Depression of mitogen response in spleen cells from reticuloendotheliosis virus-infected chickens and their suppressive effect on normal lymphocyte response

Spleen cells and peripheral blood lymphocytes from chickens infected with reticuloendotheliosis virus (REV) were depressed in their responsiveness to phytohemagglutinin (PHA). When spleen cells from uninfected chickens were co-cultured with spleen cells from chickens infected with REV at 2 weeks of age, the PHA response by the normal cells was completely suppressed. Although spleen cells from chickens infected with REV at 6 or 9 weeks of age were also suppressed in their ability to respond to PHA, they did not suppress the mitogenic response of normal cells in mixed cultures.     

Suppression of Con A mitogen-induced proliferation of normal spleen cells by macrophages from chickens with hereditary muscular dystrophy

Spleen cells from chickens with hereditary muscular dystrophy (MD) give low blastogenic responses to the T cell mitogen concanavalin A (Con A) while exhibiting normal mitogen stimulated blastogenic responses to the T cell mitogen phytohemagglutinin (PHA). The addition of MD spleen cells to normal spleen cells caused a marked suppression of the Con A response of the normal cells while not affecting the PHA response of the normal cells. The suppressive activity by the MD spleen cells requires viable cells and is contact mediated. The suppressive activity is attributed to the presence in MD spleens of a population of suppressor cells with characteristics typical of macrophages. The suppressor cell activity was not removable by complement-mediated lysis using anti-T or anti-B sera, but it was reversible by treatment with carrageenan or carbonyl iron magnet, by passage through a Sephadex G-10 column, and by adherence to plastic petri dishes or glass beads. MD spleen cells depleted of the suppressor cell population remained unable to respond to Con A.     

The suppressive effect of immunization on the proliferative responses of rat T cells in vitro. II. Abrogation of antigen-induced suppression by selective cytotoxic agents.

Rats given large i.v. doses of ovalbumin or sheep erythrocytes manifest suppressed spleen cell responses (3H-thymidine incorporation) to PHA within hours. Removal of glass wool-adherent cells totally restores responsiveness to that of normal nonadherent spleen cell cultures. Carrageenan, selectively toxic for macrophages, partially restores responses of antigen-suppressed spleen cells in culture, suggesting a supportive role for macrophages in the suppression phenomenon. Treatment of donors with low doses of cyclophosphamide (20 to 50 mg/kg) at the time of antigen injection abrogates the ability of their spleen cells to suppress the responses of normal cells to PHA. The low dose of cyclophosphamide required indicates a target other than the B cell or macrophage and suggests the possibility that cyclophosphamide eliminates the suppressor T cell component of the macrophage-T cell complex.     

Suppression of mitogen-induced proliferation of normal spleen cells by macrophages from chickens inoculated with Marek's disease virus

Spleen cells from chickens 7 days after inoculation with Marek's disease virus (MDV) responded poorly to stimulation by phytohemagglutinin (PHA). Addition of these cells to syngeneic normal spleen cells caused of marked suppression of the PHA response of the normal cells. The MDV spleen cells also inhibited the DNA synthesis of MSB-1 lymphoblastoid cells in vitro. The suppressive activity is attributed to the presence in MDV spleen cells of a population of suppressor cells with characteristics typical of macrophages. The suppressor cell activity was not removable by treatment with anti-T or anti-B serum with C, but it was reversible by treatment with carrageenan or carbonyl iron/magnet, by passage through glass wool column, and by adherence to plastic Petri dishes. The adherent MDV spleen cells also showed strong suppressor cell activity against syngeneic normal spleen cells.     

MHC-restricted cytotoxic response of chicken T cells: expression, augmentation, and clonal characterization

