Pathogens Inactivated by Low-Energy-Electron Irradiation Maintain Antigenic Properties and Induce Protective Immune Responses.

Inactivated vaccines are commonly produced by incubating pathogens with chemicals such as formaldehyde or ß-propiolactone. This is a time-consuming process, the inactivation efficiency displays high variability and extensive downstream procedures are often required. Moreover, application of chemicals alters the antigenic components of the viruses or bacteria, resulting in reduced antibody specificity and therefore stimulation of a less effective immune response. An alternative method for inactivation of pathogens is ionizing radiation. It acts very fast and predominantly damages nucleic acids, conserving most of the antigenic structures. However, currently used irradiation technologies (mostly gamma-rays and high energy electrons) require large and complex shielding constructions to protect the environment from radioactivity or X-rays generated during the process. This excludes them from direct integration into biological production facilities. Here, low-energy electron irradiation (LEEI) is presented as an alternative inactivation method for pathogens in liquid solutions. LEEI can be used in normal laboratories, including good manufacturing practice (GMP)- or high biosafety level (BSL)-environments, as only minor shielding is necessary. We show that LEEI efficiently inactivates different viruses (influenza A (H3N8), porcine reproductive and respiratory syndrome virus (PRRSV), equine herpesvirus 1 (EHV-1)) and bacteria (Escherichia coli) and maintains their antigenicity. Moreover, LEEI-inactivated influenza A viruses elicit protective immune responses in animals, as analyzed by virus neutralization assays and viral load determination upon challenge. These results have implications for novel ways of developing and manufacturing inactivated vaccines with improved efficacy.

A blocking ELISA for detection of antibody to a subgroup-reactive epitope of African horsesickness viral protein 7 (VP7) using a novel gamma-irradiated antigen.

A novel gamma irradiated inactivated cell culture derived African horsesickness viral (AHSV) antigen was used in a blocking ELISA (B-ELISA) for detecting antibody to a subgroup-reactive epitope of AHSV. A monoclonal antibody (MAB), class IgM, against an epitope on African horsesickness (AHS) viral protein 7 (VP7) was developed in BALBc mice and used in the B-ELISA. The MAB, designated F9H, was blocked by 69 serums from equidae with antibody to AHS, but its binding activity was not appreciably affected by 301 serums that did not contain antibodies to AHS virus. An ELISA protocol using a blocking format is described.

[The immunity indices of BALB/c mice immunized with an inactivated antigen of the Machupo virus]. / Pokazateli immuniteta u myshei linii BALB/c, immunizirovannykh inaktivirovannym antigenom virusa Machupo.

The paper presents the data characterizing parameters of specific and nonspecific immunity in BALB/c mice immunized with gamma-ray-inactivated Machupo virus antigen or its formalinized antigen. The gamma-ray inactivated preparation was shown to be more immunogenic for BALB/c mice. A certain relationship between the time course of activity of nonspecific immunity factors in the immunized animals and the protective activity of the preparation under study was also noted. The decisive role of the T-cell part of the immune system was demonstrated in the resistance of this model animal to Machupo virus infection.

Effect of gamma irradiation on reactivity of rinderpest virus antigen with bovine immune serum in enzyme-linked immunosorbent assays and virus neutralization and indirect fluorescent-antibody tests.

Gamma irradiation effectively inactivated gradient-purified rinderpest virus. Irradiated antigen and sera remained functional in enzyme-linked immunosorbent assays, virus neutralization tests, and indirect fluorescent-antibody tests. Irradiation, however, led to a dose-dependent decrease in reactivity, particularly significant (P < 0.05) when both reagents were irradiated. To avoid false-positive reactions, only one reagent (serum or antigen) may be irradiated.

Evidence for putative immediate early antigens in human herpesvirus 6-infected cells.

Human herpesvirus 6 (HHV-6) induced nuclear antigens in cells as early as 3 h after infection. These nuclear antigens were induced by all three strains of HHV-6 tested, and their de novo synthesis required the function(s) of the intact viral genome. Their appearance was not affected by 2,2'-anhydro(1-beta-D-arabinofuranosyl)cytosine, but was completely inhibited by cycloheximide. However, the nuclear antigens did appear if cycloheximide was replaced with actinomycin D. Thus, the nuclear antigens seem to be equivalent to the immediate early antigens of other herpesviruses.

