Reversal of virus-induced immune suppression

We studied the immunosuppressive capacity of splenic lymphocytes from rabbits at different stages of progressive myxosarcoma induced by malignant rabbit fibroma virus (MV). Spleen cells taken from rabbits 7 days after virus inoculation proliferate poorly in response to Con A, and suppress normal responses to the mitogen. Those from animals 11 days after virus injection have recovered partially from MV-induced suppression. Further, their Con A responses are no longer suppressed by day 7 spleen cells. Supernatants from cultures of spleen cells from rabbits given MV 7 days previously suppress both antibody-producing and proliferative responses to unrelated antigens. Comparable supernatants from rabbits receiving MV 11 days before sacrifice neither suppress nor augment such responses. Mixing cells from 7 or 11 day MV rabbits with normal spleen cells gives similar results. When supernatants from spleen cell of rabbits with tumors induced 7 and 11 days previously are mixed, the supernatants from rabbits with 11-day-old tumors inhibit the suppressive capacity of those from animals with 7-day-old tumors. Similarly, mixing spleen cells from rabbits given MV 7 and 11 days previously results in culture supernatants that do not suppress normal antibody and proliferative responses. The ability of cells from rabbits given MV 11 days before to inhibit the effects of cells from rabbits given MV 7 days previously does not involve the production of interferon. Thus, despite progressive tumor burden, immunologic recovery is observed in rabbits 11 days after tumor virus inoculation. One factor in this recovery may be the generation of active inhibitors of virus-induced immunosuppression. Similar mechanisms may apply to recovery of immunologic function in other virus infections as well.     

Immunologic dysfunction during viral oncogenesis: II. Inhibition of cellular immunity to viral antigens by malignant rabbit fibroma virus

The ability of two related viruses—Shope fibroma virus (SFV) and malignant rabbit fibroma virus (MV)—to induce virus-specific immune responses in lymphocytes of recipient animals was studied. SFV produces a benign local tumor which regresses in 12–14 days. Using an assay for virus-induced lymphocyte blastogenesis lymphocytes reactive to SFV were detected, both in rabbits bearing SFV-induced tumors and in rabbits whose SFV-induced tumor had regressed. These virus-reactive cells were detected in peripheral blood and spleen, and in lymph nodes draining the primary tumor. In contrast, MV produces a disseminated tumor and eventual death. MV does not induce detectable blastogenic responses in lymphocyte populations. SFV and MV are antigenically cross reactive: rabbits immune to SFV do not develop MV-induced tumors, and antisera to each virus neutralize both equally. Lymphocytes from SFV-infected rabbits proliferate in vitro in response to MV that has been inactivated by ultraviolet light (uv/MV) but not to infectious MV. In contrast, lymphocytes from rabbits infected with MV do not respond to uv-inactivated MV or to SFV. Thus, infectious MV inhibits the development of normal blastogenic responses in vivo and prevents the expression of those responses in lymphocytes from MV-resistant, SFV-immune rabbits in vitro. The relevance of this impairment to the differences in the clinical courses of SFV- and MV-induced tumors is discussed.     

Immunosuppression in viral oncogenesis. III. Effects of virus infection on interleukin 1 and interleukin 2 generation and responsiveness

