The molecular mechanism of the effects of zinc ions against herpes simples virus (HSV) infection was investigated. Zinc sulphate (100 ~tM) in the culture medium of an HSV-infected African green monkey kidney cell line did not block viral DNA synthesis and, at this concentration, only moderate cytotoxic effects were observed in uninfected cells. Nevertheless, virus yields were reduced to less than 1%0 of the control. Thus the long standing hypothesis that zinc might block multiplication of HSV by selective intranuclear inhibition of the viral DNA polymerase apparently has lost its validity. Inhibition of virus growth in the absence of severe cytotoxicity must therefore result from other effects of ZnSO4. Free virus is inactivated by 15 mM-ZnSO4 within a few hours of its addition.The inactivated virus is defective in the glycoproteindependent functions of penetration and, to some extent, adsorption. Electron micrographs show massive deposition of zinc onto virion components. In a virion, transmembrane transport of zinc ions is not expected and the established antiviral effect is therefore explained by an inhibition of virion glycoprotein function after non-specific accumulation of zinc into many virion membrane components.
The relative antigenicity of the individual herpes simplex virus type 1 (KOS) glycoproteins gC and gB was analyzed in BALB/c mice by using KOS mutants altered in their ability to present these antigens on cell surface membranes during infection. The mutants employed were as follows: syn LD70, a non-temperaturesensitive mutant defective in the synthesis of cell surface membrane gC; tsF13, a temperature-sensitive mutant defective in the processing of the precursor form of gB to the mature cell surface form at 39°C; and ts606, an immediate early temperature-sensitive mutant defective in the production of all early and late proteins including the glycoproteins. By comparing the relative susceptibility to immunolysis of mouse 3T3 cells infected at 39°C with wild-type virus, presenting the full complement of the glycoprotein antigens, gC, gB, and gD, with target cells infected with mutants presenting only subsets of these antigens, we determined that a major portion of cytolytic antibody contained in hyperimmune anti-herpes simplex virus type 1 (KOS) mouse antiserum was directed against glycoproteins gC and gB. The relative immunogenicity of wild-type and mutant virus-infected cells also was compared in BALB/c mice. Immunogen lacking the mature form of gB induced a cytolytic antibody titer comparable to that of the wild-type virus, whereas that lacking the mature form of gC showed a 70% reduction in titer. The absence of the mature cell surface forms of gB and gC in immunogen preparations resulted in a 4-to 15-fold reduction in virus neutralizing titer. Animals immunized with ts606-infected cells (39°C) induced relatively little virus-specific cytolytic and neutralizing antibody. Analysis of the glycoprotein specificities of these antisera by radioimmunoprecipitation showed that the antigens immunoprecipitated reflected the viral plasma membrane glycoprotein profiles of the immunogens. The absence of the mature forms of gC or gB in the immunizing preparation did not appreciably affect the immunoprecipitating antibody response to other antigens. Mice immunized with wildtype and mutant virus-infected cells were tested for their resistance to intracranial and intraperitoneal challenge with the highly virulent WAL strain of herpes simplex virus type 1. Despite the observed alterations in serum virus-specific antibody induced with the individual immunogens, all animals survived an intraperitoneal challenge of 10 50% lethal doses. However, differences in the survival of animals were obtained upon intracranial challenge. Protection could be induced most efficiently with wild-type virus, less well with the gC and gB mutants, and the least with the early mutant ts606. The level of protection did not strictly correlate with the relative titers of virus-neutralizing antibodies; however, in general, a reduction in titer was associated with increased susceptibility to virus challenge. These findings suggest that antibody with neutralizing activity in vitro may contribute to protection against neurological herpes simplex virus infec...
SUMMARYThe absence from the medium of any of the 13 amino acids essential for cell growth has an inhibiting effect on the multiplication of adenovirus 9-I5 and adenovirus I in HeLa cell cultures. The inhibition is accentuated by previous amino acid starvation of the cultures. Whereas with arginine deprivation, the arginine pool inside the cells is at a minimum within 3o rain, the cells are assumed to adapt slowly to the new metabolic state, which is characterized by an increased 'turnover' of protein synthesis. With arginine deficiency and in Hanks' BSS some synthesis of virus and capsid proteins takes place. Quantitative and possibly qualitative differences between the influence of the various deficient media were observed.The experiments rule out DNA synthesis as a primary cause of the amino acid deficiency effect. They lead to the hypothesis that arginine deficiency inhibits the formation of an essential protein which is synthesized very late in the infectious cycle under complete MEM.
After antisense oligodeoxynucleotides (ODNs) were suggested for therapeutic use in 1978, major advances were made in developing modified oligonucleotides with increased nuclease resistance and improved cellular uptake. In the present report, positively charged nanoparticles prepared from diethylaminoethyl (DEAE)-dextran and polyhexylcyanoacrylate (PHCA) were evaluated as carriers for ODNs. The oligonucleotides were analyzed by anion-exchange HPLC. The nanoparticles exhibited a high loading capacity, with approximately 35 mumol ODNs adsorbed per gram of polymeric material. The adsorption efficacy was found to be dependent on the pH, on the ionic strength of the medium, and on the amount of DEAE-dextran. Highest loading for ODNs was achieved at pH 5.5, using a 10 mM phosphate buffer. Oligonucleotides adsorbed to the surface of the nanoparticles were nearly completely protected against degradation by the endonuclease DNase I and under in vitro cell culture conditions, whereas unprotected ODNs were totally digested under these conditions. Nanoparticles led to a 20-fold increase in cellular uptake of FITC-oligonucleotides. The internalized oligonucleotides were frequently localized as vesicular structures in the cytoplasmatic compartment. Because of their temperature-dependent uptake, we propose an active uptake mechanism, such as endocytosis, for the internalization of the ODN-nanoparticle formulations.
Virus-neutralizing monoclonal antibodies specific for 13 different genetically defined epitopes of glycoproteins gC, gB, and gD of herpes simplex virus type 1, strain KOS-321, were compared for their ability to provide passive immunity to DBA-2 mice challenged intracranially. Protection was highly specific, since individual monoclonal antibodies failed to protect against infection with monoclonal antibody-resistant (mar) mutants altered in the single epitope recognized by the injected antibody. The dose-response kinetics of passive immunity paralleled the in vitro neutralization titers for each antibody. No correlation was observed between immune protection and antibody isotype or complement-dependent in vitro neutralization titers. This suggests that virus neutralization was not the protective mechanism. In general, antibodies reactive with epitopes of gC were protective at the lowest antibody doses, antibodies specific for gB were less efficient in providing immunity, and antibodies against gD were the least effective. mar mutants with single epitope changes in gC and multiple epitope changes in gB showed highly reduced pathogenicity, requiring up to 5 x 106 PFU to kill * Corresponding author.
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