Photochemical inactivation of viruses with psoralens: an overview.

In the presence of longwave ultraviolet light, psoralen derivatives photoreact with the nucleic acids within intact viruses and cells. This photoreaction can leave protein antigens and other surface components relatively unmodified, while eliminating the infectivity of a wide range of infectious agents. The kinetics of inactivation differ among RNA and DNA viruses photoreacted with different derivatives of psoralen. The inactivation kinetics are nonlinear as a result of photodegradation of psoralens and the unexplained biphasic inactivation of some viruses. In spite of these complexities, the photoreaction is capable of generating broad safety margins in the disinfection of microbial products under gentle, physiologic conditions. The psoralen photoreaction provides a potential method for inactivating both known and unknown viruses in active blood products. Psoralen-inactivated viruses have already proven useful as noninfectious antigens for use in immunoassays and as successful experimental vaccines.

Gamma irradiation alters bluetongue virus protein antigen.

Bluetongue virus (BTV) antigen, prepared for a monoclonal antibody (MAb)-based competitive enzyme-linked immunosorbent assay (C-ELISA), was exposed to 1, 2, 3, 4, 5 and 6 Mrad of gamma irradiation. The major group-specific BTV protein (VP7) reactive with the Mab was altered at higher doses of radiation, as revealed by immunoblotting studies. As well, a reduction in immunoreactivity was noted when irradiated antigen was used in the ELISA.

Inactivation and stability of viral diagnostic reagents treated by gamma radiation.

The objective of this study was to apply the pertinent findings from gamma inactivation of virus infectivity to the production of high quality diagnostic reagents. A Gammacell 220 (Atomic Energy of Canada, Ltd., Ottawa, Canada) was used to subject 38 viruses grown in either susceptible tissue cultures or embryonated chicken eggs to various doses of gamma radiation from a cobalt-60 source. The radiation required to reduce viral infectivity was 0.42 to 3.7 megarads (Mrad). The effect of gamma treatment on the antigenic reactivity of reagents for the complement fixation (CF), hemagglutination (HA) and neuraminadase assays was determined. Influenza antigens inactivated with 1.7 Mrad displayed comparable potency, sensitivity, specificity and stability to those inactivated by standard procedures with beta-propiolactone (BPL). Significant inactivation of influenza N1 and B neuraminidase occurred with greater than 2.4 Mrad radiation at temperatures above 4 degrees C. All 38 viruses were inactivated, and CF or HA antigens were prepared successfully. Antigenic potency remained stable with all antigens for 3 years and with 83% after 5 years storage. Influenza HA antigens evaluated after 9 years of storage demonstrated 86% stability. Gamma radiation is safer than chemical inactivation procedures and is reliable and effective replacement for BPL in preparing diagnostic reagents.

Retention of immunogenicity after X-irradiation of mouse colon tumor cells expressing the transfected influenza virus hemagglutinin gene.

We have previously demonstrated that murine colon tumor cells transfected with the gene coding for the hemagglutination antigen (HA) of influenza virus acquire an inherent immunogenicity, fail to grow in syngeneic mice, and demonstrate an ability to cross-protect against a challenge with parental nontransfected cells. In the present study the immunogenic potential of HA-transfected cells correlated with cell-surface HA expression, as measured both by a fluorescence-activated cell sorter and by radio-labeled antibody binding. HA-transfected immunogenic cells had a median lethal dose (LD50) that was 10,000-fold greater than that of nontransfected cells. Most importantly this study demonstrated that HA-transfected cells retained their immunogenicity after X-irradiation with 12,000 rad. This characteristic makes their potential usefulness in treating human neoplasia more plausible.

Endogenous murine leukemia viruses: frequency of radiation-activation and novel pathogenic effects of viral isolates.

Female C57BL/6 and BALB/c mice were injected i.p. with 0.06 microCi/kg or 0.5 microCi/kg of the short-lived alpha-emitting radionuclide 224radium at 3-day intervals. Infectious N-ecotropic XC+, and xenotropic C-type retroviruses were activated in several tissues in both strains. In C57BL/6 mice the activation of ecotropic and xenotropic virus was dose-dependent as observed 4 weeks after the start of irradiation. In BALB/c mice a few animals showed activation of ecotropic virus after four weeks of irradiation. The expression of xenotropic virus was similar in irradiated mice and controls. Viral antigen, indicative for viraemia, was not detected in irradiated or control animals. Antiviral antibodies were found in both control and irradiated mice but higher titers were found in the irradiated mice. Bone tissue-derived N-tropic XC+ virus isolates were found to be non-oncogenic in newborn mice of the parental strain. In contrast, the same virus isolates induced a novel pattern of disease, such as osteopetrosis and osteomas together with malignant lymphomas in NMRI mice. The data indicate that the pattern of endogenous murine leukemia virus activation by internal alpha-irradiation is dependent on the dose rate, and on the genetics of the mouse strain.