Malignant rabbit fibroma virus (MV) is an oncogenic immunosuppressive leporipoxvirus. We studied the effects of MV infection and MV-associated tumor-induced suppressor factor (TISF) on the production of and responsiveness to interleukins 1 and 2. Adherent cells from MV tumor-bearing rabbits elaborate adequate amounts of IL 1 in response to E. coli endotoxin. Neither live virus nor TISF alters the production or the responsiveness to IL 1. However, when we examined spleen cells from rabbits 7 days after MV inoculation, we noted that their ability to produce and respond to IL 2 is deficient. Despite their relatively poor capacity to produce IL 2, these spleen cells express receptor for IL 2 in normal amounts, as measured by the monoclonal antibody 7D4. TISF derived from T lymphocytes from MV tumor-bearing rabbits is by itself capable of inhibiting partially normal secretion of IL 2 and also the response of the cloned murine T cell line HT-2 to added IL 2. Full expression of the immunosuppressive capacity of spleen cells from MV tumor-bearing rabbits requires cell-cell contact, however, and cannot be replaced by either live virus or spleen cell supernatants. Such spleen cells inhibit normal mitogen responsiveness, a defect not remedied by adding exogenous IL 2. Immunologic dysfunction induced by MV infection is transient, and by 11 days after virus inoculation, actively mediated recovery from immunosuppression is observed. We found that spleen cells from rabbits studied 11 days postinoculation secreted IL 2 normally. Thus, immunologic dysfunction secondary to infection with malignant rabbit fibroma virus reflects deficiencies in both elaboration of and response to IL 2, and return of immune function later in the course of the infection is associated with return of the ability of lymphocytes to secrete IL 2.     

Lymphocyte-virus interactions. Identification of a restriction fragment permitting virus replication in lymphocytes

We are interested in understanding the effects of virus infection on lymphocyte function. To approach this question, we used a unique system of two genetically related leporipoxviruses to generate recombinants. One of these viruses, malignant fibroma virus (MV), replicates in many different cell types, including lymphocytes. The other, Shope fibroma virus (SFV), replicates principally in fibroblasts, but cannot replicate in lymphocytes. Fibroblasts infected with SFV received restriction fragments from MV by transfection. Recombinant viruses were selected in vitro for their ability to replicate in lymphocytes. By these means we have identified one restriction fragment, the 10.8-kb BamHI "C" fragment, capable of transferring from MV to SFV the ability to replicate in lymphocytes. A family of recombinants bearing different sized inserts of this restriction fragment has been isolated and is being characterized. Lymphocytotropic recombinants bearing portions of this restriction fragment produce colony morphology in vitro intermediate between MV's plaques and SFV's foci. On the basis of their ability to grow in and suppress mitogen responsiveness of lymphocytes, these recombinants may be classified into four different groups. Group 1 viruses are the most immunosuppressive, whereas those of group 4 are least. These traits correlate with ability to replicate in lymphocytes. Genetic analysis of recombinants indicates that the most immunosuppressive recombinants do not necessarily contain the most fragment C DNA. Therefore, we have identified a restriction fragment, one or more of the genes of which are sufficient to allow an otherwise nonlymphocytotropic virus to replicate in lymphocytes. Additional genetic and immunologic analysis should permit us to determine the structure and function of the protein responsible for this effect.     

Molecular analysis of immunosuppression induced by virus replication in lymphocytes

The relationship between immunosuppression and oncogenesis can be determined by studying the molecular interactions between tumor-inducing viruses and lymphocytes. We approached this study by using a unique system of two genetically related Leporipoxviruses, malignant fibroma virus (MV), and Shope fibroma virus (SFV). MV induces a syndrome of a highly lethal, disseminated myxosarcoma, severe immune suppression, and replicates in lymphocytes both in vivo and in vitro. In contrast, SFV causes a benign fibromyxosarcoma without immune dysfunction and cannot replicate in lymphocytes. Earlier studies demonstrated that transfer of a 10.8-kb Bam HI piece of MV (fragment "C") to SFV resulted in the ability of SFV to replicate in lymphocytes and suppress immune function. These results suggested that lymphocytotropic replication and immune suppression was located on the left side of fragment C. We extended these studies by generating families of recombinants between MV and SFV by using subfragments of fragment C. The resulting recombinant viruses were analyzed for their ability to replicate in lymphocytes, suppress immune function, and produce tumors. Those recombinants expressing MV-like characteristics were mapped by endonuclease digestion. This study demonstrates that recombinants containing a 3.6-kb Nde I subfragment, as well as those containing an overlapping 1.9-kb Hinc II subfragment, were capable of replicating in lymphocytes, suppressing immune functions, and inducing disseminated tumors in rabbits. Our study has therefore identified a portion of MV DNA sufficient to transfer the unique pathogenicity of MV to SFV, and suggests that control of immune suppression and tumor dissemination may not necessarily be mediated by the same viral genes.     

