The role of the macrophage in genetic control of the immune response.

The ability of an animal to mount an immune response is controlled by a number of autosomal dominant immune response (Ir) genes that are linked to the major histocompatibility complex of the species. In the guinea pig, alloantiserums raised by cross-immunization of inbred strain 2 and strain 13 animals specifically inhibited the in vitro proliferative responses of (2 X 13) F1 lymphocytes to those antigens the response to which is controlled by Ir genes linked to the alloantigens against which the serums are directed. A genetic analysis indicated that the inhibitory activity of the alloantiserums was directed against the alloantigens rather than the products of specific Ir genes. The interaction of antigen-pulsed macrophages with immune T lymphocytes is also mediated by the 2/13 alloantigens and alloantiserums are capable of inhibiting macrophage-T lymphocyte interaction. Studies involving combinations of macrophages and lymphocytes that differed at alloantigens or Ir gene products or both raised the possibility of the expression of the Ir gene product in the macrophage.     

Restriction by the major histocompatibility complex of antigen-induced T lymphocyte proliferation in new inbred guinea pig strains.

Employing new inbred guinea pig strains, JY 1, JY 2 and JY 3, established in this Institute in addition to strains 2 and 13, the authors investigated histocompatibility restriction in macrophage-T lymphocyte interaction. These five strains are known to possess distinct major histocompatibility complex (MHC) gene profiles (1, 2). This fact was supported by our results concerning the mixed leukocyte reaction (MLR) and cytotoxicity test with alloantisera. Using various combinations of T lymphocytes and peritoneal exudated cells (PECs) from these strains, in vitro proliferative responses of T lymphocytes from BCC-immune animals to PPD-pulsed normal PEC were tested. Successful activation of T cell response was observed not only in syngeneic combinations but also in allogeneic combinations among strains JY 1, JY 3 and strain 13 which share common Ia antigens detected by strain 2 anti-strain 13 alloantiserum. Because JY 1 and JY 3 seem to share a common B antigen differing from strain 13, it was suggested that identification in the I region of MHC is sufficient for effective antigen-presentation by the macrophage. Although a part of Ia is shared, no T lymphocyte activation was observed in the combination between JY 2 and JY 1 or JY 3, whereas strong MLR occurred in these allogeneic combinations. At the present stage of the study, it can be said that disparity in the part(s) of Ia antigens which is responsible for strong MLR cannot lead to effective T cell-macrophage interaction. These results support the concept that functional activation of primed, proliferating T lymphocyte requires the participation of gene products of macrophages coded for by the I region in MHC. By employing JY 1, JY 2 and strain 2, which appear to possess distinct B and Ia antigens, it was shown that the T lymphocyte and macrophage interactions essential for mitogen-induced T lymphocyte proliferation are not restricted by histocompatibility.     

Macrophage-lymphocyte interaction. III. Site of alloantiserum inhibition of T lymphocyte proliferation induced by allogeneic or aldehyde-bearing cells.

Inhibition by anti-Ia sera of guinea pig T lymphocyte proliferation induced by allogeneic macrophages (MLR) and NaIO4 or neuraminidase-galactose oxidase-treated macrophages has been investigated in order to identify the target cell upon which the antisera act. Anti-2 and anti-13 alloantisera were found to inhibit both MLR and aldehydeinduced T cell reactivity when directed against the specificity of the stimulatory macrophage. Little or no inhibition was observed when these antisera were directed against the T lymphocyte specificity when cultures were harvested at the time of peak proliferation. In addition, anti-2 serum was found to inhibit macrophage-lymphocyte rosett formation at 20 hr between neuraminidase-galactose oxidase-treated strain 2 macrophages and strain 13 lymphocytes. These findings demonstrate that inhibition of T cell proliferation can be produced by anti-Ia sera directed against the macrophage and raise the possibility that Ir gene products may function in part at the level of the macrophage.     

Major-histocompatibility-complex-class-II-positive cells and interleukin-2-dependent proliferation of immune T cells are required to reject carcinoma cells in the guinea pig