[Biological consequences of the decay of 3H and 14C incorporated into the influenza virus]. / Nekotorye biologicheskie posledstviia raspada 3H i 14C, inkorporirovannykh v virus grippa.

An influenza virus labeled with 3H-uridine loses its infectiousness when stored for a long time. It is suggested that disintegration of tritium incorporated into virus RNA causes lethal intramolecular modifications therein. At the same time, the antigenic activity of virus nucleoprotein decreases perhaps due to the direct effect of tritium. The comparison of the degree of inactivation of various antigenic sites of the nucleoprotein within a virus labeled with 3H-uridine, suggests that they are located at different distances from RNA. A long-term action of 3H disintegration on RNA of a maturing virus decreases the yield probably due to the injury of the intracellular virus RNA during the infections process. Upon storage of the influenza virus labelled with 14C-amino acids the antigenic properties are reduced by the nucleoprotein while the infectiousness remains unaffected. The long-term effect of 14C disintegration on proteins of the maturing virus does not lead to fatal outcome.

Reactivation of herpes simplex virus is associated with production of a low molecular weight factor that inhibits lymphokine activity in vitro.

Peripheral blood mononuclear cells obtained during recrudescent Herpes simplex virus (HSV) infection and stimulated with UV-inactivated viral antigen (UV-HSV) for 24 hr produced a low molecular weight (dialyzable) factor that inhibited lymphokine activity. This factor prevented the expression of leukocyte inhibitory factor (LIF) activity, but not its production. It was not made in UV-HSV-stimulated cultures grown in presence of 2 X 10(-6) M indomethacin nor in cultures of peripheral blood mononuclear cells obtained during convalescence or quiescence (greater than 4 days from onset of clinical symptoms) or from seropositive controls without a history of recurrent HSV disease. Dialyzable inhibitory factor production required OKM1+, OKT8+, and OKIa+ cells as determined by complement-mediated lysis with monoclonal antibody. Dialyzable inhibitory factor activity was associated with a trypsin-sensitive 8.2 K fraction as determined by Sephadex chromatography followed by sodium dodecyl sulfate-acrylamide gel electrophoresis.

Effect of beta-decay of radionuclides incorporated into influenza virus RNA and proteins on the infectivity of the virus and antigenicity of its nucleoprotein.

The effect of beta-decay of radionuclides incorporated into influenza virus on the properties of the two closely adjacent structures--RNA and nucleoprotein (NP)--was studied. The long-term storage of 3H-uridine labelled influenza virus was shown to lead to the loss of infectivity. This effect may be explained by lethal intra-molecular modifications of viral RNA, caused by beta-decay of 3H incorporated into the molecule. There was an accompanying decrease of monoclonal antibody (MAB) binding activity, this also being a plausible result of beta-decay. The different rates of inactivation of MAB binding activity of different epitopes of NP of the 3H-labelled virus shown in our studies suggest that there are different types of structural organization or different location of these epitopes in the NP. The effect of 3H-decay on the intracellular RNA of reproducing virus lead to a decrease in virus yield; this may be due to radiation- and transmutation-induced damage of messenger and progeny RNA populations synthesized during the infection. The storage of influenza virus labelled with 14C-aminoacids lead to a decrease in MAB binding activity of the NP that was unaccompanied by a decrease in infectivity. Furthermore, 14C-decay in proteins of reproducing virus had no adverse effect.

[Principles of selective inactivation of the virus genome. IV. The effect of UV-irradiation of phage MS2 on its binding with anti-MS2-immunoglobulins]. / Printsipy selektivnoi inaktivatsii virusnogo genoma. IV. Vliianie UF-oblucheniia faga MS2 na ego sviazyvanie s anti-MS2-immunoglobulinami.