Major histocompatibility complex (MHC)-restricted cytotoxicity of chicken lymphocytes was studied by using three reticuloendotheliosis virus (REV)-transformed cell lines as targets in 51Cr-release assays. The cell lines, designated RECC-UG5, RECC-UG6, and RECC-UG8, were developed from bone marrow cells of REV-infected line G-B1, line G-B2, and (G-B1 X G-B2)F1 chickens respectively. Effector cells were obtained from spleens of G-B1, G-B2, F1, and F2 chickens 7 days after inoculation of REV. The inbred G-B1 (MHC genotype B13/B13) and G-B2 (MHC genotype B6/B6) lines originate from a common partially inbred line. Initial studies with effector cells from G-B1 and G-B2 chickens showed that significant cytotoxicity occurred only with syngeneic target cells. The degree of cytotoxicity was markedly enhanced by neonatally treating effector cell donors with cyclophosphamide (CY) and delaying virus challenge until the birds were 4 wk old. Augmentation of cytotoxicity was presumed to be due to elimination of bursal-dependent suppressor T cells by CY. The results with spleen cells from REV-inoculated F2 birds clearly showed that cytotoxicity was MHC restricted; i.e., significant lysis only occurred if effector cells and target cells had a common B system antigen. Lysis of RECC-UG5 targets was three to four times higher than lysis of RECC-UG6 targets when effector cells were from heterozygous (B6/B13)F1 and F2 birds. Because these two target cell lines generally showed a similar degree of lysis by effector cells from syngeneic B homozygous birds, the differences obtained with effector cells from B heterozygous birds was most likely due to differences in the number of effector cells with specificity for each target line. Evidence for an additive cytotoxic effect, considered to be due to the lytic activity of two separate T cell clones, was obtained when F1 effector cells were tested with the F1-derived RECC-UG8 targets. The results of other experiments indicated that the effector cells were of T cell lineage and that their activity was probably directed against virus-induced antigens on the transformed target cells.     

Infection with Eimeria tenella: modulation of lymphocyte blastogenesis by specific antigen, and evidence for immunodepression

The blastogenic effects of specific parasite antigen and of mitogens on the lymphocytes of chickens infected with Eimeria tenella were examined. Lymphocytes from infected chickens were stimulated to divide when cultured with parasite antigen, but their responses to the T-cell mitogen, phytohemagglutinin (PHA), were depressed throughout the period of infection. Responses to the B-cell mitogen, lipopolysaccharide (LPS), were depressed during the first week of infection but enhanced in the second week. The inclusion of plasma samples from infected chickens in the culture medium depressed the responses of normal spleen lymphocytes to PHA, suggesting that soluble suppressor factors are generated during infection.     

网状内皮增生病病毒感染SPF鸡对疫苗免疫反应的抑制作用

我国鸡群中网状内皮增生病病毒(REV)感染已相当普遍,但对其造成的实际危害却不太清楚。本研究结果表明,1日龄SPF鸡感染REV会显著抑制对新城疫病毒(NDV)和禽流感病毒(AIV,H5和H9)疫苗的免疫反应。1周龄用相应灭活疫苗免疫后3周、4周和5周,REV感染组对不同病毒疫苗免疫后的HI效价显著低于对照组。高剂量REV感染组的抑制作用大于低剂量感染组,但统计学差异不显著。REV感染可造成中枢免疫器官萎缩,REV感染组的胸腺、法氏囊与体重比显著低于对照组。本研究证明了,REV早期感染会干扰鸡群对NDV、AIV的免疫效果,特别是会严重干扰对AIV疫苗的免疫效果。     

Infection with Eimeria tenella: Modulation of Lymphocyte Blastogenesis by Specific Antigen,and Evidence for Immunodepression1

ABSTRACT. The blastogenic effects of specific parasite antigen and of mitogens on the lymphocytes of chickens infected with Eimeria tenella were examined. Lymphocytes from infected chickens were stimulated to divide when cultured with parasite antigen, but their responses to the T-cell mitogen, phytohemagglutinin (PHA), were depressed throughout the period of infection. Responses to the B-cell mitogen, lipopolysaccharide (LPS), were depressed during the first week of infection but enhanced in the second week. The inclusion of plasma samples from infected chickens in the culture medium depressed the responses of normal spleen lymphocytes to PHA, suggesting that soluble suppressor factors are generated during infection.     

Transfer of agammaglobulinemia in the chicken. I. Generation of suppressor activity by injection of bursa cells

Spleen cells from adult agammaglobulinemic (bursectomized) chickens taken 1 to 3 weeks after an injection of histocompatible bursa cells can inhibit the adoptive antibody response to B. abortus of normal spleen or bursa cells in irradiated recipients. Spleen cells from Aγ chickens not injected with bursa cells generally do not. Moreover, bursectomized chickens which have been reconstituted with spleen cells within the first week after hatching do not respond with suppressor cell formation upon bursa cell injection. This apparent “autoimmunization” with bursa cells induces suppressor T cells which are only minimally sensitive to treatment with mitomycin C or to 5000 R γ irradiation. The suppressor activity is neither induced nor potentiated by concanavalin A in vivo. It is much stronger in spleen than in thymus cells and appears to be macrophage independent and to require intact cells. The cell component which stimulates the suppressor activity is more pronounced on bursa than on spleen cells, and is at most present to a very limited extent on bone marrow, thymus, or peritoneal exudate cells. It is better represented in comparable cell numbers of Day 17 than of Day 14 embryonic bursa. The inducing cell component is present in the membrane fraction of disrupted bursa cells. Immunization with bursa cells from B locus histoincompatible chickens leads to suppressor activity against histocompatible bursa cells. Although the removal of Ig-bearing cells from bursa greatly diminishes its immunizing capacity, injection of serum IgM and IgG does not induce suppressor cells. It is suggested that tolerance to a B-cell antigen is lacking in adult Aγ chickens, resulting in an autoimmune response upon exposure to B cells. The B-cell antigen may be a cell surface-specific form of Ig, a complex of Ig and a membrane component, or a differentiation antigen which appears simultaneously with Ig during ontogeny.     