Immunosuppression during viral oncogenesis. IV. Generation of soluble virus-induced immunologic suppressor molecules

We describe herein functional attributes and generation of immunologic suppressor activity elaborated in response to oncogenic virus infection. Malignant rabbit fibroma virus-induced immunologic suppressor factor (VISF) is a T cell product produced in peak quantities by spleen cells taken from infected rabbits 7 days after infection in vivo. Its production does not appear to require macrophage participation. VISF is highly labile, 3.5 to 12 kDa, and capable of suppressing both B and T lymphocytic responses. Indomethacin and the cyclic nucleotides cAMP and cGMP inhibit its generation. VISF activity is neither antigen nor species specific. It suppresses murine and leporine immune responses to antigens unrelated to the inducing virus. Comparable suppressor activity may be induced by infecting an apparently non-functional rabbit T lymphoma line, RL-5, with malignant rabbit fibroma virus. VISF is principally a suppressor-inducer factor: in vitro, lymphocytes exposed to VISF do not show decreased immunologic responsiveness until 4 days of culture. VISF induces T suppressor cell activity when normal spleen cells are exposed briefly to VISF. Thus, immunosuppressive consequences of malignant fibroma virus infection are partially mediated by a small, non-specific T cell-derived suppressor lymphokine with unique functional characteristics. Non-specific immunologic dysfunction that often attends virus infections may reflect the activity of such factors in humans as well.     

Immunosuppression during viral oncogenesis. V. Resistance to virus-induced immunosuppressive factor

Rabbits given malignant rabbit fibroma virus (MV) develop severe immunologic dysfunction during the course of infection. Splenic T lymphocytes from these rabbits elaborate a soluble non-specific immunosuppressive factor (virus-induced suppressor factor (VISF]. As malignant rabbit fibroma virus infection progresses, normal immunologic responsiveness returns. This recovery is multi-factorial and involves production by T lymphocytes of a soluble factor capable of antagonizing the activity of VISF. This soluble anti-suppressor factor (ASF) is not a generalized immunologic potentiator. Its sole apparent effect on immune function appears to be to antagonize the activity of VISF. The protective effects of ASF are evident only when suppressor factors and ASF are simultaneously present in culture. Pre-treatment of target cells with ASF-containing culture supernatants does not render them insensitive to the immunosuppressive effects of subsequent treatment with VISF. In addition, ASF appears to be directly responsible for antagonizing VISF activity. That is, ASF does not appear to initiate an anti-suppressive cascade by activating a population of cells that in turn generate secondary protective factors. ASF-producing cells do not bind Vicia villosa lectin, as do contra-suppressor cells described by others. In almost all of these features, the system we describe herein differs from systems in which other investigators have described factors that antagonize the effects of suppressor factors.     

A differential effect of IgM and IgG antibodies on the blastogenic response of lymphocytes to rubella virus

Peripheral blood lymphocytes of rabbits immunized with live rubella vaccine respond to rubella virus antigens in tissue culture with increased DNA synthesis as measured by incorporation of ³H-thymidine. This reaction can be inhibited by rubella antibody. A dose dependent effect was observed when antibodies in whole serum were mixed with virus prior to addition to lymphocyte cultures. When antisera were fractionated and their individual immunoglobulins tested, a paradoxical effect was obtained. Immune IgG although it was highly effective in neutralizing the virus was incapable of inhibiting the lymphocyte response and at times caused an increased response. In contrast, immune IgM which was less efficient in neutralizing virus caused significant suppression of the blastogenic reaction. By themselves these results might have signified that IgG and IgM antibodies have different specificities or different binding properties with respect to viral surface antigens. However, immune complexes consisting of virus and IgM reduced response of both rubella immune and normal rabbit lymphocytes to PHA. This nonspecific inhibitory action required a specific step of antigen and IgM antibody interaction and normal IgM-virus mixtures or mixtures of anti-rubella IgM and poliovirus or influenza virus did not suppress lymphocyte response to PHA. Anti-rubella IgG complexed with rubella virus did not suppress the PHA response. The IgG function was apparently limited to neutralization of the infectivity of rubella virus whereas the major role of IgM was manifested through its suppressive effect on lymphocyte reactions.     

