A rapid method to quantify neurons in mixed cultures based on the specific binding of [3H]ouabain to neuronal Na+,K(+)-ATPase.

The high-affinity binding of [3H]ouabain to Na+,K(+)-ATPase was characterized in primary cultures of hippocampal neurons grown on feeder layers of astrocytes. The specific binding of [3H]ouabain was found to be time-dependent, high-affinity (apparent Kd = 8.5 nM), saturable (Bmax = 20.6 pmol/mg protein), dependent upon the presence of ATP, inhibited by K+, and directly proportional to neuronal, but not glial, cell number. Similar results were obtained using either sonicated cell suspensions or intact whole cells in culture. At the concentration of neurons routinely used, the specific binding of [3H]ouabain to the astrocyte feeder layer constituted less than 10% of total specific binding. Agents that selectively kill neurons rather than glia, such as the excitotoxins N-methyl-D-aspartate (NMDA) and kainate, reduced the amount of [3H]ouabain specifically bound in mixed cultures in a time- and concentration-dependent manner. Measurement of high-affinity [3H]ouabain binding to the neuronal form of Na+,K(+)-ATPase provides a simple, rapid, and reproducible method to quantify neurons in mixed culture.

Influenza viruses induce autoantibodies to a brain-specific 37-kDa protein in rabbit.

Immunization of rabbits with certain H1N1 influenza viruses, including the neurotropic strains NWS/33 and WSN/33 and the New Jersey/76 strain, resulted in the production of autoantibodies to a brain-specific protein of 37 kDa that is present in various species, including humans. Autoantibodies were produced to brain only; various other tissues tested were negative. These antibodies were not elicited by other influenza A or B viruses, including closely related recombinant strains, but were elicited by the isolated hemagglutinin of A/Bellamy/42 strain and by formaldehyde-fixed WSN virus--demonstrating that infection was not essential for the induction of autoantibodies. In histological studies, reaction with anti-viral antisera was specific to gray matter and was confined to sera that recognized the 37-kDa protein. Antibody binding was prominent in regions comprised of neuronal cell bodies in cellular layers of the dentate gyrus, hippocampus, cerebral cortex, and cerebellum and was undetectable in myelin-rich regions, such as the corpus callosum. The 37-kDa protein, therefore, appears to be a neuronal antigen. Antibodies directed against this protein may be involved in the pathogenesis of one or more of the neuropsychiatric disorders that occur after infection with influenza.

Scenarios for a viral etiology of schizophrenia.

Recent discoveries in the field of virus receptors have revolutionized our concepts of viral pathogenesis. The lysis of cells resulting from virus infection or immune recognition of infected cells is seen as merely one facet of a spectrum of pathogenic mechanisms which may be subtle and complex. This is particularly relevant to the central nervous and immune systems which share cell-surface receptors for various neuropeptides and neurotransmitters. A number of viruses are now known to share receptors for such endogenous ligands; indeed, some viruses (e.g., human immunodeficiency virus and vaccinia) may themselves be structural analogs of these ligands. There is, therefore, considerable scope for interference by viruses in the normal functioning of the brain and neuroendocrine systems. Brief reactive psychoses are occasionally reported as acute sequels to viral infections, but generally these are regarded as unrelated to schizophrenia. An opposite viewpoint is presented in the article: i.e., that the only reason these reactive psychoses do not progress to schizophrenia is that the majority of individuals affected are not predisposed genetically to schizophrenia. Conceivably, therefore, the genetic predisposition to schizophrenia may be attributable to genes which determine idiosyncratic differences in immune responsiveness to common viral pathogens.

Expression of gangliosides as receptors at the cell surface controls infection of NCTC 2071 cells by Sendai virus.

The involvement of gangliosides as receptors for Sendai virus was established previously using experimentally produced receptor-deficient cells. In the search for a naturally occurring counterpart, NCTC 2071 cells emerged as a likely candidate. These cells in their native state were not agglutinated nor infected by Sendai virus, but were infected by the virus when the gangliosides GD1a, GT1b, or GQ1b were supplied in the culturing medium. Preliminary analysis indicated that NCTC 2071 cells contained an unusually high ratio of sialoglycoproteins to gangliosides. A brief treatment of the cell surface with the protease trypsin made greater than 99% of the native monolayer susceptible to infection by the wild-type virus which contains the viral attachment protein HN. (Incubation of the trypsin-treated cells with a temperature-sensitive mutant missing HN produced no detectable infection.) The increased binding of cholera toxin, a ganglioside-specific probe, after incubation of the cells with trypsin and sialidase, was consistent with the hypothesis that gangliosides more complex than GM1 are on the surface of NCTC 2071 cells and that trypsin treatment increases their accessibility. The presence of receptor gangliosides in lipid extracts of NCTC 2071 cells was confirmed by thin-layer chromatography of the ganglioside fraction and by the binding of cholera toxin. These results demonstrate that cells containing receptor gangliosides may still be resistant to infection because these are not expressed properly at the cell surface as receptors for interaction with the HN protein of Sendai virus.

An alternative route of infection for viruses: entry by means of the asialoglycoprotein receptor of a Sendai virus mutant lacking its attachment protein.