Summary Tumor immunity induced by bacillus Calmette-Guérin was studied in the line 10 hepatocellular carcinoma (line 10) in the strain-2 guinea pig. Line 10 immunity was investigatedin vitro with a lymphocyte proliferation assay using line 10 tumor protein extracted with 3 M KCl andin vivo by adoptive transfer of line-10-immune spleen cells. Monoclonal antibodies against guinea pig leucocyte markers were used to block functional properties of the immune cells in order to determine which cell types or cell markers are involved in the immune response to the line 10 tumor.In vitro cells from the spleen, peripheral blood and regional lymph node of immune animals reacted with a proliferative response to line 10 protein. This antigen-specific response was caused by T cells and was regulated by major histocompatibility complex (MHC) class II molecules. In blocking experiments it was found that CT5 (anti-PanT), or MSgp4 [anti-(MHC class I antigen)] monoclonal antibodies did not block but some-times stimulated the proliferative response. The effect of H159 (anti-PanT) was irregular, while H155 [anti-(T helper)], and 5C3 [anti-(IL-2 receptor)] monoclonal antibodies blocked the response almost completely. We studied the relevance of the resultsin vitro obtained and found that mAb 5C3 [anti-(IL-2 receptor)] inhibited the adoptive transfer of line 10 immunity, suggesting that the rejection of line 10 cells is caused by a mechanism that is interleukin-2 (IL-2)-dependent. Moreover, complement lysis of MHC-class-II-antigen-positive immune spleen cells inhibited completely the rejection of the line 10 tumor cell challenge in the adoptive-transfer experiments. In conclusion, our data show that MHC class II molecules or cells possessing these molecules are involved in immunity against line 10 tumor cells, as (a) monoclonal antibodies against MHC class II antigens inhibited thein vitro proliferative response of T cells to tumor antigens and (b) removal of MHC-class-II-positive immune spleen cells abrogated the antitumor effect in the adoptive-transfer experiments. Interleukin-2-dependent proliferation of immune T cells is required for the rejection of line 10 tumor cells.     

Ia antigens in inbred rats and their relationship to the MLR phenotype.

Three different alloantisera were raised by using Ag-B/MLR disparate rats, and the cytotoxic activity remaining after absorption with erythrocytes to remove anti-Ag-B antibodies was examined. The alloantisera detected surface antigens present only on B cells and segregation studies demonstrated that the genes that code for these antigenic specificities were linked to the major histocompatibility complex. The reactivity of the alloantisera with splenic lymphocytes from a panel of strains representative of the currently known Ag-B groups showed that multiple specificities were present in two of the three antisera and that these specificities were shared by many inbred strains. The appropriate absorption studies showed, however, that each antiserum detected an unique specificity that was found only in those inbred strains that shared the same mixed lymphocyte reactivity (MLR) phenotype as the donor strain. The alloantiserum produced against the KGH strain inhibited the MLR reactions involving this strain only when it was used as the stimulating cell population. The antigens detected by the three alloantisera described here have the characteristics of Ia antigens, and they have tentatively been designated Ia.1 (ACI anti-KGH), Ia.3 (B3 anti-BN) and Ia.4 (MNR anti-DA).     

The major histocompatibility complex of the guinea pig. I. Serologic and genetic studies.

Serologic and genetic studies of the antigens which comprise the guinea pig MHC have demonstrated three distinct but linked genetic regions. Antisera to the B region were raised by cross-immunization of random-bred animals; this region controls antigens B.1, B.2, B.3, and B.4 which behave as alleles at a single locus and which resemble the products of the murine D or K region genes in their tissue distribution and molecular characteristics. Cross-immunization of inbred strain 2 and strain 13 animals, both of which bear the B.1 antigen, leads to sera which identify antigens which resemble the products of the I region of the murine MHC. Specific absorption experiments have demonstrated four distinct I region antigens. In addition to the B and I regions, inbred strain 2, strain 13, and some outbred animals bear an antigen (S.1) which is the product of a third genetic region and which also resembles the murine D or K region gene products in molecular size. The results of these studies should facilitate the use of the guinea pig as an experimental model for studies of genetic control of the immune response and the function of the histocompatibility-linked Ir genes.     

Modulatory effect of zinc on the proliferative response of murine spleen cells to polyclonal T cell mitogens

To study the effect of zinc on the proliferative response to polyclonal T cell mitogens, spleen cells from C57BL/6 mice were cultured with or without ZnCl2 and stimulated with graded doses of concanavalin A or phytohemagglutinin. Addition of 10(-4) M ZnCl2 inhibited proliferation whereas 10(-5) to 10(-6) M ZnCl2 did not modify the response to suboptimal doses of mitogen but increased DNA synthesis in cultures stimulated with high doses of mitogen (10 or 20 micrograms/ml of concanavalin A and 10 or 25 microliters/ml of phytohemagglutinin) which are supraoptimal for C57BL/6 mice, and inhibited proliferation in cultures of spleen cells from animals of this strain, low responder to T cell mitogens. In contrast, supplementation with ZnCl2 did not enhance the response to mitogen of spleen cells from high responder BALB/c mice. The enhancing effects of ZnCl2 on the proliferative response of C57BL/6 cells were not observed following depletion of adherent cells or in cultures supplemented with 5 X 10(-5) M 2-mercaptoethanol, both conditions capable of abrogating the inhibitory effect of high mitogen doses on the response of C57BL/6 cells.     