Inhibition of T cell-mediated functions by MVM(i), a parvovirus closely related to minute virus of mice

A purified preparation of MVM(i), a murine parvovirus closely related to minute virus of mice (MVM), was found to inhibit various functions mediated by murine T cells in vitro. Addition of MVM(i) virus to secondary allogeneic mixed leukocyte cultures resulted in the inhibition of both lymphocyte proliferation (3H-thymidine incorporation) and the generation of cytolytic T lymphocyte activity but not interferon production. MVM(i) virus also inhibited the growth and cytolytic activity of several cloned, long-term Lyt-2+ cytolytic T cell lines. Furthermore, the antigen-induced proliferative responses of parasite- (Leishmania) specific Lyt-1+ T cells in vitro was abrogated by the addition of MVM(i) virus to the culture. Finally, the suppression of an in vitro antibody response to SRBC by MVM(i) virus was the result of the inhibition of T helper cells required for the B cell response. These suppressive effects were specific for MVM(i); parallel studies in which the prototype MVM parvovirus was used showed no significant inhibition in the various systems tested.     

Immunosuppression of experimental allergic encephalomyelitis. III. In vitro evidence for induction of suppressor T lymphocytes in draining lymph node cells of animals immunized with myelin basic protein complexed to lipopolysaccharides

We recently demonstrated that Lewis rats immunized with bacterial lipopolysaccharides (LPS) precomplexed to guinea pig myelin basic protein (BP) in complete Freund's adjuvant were less effective in inducing experimental allergic encephalomyelitis (EAE) than BP-immunized controls. When tested in vitro both lymph node cells (LNC) and spleen cells (SpC) of animals immunized with BP-LPS were less effective in proliferative responses to various mitogens, which included phytohemagglutinin, concanavalin A, purified protein derivative of tuberculin, LPS, and BP. Of importance immunization of rats with BP complexed to LPS results in the generation of cells in lymph nodes of these animals that suppress the mitogenic response of BP-immunized LNC and also SpC in mixed lymphocyte cultures. The suppressive effect of these cells in mixed lymphocyte culture reaction was found specifically in response to BP and to a lesser extent to LPS in LNC. SpC of BP-LPS immunized animals did not suppress the proliferative response to SpC of BP-immunized animals. Treatment of these LNC with antithymocyte serum and complement abolished this suppressive effect of LNC, suggesting that the immunoregulatory cells in LNC of BP-LPS immunized animals are suppressor T lymphocytes. The parallel between the in vitro induction of suppressor T lymphocytes in the draining LNC and the function of LPS in the development of EAE in Lewis rats suggests a possible immunologic significance of the effect.     

Antibodies against cortisol block suppressive effects of corticosteroids on lymphocytes in vitro.

Lymphocyte transformation assays were used to test the ability of antibodies against cortisol to reduce bioactivity of corticosteroids in vitro. Mononuclear cells were separated from whole bovine blood and cultured in the presence of PHA alone, PHA + steroid, PHA + steroid + anticortisol, or PHA + steroid + anti-bovine serum albumin. Tritiated thymidine uptake was determined for all groups during the last 24 hr of a 72-hr culture period by scintillation counting. Polyclonal anticortisol against cortisol-bovine serum albumin conjugated in the 21 position was more effective in blocking cortisol activity than monoclonal anticortisol built against conjugates in the 3 position. The steroids that suppressed PHA-induced lymphocyte proliferation in a concentration-dependent manner were: cortisol, corticosterone, dexamethasone, prednisolone, 11-deoxycortisol, and 11-deoxycorticosterone. Aldosterone, cortisone, cholesterol, estradiol, and progesterone did not exhibit concentration-dependent effects and, thus, were not considered suppressive. These concentration-independent steroids were also the least suppressive (with the exception of aldosterone). Anticortisol was able to reduce bioactivity of suppressive corticosteroids that had an 11-hydroxy group, suggesting the antibody was primarily made against this site. Anti-BSA was not effective in blocking corticosteroid activity, but it did enhance proliferation of lymphocytes if added in combination with weakly suppressive steroids. Anticortisol also had an enhancing effect when added with some weakly suppressive steroids. We conclude that antibodies against cortisol are capable of reducing bioactivity of steroids that strongly suppress lymphocyte proliferation. Additionally, the 11-hydroxy group may be an important antigenic determinant of steroid molecules.     