Characterization of the interaction of reticuloendotheliosis virus with the avian lymphoid system.

Splenic lymphocytes from chickens infected with reticuloendotheliosis virus (REV) are cytostatically impaired in their ability to undergo mitogen-induced blastogenesis ([³H]TdR uptake and proliferation), but are fully capable of eliciting cytotoxic reactions against allogeneic, ⁵¹Chromium-labeled chicken erythrocytes. Spleen cells from birds with reticuloendotheliosis (RE_s) are able to suppress DNA synthesis of normal splenic lymphocytes (N_s), but are unable to inhibit ¹[³H]TdR uptake by chick embryo fibroblasts. The suppression of the N_s mitogenic response is not restricted by major histocompatibility (B-locus) differences between populations of RE_s suppressor and N_s target cells. Moreover, infection of birds with an attenuated form of REV, which replicates in the host but does not cause tumorigenesis, also leads to suppression of phytohemagglutinin-induced, [³H]TdR uptake by host lymphocytes. These results are discussed in terms of the interaction between viral-infected/transformed cells and host defense mechanisms.     

Freezing of rat lymphocytes. I. The effects of dimethyl sulfoxide and freezing on the phytohemagglutinin- and pokeweed mitogen-responding lymphocyte subpopulations.

Rat spleen and lymph node lymphocytes have been frozen with dimethyl sulfoxide (DMSO) at 1 °C/min and stored at ?196 °C for 10 min. The functional recovery of the cell populations was monitored by the mitogenic response (uptake of [³H]thymidine) to phytohemagglutinin (PHA) or pokeweed mitogen (PWM) in culture after thawing. With 5 to 10% DMSO in the freezing medium, frozen-thawed lymph node cells were found to retain about 40% of their response to PHA. In contrast, frozen-thawed spleen cells responded better to PHA than fresh cells. The response to PWM was markedly decreased in both spleen and lymph node cell cultures.A similar effect was observed when DMSO was added to the culture medium of fresh spleen cells, i.e., an augmentation of the response to PHA and a suppression of the response to PWM. However, the concentrations of DMSO needed to induce this effect was more than 10-fold higher than that present in the culture medium after freezing and thawing.Since removal of adherent cells from the spleen cell population also produced an augmentation of the response to PHA, it is suggested that the freezing procedure and DMSO may have an inhibitory effect on suppressor cell functions present in spleen cell populations.     

Effects of lymphocytes from Marek's disease-infected chickens on mitogen responses of syngeneic normal chicken spleen cells.

PHA responses have been measured in lymphoid cell cultures prepared by mixing normal chicken spleen cells with spleen or thymus cells from syngeneic chickens infected with the oncogenic herpesvirus MDV. Results of these studies may be summarized as follows: 1) spleen cells from MDV-infected chickens with visceral lymphomas inhibit the PHA response of normal spleen cells possibly by release of soluble inhibitory factors in response to the mitogen; 2) lymphoid cells from asymptomatic MDV-infected chickens, although hyporeactive themselves to PHA, can have a stimulatory effect on PHA responses of normal spleen cells in mixed cultures; 3) spleen cells from MDV-infected chickens, effectively protected from viral oncogenesis by HVT vaccination, show normal reactivity to PHA in spearate cultures and may react in mixed cultures like normal lymphocytes, with neither a pronounced stimulatory nor inhibitory effect on the PHA response of normal spleen cells.     

Splenic suppressor macrophages induced in mice by injection of Corynebacterium parvum.