Induction of transplantation tolerance in guinea pigs by spleen allografts. II. Responses in the mixed leukocyte reaction correlate with the tolerant state

We have developed a model for the induction of transplantation tolerance in the guinea pig by vascularized spleen allografts. Spleen allografts from strain 13 to strain 2 hosts frequently survived in healthy recipients without clinical GVHD or induced clinical GVHD. (2 x 13)F1 to strain 2 spleen allografts survived indefinitely without inducing GVHD. In contrast, strain 2 spleen allografts were rejected by strain 13 hosts. An excellent correlation was observed between the clinical course and the degree of reactivity to donor strain stimulator cells in the MLR. Animals that had rejected their grafts had normal or enhanced proliferative responses in the MLR. Strain 2 hosts with long-term surviving strain 13 or (2 x 13)F1 grafts had markedly suppressed anti-13 responses. Animals with GVHD had a suppressed MLR toward donor strain stimulator cells with simultaneous reactivity to host strain stimulator cells. Cells capable of suppressing the response of normal host strain cells to donor strain stimulators were present in some long-term surviving animals and may be responsible in part for the maintenance of the tolerant state.     

Major histocompatibility complex restriction of T-cell responses to varicella-zoster virus in guinea pigs.

Varicella-zoster virus (VZV), adapted to grow in guinea pig fibroblasts, was injected subcutaneously into Hartley, strain 2, and strain 13 guinea pigs. Serum immunoglobulin G antibodies were detected 2 weeks later, and T-cell proliferative responses by blood lymphocytes were found 3 weeks after injection. The proliferating cells bound the 155 antibody, which defines a CD4-like subset of guinea pig T lymphocytes. VZV-infected fibroblasts of human, Hartley, and strain 13 origin elicited equivalent amounts of proliferation, which was quantitatively greater than that obtained with an extracted VZV antigen. Uninfected (control) human or guinea pig fibroblasts did not elicit T-cell proliferation. The proliferative response to VZV required the presence of autologous (strain 2 or 13) antigen-presenting cells and was blocked by the addition of an anti-class II major histocompatibility complex antibody. Effector cells obtained from in vitro cultures mediated class II-restricted cytotoxicity to L2C cells incubated with VZV. Class I-restricted responses were obtained only by cross-priming strain 2 animals with strain 13 peritoneal exudate cells which had been preincubated with VZV. The data indicate that guinea pigs resemble humans in that class II-restricted T cells with specificity for VZV are more readily cultured from blood than are class I-restricted cells.     

Specific absorption of T lymphocytes committed to soluble protein antigens by incubation on antigen-pulsed macrophage monolayers.

Monolayers of macrophages (Mphi) pulsed with antigen were used as immunosorbents for T lymphocytes from guinea pigs primed to soluble protein antigens. T lymphocytes were cultured on the Mphi monolayers for 4 hr, then aspirated and reincubated on a fresh monolayer pulsed with the same antigen for a second and a third step. T lymphocytes so treated were selectively deprived of cells responding in assay for antigen-dependent proliferation against the antigen used for pulsing the absorbing monolayer, but maintained their response to other antigens. The lymphocytes adhering to the Mphi of the absorbing monolayer were capable of giving a full response to the antigen used for pulsing the Mphi of the monolyers. The proliferative response of F1 T lymphocytes to antigen in association with Mphi of either parental strain could be absorbed leaving the response to antigen in association with Mphi of the other parental strain. The absorption of the proliferative response was not inhibited by addition of excess soluble antigen to the medium of the absorption culture. Our results indicate that specific guinea pig T lymphocytes responding by proliferation to soluble protein antigens recognize and bind specifically to a complex of Ia antigen and protein antigen at the surface of the Mphi.     

Genetic control of experimental autoimmune myasthenia gravis in mice. III. Ia molecules mediate cellular immune responsiveness to acetylcholine receptors

When MHC congenic and recombinant mice are inoculated with Torpedo acetylcholine receptors (AChR) with adjuvants, the magnitude of autoantibody responses to muscle AChR and the defect of neuromuscular transmission closely parallel in vitro lymphocyte proliferative responses to Torpedo AChR. All of these responses are controlled by gene(s) at the I-A subregion of the H-2 complex. Data presented in this report confirm in back-cross mice that T lymphocyte proliferative responses to AChR are controlled by a Mendelian dominant gene linked to H-2, at the I-A subregion. Lymphocyte responses were eliminated by blocking Ia antigens on lymph node cell surfaces with appropriate anti-I-A alloantisera and by removal of adherent cells. A spontaneous mutation at the I-A subregion in the B6 strain, which resulted in structural alteration of the A beta chain of Ia, converted high responsiveness to AChR to a state of low responsiveness. These data implicate a macrophage-associated Ia molecule in induction of autoimmune responses to AchR, probably in the presentation of AChR to helper T lymphocytes that thereby help B lymphocytes to differentiate into anti-AChR antibody-forming cells.     