During the first stage of infection, the paramyxovirus Sendai virus attaches to host cells by recognizing specific receptors on the cell surface. Productive virus-cell interactions result in membrane fusion between the viral envelope and the cell surface membrane. It has recently been shown that the ganglioside GD1a and its more complex homologs GT1b and GQ1b are cell surface receptors for Sendai virus. We report in this paper that the temperature-sensitive mutant ts271 of the Enders strain of Sendai virus lacks the viral attachment protein HN and the biological activities of hemagglutination and sialidase activity associated with it when the virus is grown at 38 degrees C. This HN- virus was unable to infect or agglutinate conventional host cells that contained receptor gangliosides and were readily infected by the parental wild-type virus. The HN- virus did, however, attach to and infect Hep G2 cells, a line of hepatoma cells that retains the asialoglycoprotein receptor (ASGP-R) upon continuous culture. This receptor is a mammalian lectin that recognizes galactose- or N-acetylgalactosamine-terminated proteins. In accordance with the known properties of this receptor, infection by the HN- virus was abolished by treatment of Hep G2 cells with sialidase, by the presence of Ca2+ chelators, and by competition with N-acetylgalactosamine, asialoorosomucoid, and antibody to the receptor. F, the only glycoprotein on the HN- virus, was shown to compete with the galactose-terminated protein asialoorosomucoid for the ASGP-R. The ability of the HN- virus to cause cell-cell fusion of Hep G2 cells indicated that attachment of this virus to the ASGP-R still permitted viral entry by its usual mode--i.e., membrane fusion at the cell surface. These results open up the possibility that enveloped viruses, which contain glycosylated proteins or lipids, may make use of naturally occurring lectins in addition to their normal receptors as a means of attachment to host cells.

Receptor ganglioside content of three hosts for Sendai virus. MDBK, HeLa, and MDCK cells.

Specific gangliosides GD1a, GT1b and GQ1b isolated from brain have been shown to function as receptors for Sendai virus by conferring susceptibility to infection when they are incorporated into receptor-deficient cells (Markwell, M.A.K., Svennerholm, L. and Paulson, J.C. (1981) Proc. Natl. Acad. Sci. USA 78, 5406-5410). The endogenous gangliosides of three commonly used hosts for Sendai virus: MDBK, HeLa, and MDCK cells were analyzed to determine the amount and type of receptor gangliosides present. In all three cell lines, GM3 was the major ganglioside component. The presence of GM1, GD1a and the more complex homologs of the gangliotetraose series was also established. In cell lines derived from normal tissue, MDBK and MDCK cells, gangliosides contributed 47-65% of the total sialic acid. In HeLa cells, gangliosides contributed substantially less (17% of the total sialic acid). The ganglioside content of each cell line was shown not to be immutable but instead to depend on the state of differentiation, passage number, and surface the cells were grown on. Thus, the ganglioside concentration of undifferentiated MDCK cells was found to be substantially greater than that of MDBK or HeLa cells, but decreased as the MDCK cells underwent differentiation. Changes in culture conditions that were shown to decrease the receptor ganglioside content of the cells resulted in a corresponding decrease in susceptibility to infection. The endogenous oligosialogangliosides present in susceptible host cells were shown to function as receptors for Sendai virus.

Specific gangliosides function as host cell receptors for Sendai virus.

The ability of specific gangliosides to function as host cell receptors for Sendai virus was investigated by using Madin-Darby bovine kidney cells which become resistant to infection upon treatment with Vibrio cholerae sialidase. Sialidase-treated cells were incubated for 20 min at 37 degrees C with individual, highly purified gangliosides containing homogeneous carbohydrate moieties and then inoculated with virus for 10 min. Susceptibility of the cells to infection was monitored by hemagglutination titer of the virus produced 48 hr after inoculation. Incubation of the cells with gangliosides containing the sequence NeuAc alpha 2,3Gal beta 1,3GalNAc (i.e., GD1a, GT1b, and GQ1b) fully restored susceptibility to infection to the cells. However, the ganglioside GQ1b in which the sequence ends with two sialic acids in a NeuAc alpha 2,8NeuAc linkage instead of a single sialic acid as in GD1a and GT1b, was effective as a receptor at a concentration 1/100th that of any of the other gangliosides tested. Incubation with gangliosides similar in structure to GD1a, GT1b, and GQ1b but lacking the sialic acid attached to the terminal galactose (i.e., GM1 and GD1b) had no effect. The results from control experiments in which gangliosides were incubated at 0 degrees C with cells or in which trypsin was used to remove gangliosides adsorbed to cells were consistent with the premise that the gangliosides must actually insert into the cellular membrane to function as Sendai virus receptors. Addition of 4 X 10(6) molecules of 14C-labeled GD1a per cell made the cells fully susceptible to infection. Analysis of the ganglioside content of cell membranes showed that gangliosides GD1a, GT1b, and GQ1b are natural components of these cells and are present in quantities sufficient to act as receptors. These results demonstrate that gangliosides with the proper carbohydrate sequence, such as GD1a, GT1b, and GQ1b, function as natural receptors for Sendai virus in host cells.