Macrophage-mediated suppression of immune responses in Toxoplasma-infected mice. I. Inhibition of proliferation of lymphocytes in primary antibody responses

The suppressor cells induced by Toxoplasma infection were shown to be macrophages, since they adhered to plastic, and their suppressive activity in anti-sheep erythrocytes (SRBC) antibody responses was abrogated by treatment with silica or carrageenan, which are selectively cytotoxic for macrophages. The suppressor macrophages strongly inhibited the uptake of tritiated thymidine ( [3H]TdR) by normal mouse spleen cells in the responses to SRBC and Toxoplasma antigens. Supernatant fluids from the suppressor macrophages could not passively transfer the suppressive effect on anti-SRBC antibody responses. Furthermore, when the suppressor macrophages were isolated by a cell-impermeable membrane from normal mouse spleen cells, the antibody responses of normal spleen cells were not suppressed. These results indicate that suppression of antibody responses in Toxoplasma-infected mice is caused by an inhibitory effect of the suppressor macrophages upon proliferation of lymphocytes via direct contact with responder target cells. The suppressive effect of the macrophages was not counteracted by indomethacin, a potent inhibitor of prostaglandin synthesis, or catalase, a catabolic enzyme for hydrogen peroxide (H2O2).     

Biological expressions of lymphocyte activation. IV. Concanavalin A-activated suppressor cells in mouse mixed lymphocyte reactions.

Thymus-derived lymphocytes (T cells) from mouse spleen, activated in vitro or in vivo with concanavalin A (Con A), suppress proliferative responses of syngenic lymphocytes in mixed lymphocyte reactions (MLR). Replication in vitro was not required for expression of suppressor activity by Con A-activated cells and was blocked in MLR by treating suppressor cells with mitomycin C or irradiation. Kinetics of MLR responses and viability of cultures were not altered by addition of activated suppressor cells. The data are consistent with a direct inhibitory effect of suppressor T cells on antigen-induced DNA replication. These observations extend a model previously described for regulation of antibody synthesis by Con A-activated T cells to control of cell-mediated immune responses. This model should be particularly useful in further definition of regulatory T cell subpopulations, and in investigation of interactions and relationships between such populations.     

In vitro proliferation of rabbit bone marrow-derived and thymus-derived lymphocytes in response to vaccinia virus

Peripheral blood leukocytes from rabbits immunized with vaccinia virus were incubated in vitro with vaccinia antigen, and resultant lymphocyte proliferation was measured by incorporation of tritiated thymidine into acid-insoluble material. Significant lymphocyte stimulation was observed at a time when antiviral antibody was being synthesized in vivo. The extent of proliferation by bone marrow-derived lymphocytes after culture with viral antigen was determined by simultaneous detection of complement receptor lymphocytes (CRLs have been shown to be B cells) and uptake of tritiated thymidine in these CRLs by radioautography. The results indicate that both bone marrow-derived and thymus-derived lymphocytes participate in the in vitro proliferative response of rabbit peripheral blood lymphocytes to vaccinia antigen.     

Suppression of antibody responses in allogeneic mice by products of lymphoid tissue. I. Allogeneic suppressive factor (ASF) from spleens repopulated with thymus cells.