Spleen cells from C57BL/6N mice injected with killed Corynebacterium parvum (CP) had a marked growth inhibitory effect on the in vitro proliferation of RBL-5 murine lymphoma cells. It was most marked 12 to 14 days after injection and was usually no longer detectable later than 21 days. It could be demonstrated at effector cell to target ratios between 20:1 and 5:1 at which normal spleen cells had a growth-promoting effect. Addition of CP to an in vitro mixture of spleen cells and tumor cells augmented the inhibitory effect of spleen cells from CP-injected mice although it conferred no inhibitory potential on normal spleen cells. Growth inhibiton by CP spleen cells was not mediated by T cells and various depletion experiments suggested that the effector cells of the phenomenon were macrophages. Spleen cells of CP-injected mice also showed strongly depressed responses to the T cell mitogens PHA and Con A and suppressed the mitogen responses of syngeneic normal spleen cells. The characteristics of the suppressor cells mediating this effect appeared to be very similar to those inhibiting lymphoma cell growth. The responses to LPS were also strongly suppressed in mice injected with 2.1 mg of CP. However, after injection of one-tenth of the dose a relative sparing of the LPS response was noted, whereas the PHA response was still suppressed.     

Fowlpox virus recombinants expressing the envelope glycoprotein of an avian reticuloendotheliosis retrovirus induce neutralizing antibodies and reduce viremia in chickens.

Eight stable fowlpox virus (FPV) recombinants which express the envelope glycoprotein of the spleen necrosis virus (SNV) strain of reticuloendotheliosis virus (REV), an avian retrovirus, were constructed. These recombinants differ in the genomic location of the inserted genes, in the orientation of the insert relative to flanking viral sequences, and in the promoter used to drive expression of the env gene. Of these variables, promoter strength seems to be the most crucial. The P7.5 promoter of vaccinia virus, which is commonly used in the construction of both vaccinia virus and FPV recombinants, resulted in lower levels of expression of the envelope antigen in infected chicken cells compared with a strong synthetic promoter, as determined by immunofluorescence and enzyme-linked immunosorbent assay. Two peptides encoded by the env gene, the 21-kDa transmembrane peptide and a 62-kDa precursor, were detected by immunoprecipitation of labeled proteins from cells infected with recombinant FPVs, using monoclonal antibodies against REV. These peptides comigrated with those precipitated from REV-infected cells. One of the recombinants (f29R-SNenv) was used for vaccination of 1-day-old chickens. Vaccinated chicks developed neutralizing antibodies to SNV more rapidly than did unvaccinated controls following SNV challenge and were protected against both viremia and the SNV-induced runting syndrome.     

The presence of immunoregulatory cells in chicken thymus: function in B and T cell responses.

The presence of immunoregulatory cells in chicken thymus was studied by using several different systems. Chickens injected with large numbers of syngeneic thymocytes were tested for their ability to produce antibody to heterologous red cells. Similar chickens were studied for their ability to reject allogeneic skin grafts. In separate studies, mixtures of thymocytes with spleen cells or with peripheral blood leukocytes were assayed for their ability to respond to PHA or to produce a graft-vs-host reaction in embryonic chicks. These studies indicated that immunoregulatory cells exist in chicken thymus, which displays both helper and suppressor activity. The suppressor cells were more prevalent or more easily detectable in young birds and in chickens with intact bursas. The helper function of thymocytes was seen to better advantage with cells derived from older animals and from bursectomized donors.     

Suppression of Hen Egg-White Lysozyme (HEL)-Specific Delayed-Type Hypersensitivity Responses in Mice by Suppressor T Cells after Neonatal Administration of Anti-Idiotypic Antibodies

Anti-idiotypic rabbit antiserum (anti-Id) directed to the idiotypes of anti-hen egg-white lysozyme (HEL) antibody from a single C3H mouse (No. 2) was shown to be capable of recognizing only a fraction of the anti-HEL antibody populations produced by other C3H mice. Experiments were performed to examine the effect of this particular anti-Id on the delayed-type hypersensitivity (DTH) response specific for the same protein antigen. A group of 60-day-old C3H mice which had been administered anti-Id within 24 hr after birth were tested for HEL-DTH response. The results indicated that the DTH response was completely suppressed by the anti-Id treatment. The inhibition of DTH reactivity is due to active suppression and involves the generation of suppressor T cells. Thus, the suppression induced with a single injection of anti-Id was transferable with both spleen cells and thymocytes from mice that received anti-Id. These suppressor cells are T cells since their ability to suppress DTH is completely abrogated by treatment in vitro with anti-Thy 1.2 serum and complement.     