Ultraviolet (254 nm) irradiation of the bacteriophage MS2 results in the decrease of the number of antigenic determinants exposed on the virion surface. The cross-section of the decrease, as measured by the number of anti-MS2 IgG molecules bound per virion, is 10(-16) mm2 per photon. The decrease of the phage-antibody binding proceeds after irradiation with a rate constant of about 5 x 10(-3) min-1. Since the antigenic determinants of the phage MS2 coat protein does not contain photoreactive amino acid residues, the irradiation-induced decrease of the phage antibody binding is determined, most probably, by the shielding of the antigenic determinants. Such shielding could be caused by rearrangement of coat protein molecules and/or of the capsid induced by photomodification of non-antigenic fragments of coat protein and/or of intraphage RNA.

The effect of some common inactivation procedures on the antigens of bovine herpesvirus 1.

Bovine embryonic kidney cells were infected with bovine herpesvirus 1 (BHV1) or were sham-inoculated. When cytopathic effect was apparent, the cells were treated with beta-propiolactone, formalin, heat (56 degrees C), or ultraviolet irradiation until the virus was inactivated. Infected-treated, infected-untreated (IU) and sham-inoculated cultures were solubilized using Triton X-100 detergent. Resulting preparations were tested by 2-dimensional- and fused rocket-immunoelectrophoresis and were evaluated for their ability to inhibit virus neutralization by BHV1 antiserum. Eleven viral antigens were detected consistently in IU preparations, which strongly inhibited virus neutralization. Eight or more IU antigens were detected in beta-propiolactone-treated, formalin-treated and heat-treated preparations; these inhibited virus neutralization less strongly than the IU preparations. No IU antigens were detected in ultraviolet-treated preparations, nor did this material inhibit virus neutralization. One of the IU antigens was reduced preferentially by all treatments. The selective destruction of antigens by the various treatments might allow antigen-specific serological testing to distinguish vaccinated from naturally-exposed cattle.

Induction of gp70-specific suppressor T-cells in mice inoculated with virus-producing tumor cells.

Inoculation of BALB/c mice with syngeneic, murine leukemia virus (MuLV)-producing (murine sarcoma virus-transformed) Balb/3T3 tumor cells resulted in diminution of alloreactivity as measured in the mixed leukocyte culture (MLC) reaction. Cells that suppressed this response were identified in the spleens of tumor-bearing mice 10--14 days after inoculation. The suppressor cells were adherent, radiosensitive T-lymphocytes of the Lyt 1-, 2, 3+ phenotype. Mice inoculated with Gross MuLV (G-MuLV)-producing tumor cells, but not those inoculated with a nonproducing subclone of the same tumor cells, developed suppressor T-cells. The T-cell-mediated suppression of the MLC could be augmented by the admixture of G-MuLV antigen, similar to that replicated by the tumor cell, but not by the admixture of a Rauscher-type MuLV antigen which lacked the cross-reactive, type-specific antigens of the G-MuLV. Furthermore, this augmented suppression could be abrogated by the addition of monoclonal anti-gp70 antibody. These findings indicated that antigen-specific suppressor T-cells were induced in response to leukemia virus antigen shed from and/or expressed on tumor cells and that the suppressive activity involved the specific recognition of the gp70 portion of the virus.

Psoralen inactivation of influenza and herpes simplex viruses and of virus-infected cells.

Psoralen compounds covalently bind to nucleic acids when irradiated with long-wavelength ultraviolet light. This treatment can destroy the infectivity of deoxyribonucleic acid and ribonucleic acid viruses. Two psoralen compounds, 4'-hydroxymethyltrioxsalen and 4'-aminomethyltrioxsalen, were used with long-wavelength ultraviolet light to inactivate cell-free herpes simplex and influenza viruses and to render virus-infected cells noninfectious. This method of inactivation was compared with germicidal (short-wavelength) ultraviolet light irradiation. The antigenicity of the treated, virus-infected, antigen-bearing cells was examined by immunofluorescence and radioimmunoassay and by measuring the capacity of the herpes simplex virus-infected cells to stimulate virus-specific lymphocyte proliferation. The infectivity of the virus-infected cells could be totally eliminated without altering their viral antigenicity. The use of psoralen plus long-wavelength ultraviolet light is well suited to the preparation of noninfectious virus antigens and virus antigen-bearing cells for immunological assays.