A cellfree extract prepared from the spleen cells of C3H mice is capable of suppressing antibody responses to SRBC when extract material is exposed to alloantigens. The observed immunosuppression was attributed to a soluble factor in the extract. This allogeneic suppressive factor (ASF) was detected in extracts prepared from the spleen cells of unirradiated mice as well as those of irradiated mice repopulated with thymocytes, provided that mice were previously immunized with SRBC. Donors of actively suppressive ASF preparations did not need to be previously exposed to alloantigens. Extracts from thymus and marrow cells of unirradiated mice and the spleen cells of irradiated mice repopulated with marrow cells (or no cells) did not contain ASF. C3H thymocytes stimulated with SRBC generated more ASF activity in spleens of C3BF1 hosts than in those of C3H hosts, indicating that alloantigenic stimulation enhances the production or activity of ASF. Once produced, C3H ASF was able to suppress antibody responses in cell transfer experiments only if exposed to C3BF alloantigens of either donor lymphoid cells or irradiated hosts. Once exposed to alloantigens, ASF appears to be capable of suppressing antibody responses of syngeneic C3H or semi-allogeneic C3BF cells. When both donor lymphoid cells and hosts were syngeneic with the donor of the ASF, there was enhancement of antibody formation in cell transfer experiments. C3H ASF did not interfere with education of C3BF thymocytes to SRBC or with the generation of precursors of anti-SRBC antibody-forming cells by C3BF1 marrow cells. ASF may interfere with cellular cooperative events necessary for humoral immune responses or with terminal differentiation of B cells. Production of ASF could partially account for the suppression of antibody responses observed during graft-vs-host reactions.     

Complement reversal of immunosuppression induced with plasma of rats infected with Trypanosoma brucei rhodesiense

Suppression of antibody production by splenic lymphocytes from rats immunized with sheep red blood cells (SRBC) after incubation with plasma from rats infected with Trypanosoma brucei rhodesiense was confirmed. Suppressive activity became evident in plasma after the sixth day of infection and was manifested by reduction in the number of hemolytic Jerne plaques produced by the treated cells. The activity was temporally associated with increased amounts of soluble immune complex (SIC) reduced titers of lytic complement, elevated titers of immunoconglutinin (IK) and anemia. Treatment of suppressive plasma with hemolysin sensitized SRBC alexinated with horse complement to reduce IK did not reduce suppressive activity, and the activity appeared to have been enhanced when the plasma was heated to inactivate the remaining complement (C'). When fresh rat C' was added to the treated cells, the suppression was largely, though not completely, reversed. Treatment of spleen cells with SIC prepared in vitro from bovine serum albumin (BSA) and rabbit antiBSA also suppressed the plaque forming capacity of the cells. Complexes of BSA-antiBSA-C' and complexes of BSA-antiBSA-C'-IK were equally suppressive. Again, addition of fresh C' to cells treated with these complexes largely, though not completely, reversed the suppressive effect on the cells. From the results it is suggested that immunosuppression associated with experimental T. b. rhodesiense infection may be in part a suppression of the capacity of induced lymphocytes to produce antibody. It is possible that the suppression was mediated by SIC present in the plasma of the infected rats and this effect was probably enhanced by reduced levels of complement in the suppressive plasma.     

Spontaneous cytotoxicity of human peripheral blood mononuclear cells toward red blood cell targets. II. Time-dependent loss of suppressor cell activity.

In a previous paper we demonstrated that human peripheral blood mononuclear cells become strikingly cytotoxic toward a wide variety of red blood cell targets after 7 days of in vitro culture. The cell responsible for cytotoxicity does not rosette with SRBC and demonstrates both surface adherence and phagocytic properties. In this paper we wish to show that development of spontaneous cytotoxicity is due to a time-dependent loss of suppressor cell function. Fresh autologous lymphocytes, when added to cultured cells, abrogate the subsequent expression of spontaneous cytotoxicity toward RBC targets. The suppressor cell is radioresistant; requires 24 hr to suppress optimally; is inactivated by heating at 56 degrees C for 15 min, and is enriched in the non-T interface after SRBC rosette depletion over a discontinuous Ficoll-Hypaque gradient. Furthermore, the addition of a cell-free sonicate of fresh lymphocytes is capable of inhibiting spontaneous cytotoxicity toward RBC targets. However, if mononuclear cells are allowed to incubate in tissue culture medium for 7 days they are no longer suppressive after sonication. These data suggest that fresh mononuclear cells exert a potent negative regulatory influence on monocyte killing. Our culture conditions by removing this negative influence have produced a new model of spontaneous nonspecific killing by monocytes.     