Sendai virus utilizes specific sialyloligosaccharides as host cell receptor determinants.

Purified sialyltransferases (CMP-N-acetyl-neuraminate:D-galactosyl-glycoprotein N-acetylneuraminyl-transferase, EC 2.4.99.1) in conjunction with neuraminidase (acylneuraminyl hydrolase, EC 3.2.1.18) were used to produce cell surface sialyloligosaccharides of defined sequence to investigate their role in paramyxovirus infection of host cells. Infection of Madin-Darby bovine kidney cells by Sendai virus was monitored by hemagglutination titer of the virus produced and by changes in morphological characteristics. By either criterion, treatment of the cells with Vibrio cholerae neuraminidase to remove cell surface sialic acids rendered them resistant to infection by Sendai virus. Endogenous replacement of receptors by the cell occurred slowly but supported maximal levels of infection within 6 hr. In contrast, sialylation during a 20-min incubation with CMP-sialic acid and beta-galactoside alpha 2,3-sialytransferase restored full susceptibility to infection. This enzyme elaborates the NeuAc alpha 2,3Gal beta 1,3GalNAc (NeuAc, N-acetylneuraminic acid) sequence on glycoproteins and glycolipids. No restoration of infectivity was observed when neuraminidase-treated cells were sialylated by using beta-galactoside alpha 2,6-sialytransferase, which elaborates the NeuAc-alpha 2,6Gal beta 1,4GlcNAc sequence. These results suggest that sialyloligosaccharide receptor determinants of defined sequence are required for Sendai virus infection of host cells.

Protein-protein interactions within paramyxoviruses identified by native disulfide bonding or reversible chemical cross-linking.

Analysis of native disulfide-bonded protein oligomers in paramyxoviruses showed that some viral proteins are consistently present as covalent complexes. In isolated Sendai virus the hemagglutinating protein HN is present in homodimeric and homotetrameric forms, and the minor nucleocapsid protein P exists partly as a monomer and partly as a disulfide-linked homotrimer. Similar disulfide-linked complexes were observed in Newcastle disease virus (strain HP-16), in which HN exists as a homodimer and some of the major nucleocapsid protein NP exists as a homotrimer. Noncovalent intermolecular interactions between proteins were studied with the reversible chemical cross-linkers dimethyl-3,3'-dithiobispropionimidate and methyl 3-[(p-azidophenyl)dithio]propionimidate, which contain disulfide bridges and a 1.1-nm separation between their functional groups. The same results were achieved with both reagents. The conditions of preparation, isolation, and storage of the viruses affected the protein-protein interactions observed upon cross-linking. Homooligomers of the glycoprotein F, the matrix protein M, and the major nucleocapsid protein NP were produced in both Sendai and Newcastle disease viruses after mild cross-linking of all viral preparations examined, but NP-M heterodimer formation in both viruses was most prevalent in early harvest preparations that were cross-linked soon after isolation. The ability of NP and M to form a heterodimer upon cross-linking indicates that the matrix protein layer lies in close proximity (within 1.1 nm) to the nucleocapsid in the newly formed virion. Some noncovalent intermolecular protein interactions in Sendai and Newcastle disease viruses, i.e., those leading to the formation of F, NP, and M homooliogmers upon cross-linking, are more stable to virus storage than others, i.e., those leading to the formation of an NP-M heterodimer upon cross-linking. The storage-induced loss of the ability of NP and M to form a heterodimer is not accompanied by any apparent loss of infectivity. This indicates that some spacial relationships which form during virus assembly can alter after particle formation and are not essential for the ensuing stages of the infectious process.

Surface-specific iodination of membrane proteins of viruses and eucaryotic cells using 1,3,4,6-tetrachloro-3alpha,6alpha-diphenylglycoluril.

The use of the iodinating reagent 1,3,4,6-tetrachloro-3alpha,6alpha-diphenylglycouril (chloroglycoluril) to selectively label membrane surface proteins was investigated with the following systems: enveloped viruses (Sendai and Newcastle disease viruses), human erythrocytes, and nucleated cells propagated both in suspension (EL-4) and in monolayer culture (BHK-21). Conditions are described for specifically iodinating surface proteins while maintaining full virus integrity or cell viability. Comparison of the chloroglycoluril method with the lactoperoxidase and chloramine-T methods for labeling surface membrane proteins shows that the chloroglycoluril method has a number of advantages: It routinely produces a 3- to 17-fold greater specific radioactivity without sacrificing viral or cellular integrity, it is technically simpler to use, it does not require the addition of extraneous protein to initiate the reaction nor a strong reducing reagent to terminate it. Chloroglycoluril also proved to be an effective substitute for chloramine-T in the nonvectorial labeling of viral and cellular proteins. Membrane protein samples were solubilized with the detergent sodium dodecyl sulfate before iodination or labeled in the presence of high iodide concentrations without prior solubilization. The resulting specific radioactivities generated by the use of chloroglycoluril were equal to or greater than those generated by the chloramine-T method. The effectiveness, simplicity of use, and versatility of chloroglycoluril recommend it as an iodinating reagent for both surface-specific and nonvectorial labeling of membrane systems.