation value about 70% that of RNA from infectious virus. Since the specific infectivity of RNA from particles recovered from sludge was directly proportional to that of the particles from which it was extracted, loss of infectivity was probably due to inactivation of RNA. Some breakdown was also found in the two largest viral proteins of inactivated particles. Thus, the mechanism of inactivation may be cleavage of viral proteins followed by nicking of encapsulated RNA. Because no virucidal activity was found in raw sludge, this component of digested sludge appears to be a product of the digestion process.