An endotoxin induced serum factor that causes enhancement of antibody response to heterologous erythrocytes.

The sera obtained from blood of the mice, which had been intravenously injected with LPS several hours in advance, contained some active substance capable of enhancing anti-sheep red blood cell (SRBC) antibody responses in mice. Activity of the sera was still retained after passage through a rabbit anti-LPS antibody-coated Sepharose 4B column, but greatly reduced by passage through a rabbit anti-mouse thymocyte antibody-coated Sepharose 4B column. The active substance in the sera was eluted through a Sephadex G-200 column at the same position as the serum albumin. The addition of this substance to B cell rich spleen cell cultures in vitro in the presence of SRBC generated tremendous numbers of antibody forming cells 4 days after the incubation, suggesting that this substance was able to take over the helper function of T cells in thymus dependent antibody responses. However, this substance was not capable of stimulating 3H-thymidine-uptake into cultured spleen cells. The possible role of this substance in the adjuvant effect of LPS is discussed.     

Interaction of reovirus with cell surface receptors. II. Generation of suppressor T cells by the hemagglutinin of reovirus type 3

In studying reovirus interactions with lymphocytes, we have found that reovirus type 3, but not type 1, inhibits the in vitro proliferative response of murine splenic lymphocytes to concanavalin A (Con A). By analyzing recombinant clones containing genes from both reovirus types 1 and 3, we found that the S1 gene, the gene that encodes the viral hemagglutinin, is responsible for the inhibitory effect. In addition we found that type 3, but not type 1, generates suppressor T cells in vitro capable of suppressing Con A proliferation. By analyzing recombinant clones, we also found that the viral hemagglutinin is responsible for the generation of suppressor T cells by reovirus type 3. These effects were observed whether UV-inactivated or live virus was used. Reovirus type 3 inhibition of the proliferative response of murine splenic lymphocytes to Con A was blocked by anti-reovirus type 3 antibody but not by anti-reovirus type 1 antibody. Antiviral antibody had no effect on the ability of reovirus type 3 induced suppressor cells to inhibit Con A proliferation. We have previously demonstrated a receptor on murine lymphocytes for the hemagglutinin of reovirus type 3, and our results suggest that the in vitro suppression of Con A proliferation of murine lymphocytes by reovirus type 3 is secondary to the interaction of the viral hemagglutinin with a receptor on the surface of murine lymphocytes, which results in the generation of functionally active suppressor T cells.     

体外诱导绵羊红细胞特异性抗体形成及单纯疱疹病毒感染对它的影响

本文建立了一种较稳定、理想的人淋巴细胞体外诱导绵羊红细胞(SRBC)特异性抗体生成的系统。用SRBC体外刺激人扁桃体淋巴细胞,用溶血空斑法计数针对SRBC特异性抗体形成细胞。发现极低量抗原可诱导其抗体形成,抗体形成量随抗原量呈规律性变化;在抗原刺激后的第4天特异性抗体开始出现,第6天达高峰,并稳定维持至第8天;在辅助刺激剂美洲商陆(PWM)存在下,抗体形成量显著高于无PWM的情况;除去人扁桃体细胞中粘附细胞(主要是巨噬细胞)才能诱导最适抗体形成。将具感染性的HSV-1与SRBC一起加入淋巴细胞培养中,可显著抑制SRBC诱导的特异性抗体形成,这一抑制效应与病毒的感染量有关。此系统中同时加入α-干扰素则可部分解除病毒的抑制效应,并且解除效果与α-干扰素的剂量有关。