Spontaneously Induced Suppressor Cells In Vitro: Nonspecific Suppression of In Vitro Antibody Formation

Nonspecific suppressor cells were induced during in vitro culture of normal mouse spleen cells (SPC) using the Marbrook culture system. The suppressor cells inhibited both the primary and secondary antibody-formation responses antigen nonspecifically in vitro, and both IgM- and IgG-responses were inhibited. The supernatants from suppressive precultured cells were not suppressive. The suppressor cells also inhibited the response of allogeneic SPC beyond H-2 compatibility. The induction of the suppressor cells did not require the presence of antigen but required fetal calf serum (FCS) or both FCS and 2-mercaptoethanol (2-ME). The suppressor cells were generated from the nylon-wool adherent, radiation-sensitive T cell population. On the other hand, the suppressor cells were nylon-wool nonadherent, relatively radiation-sensitive T cells. Actively antibody-producing cells were not affected by the suppressor cells. The suppressor cells inhibited the mitogenic responses of normal SPC to phytohemagglutinin-P (PHA), bacterial lipopolysaccharide (LPS) and concanavalin A (Con A). The suppressor cells themselves inhibited the growth of EL4 cells (T-cell leukemia of C57BL/6 mouse origin) and MOPCll cells (B cells, plasmacytoma of BALB/c mouse origin) even at a low effector-to-target cell ratio (E:T ratio = 1:1), but did not kill these tumor cells. These results indicate that the target cells of the suppressor cells are both T and B cells, and that the mechanism of action of the suppression is either inhibition of proliferation or inhibition of early events in the course of the immune response.     

Mechanism of histamine-induced inhibition of lymphocyte response to mitogens in mice

Histamine induced, in mice, an inhibition of lymphocyte response to PHA and LPS, at molar concentrations ranging from 10^?3 to 10^?9M. This inhibition occurs as a specific interaction between histamine and T lymphocytes bearing H2-type receptors for this hormone (H + cells) and Ly 2 membrane antigens. Two features of the suppressive activity of this T-cell subpopulation were observed: (i) when histamine is added at the beginning of the culture period with PHA or LPS, it activates the suppressor activity of H + cells which act on the lymphocyte population responding to PHA and LPS; (ii) preincubation of spleen lymphocytes with histamine for 24 hr induces suppressor cells which inhibit the response to PHA, but not to LPS, of syngeneic lymphocytes in a coculture system, and which are radiosensitive. The role of PHA as a second stimulus of histamine-induced suppressor cells, and the relation between these cells and PHA or Con A-induced suppressor cells, are discussed.     

Suppression of mitogen- and tumor-cell-induced lymphocyte stimulation by tumor-associated fetal antigens

The ability of tumor-associated fetal antigens (TAFA) to suppress mitogen and tumor-cell-induced blastogenesis was investigated. Three different TAFA (I, III, and IV) were tested in PHA and Con A lymphocyte proliferation assays. Spleen cells from New Zealand black rats (NBR) were fractionated over nylon wool; and nonadherent (NA) and adherent (AD) cells were compared with unfractionated (UF) cell responses. Preincubation of NA cells with TAFA-I was followed by addition of phytohemagglutinin (PHA) elicited suppression in a 3-to 4-day assay. UF cells were unresponsive to TAFA and/or PHA at all concentrations tested. TAFA dose—response titration curves in Con A proliferation assays revealed that all TAFA tested (TAFA I, -III, and -IV from fibrosarcomas; TAFA-I and -III from osteosarcomas) were suppressive. For some TAFA, nanogram quantities produced significant suppression. In mixed leukocyte tumor cell assays (MLTC) both UF and NA normal rat spleen cells were tested for proliferative responses to syngeneic tumor cells. Four distinct TAFA, purified by high-pressure liquid chromatography, suppressed lymphocyte proliferation when added to MLTC cultures in 5-day assays. Specificity experiments demonstrated that trinitrophenol-bovine serum albumin did not produce similar immunosuppression. TAFA did not block recognition of tumor antigen nor produce nonspecific cytotoxicity of the spleen cells. Significant suppression of DNA synthesis was produced by TAFA-1 following cocultivation with spleen and tumor cells for 1, 2, and 3 days, compared to no suppression when spleen and tumor cells were washed free of TAFA-I prior to tumor cell addition at Day 0. Similar experiments using rat embryo fibroblasts (REF) as stimulators demonstrated that pre-REF cocultivation treatment of lymphocytes with TAFA-I significantly reduced subsequent blastogenic responses. This effect was not reversible; however, if TAFA-I was added to responders previously stimulated by REF, a suppressive response was not seen. Experiments were also carried out to determine the reversibility of TAFA-I effects. Cells were treated with TAFA-I from 1 to 5 days, followed by determination of lymphocyte blastogenesis. TAFA-I effects are reversible and antigen presence is required to completely suppress (or inhibit) stimulation by tumor cells.