T lymphocyte-enriched murine peritoneal exudate cells. III. Inhibition of antigen-induced T lymphocyte Proliferation with anti-Ia antisera.

The recent development of a reliable murine T lymphocyte proliferation assay has facilitated the study of T lymphocyte function in vitro. In this paper, the effect of anti-histocompatibility antisera on the proliferative response was investigated. The continuous presence of anti-Ia antisera in the cultures was found to inhibit the responses to the antigens poly (Glu58 Lys38 Tyr4) [GLT], poly (Tyr, Glu) ploy D,L Ala-poly Lys [(T,G)-A--L], poly (Phe, Glu)-poly D,L Ala-poly Lys [(phi, G)-A--L], lactate dehydrogenase H4, staphylococcal nuclease, and the IgA myeloma protein, TEPC 15. The T lymphocyte proliferative responses to all of these antigens have previously been shown to be under the genetic control of major histocompatibility-linked immune response genes. The anti-Ia antisera were also capable of inhibiting proliferative responses to antigens such as PPD, to which all strains respond. In contrast, antisera directed solely against H-2K or H-2D antigens did not give significant inhibition. Anti-Ia antisera capable of reacting with antigens coded for by genetically defined subregions of the I locus were capable of completely inhibiting the proliferative response. In the two cases studied, GLT and (T,G)-A--L, an Ir gene controlling the T lymphocyte proliferative response to the antigen had been previously mapped to the same subregion as that which coded for the Ia antigens recognized by the blocking antisera. Finally, in F1 hybrids between responder and nonresponder strains, the anti-Ia antisera showed haplotype-specific inhibition. That is, anti-Ia antisera directed against the responder haplotype could completely block the antigen response controlled by Ir genes of that haplotype; anti-Ia antisera directed against Ia antigens of the nonresponder haplotype gave only partial or no inhibition. Since this selective inhibition was reciprocal depending on which antigen was used, it suggested that the mechanism of anti-Ia antisera inhibition was not cell killing or a nonspecific turning off of the cell but rather a blockade of antigen stimulation at the cell surface. Furthermore, the selective inhibition demonstrates a phenotypic linkage between Ir gene products and Ia antigens at the cell surface. These results, coupled with the known genetic linkage of Ir genes and the genes coding for Ia antigens, suggest that Ia antigens are determinants on Ir gene products.     

Effect of monoclonal antibodies (MoAb) to class I and class II HLA antigens on lectin- and MoAb OKT3-induced lymphocyte proliferation

We have examined the effect of several monoclonal antibodies (MoAb) to monomorphic determinants of class II HLA antigens, and MoAb to monomorphic determinants of class I HLA antigens and to beta-2-microglobulin (beta 2-mu) on lectin- and MoAb OKT3-induced proliferation of human peripheral blood mononuclear cells (PBMNC) and cultured T cells (CTC). Some, but not all, anti-class II HLA MoAb inhibited the proliferative response of PBMNC to MoAb OKT3 and pokeweed mitogen (PWM). The degree of inhibitory effect varied considerably. This effect was not limited to anti-class II HLA MoAb since anti-class I HLA MoAb and anti-beta 2-mu MoAb also inhibited MoAb OKT3- or PWM-induced proliferative responses. In contrast, the response of PBMNC to phytohemagglutinin (PHA) and concanavalin A (Con A) was not blocked by any anti-class II HLA MoAb. However, some anti-class II HLA MoAb also inhibited the proliferative response of CTC plus allogeneic peripheral blood adherent accessory cells (AC) to PHA or Con A as well as to MoAb OKT3 or PWM. This may be attributable to the substantially greater class II HLA antigen expression by CTC than by fresh lymphocytes. Pretreatment of either CTC or AC with anti-class II HLA MoAb inhibited OKT3-induced proliferation. In contrast, pretreatment of CTC, but not AC, with anti-class I HLA MoAb inhibited the proliferative response of CTC to OKT3. Pretreatment of CTC with anti-class I HLA MoAb inhibited PHA-, Con A and PWM-induced proliferation, to a greater degree than the anti-class II HLA MoAb. It appears as if lymphocyte activation by different mitogens exhibits variable requirements for the presence of cells expressing major histocompatibility determinants. Binding of Ab to membrane markers may interfere with lymphocyte-AC cooperation, perhaps by inhibiting binding of mitogens to their receptors or by interfering with lymphocyte and AC function. We also have examined the role of class II HLA antigens on CTC by depleting class II HLA-positive cells. As expected, elimination of class II HLA-positive AC with anti-class II HLA MoAb plus complement caused a decrease in proliferation of CTC in response to all the mitogens tested. In contrast, elimination of class II HLA-positive CTC was shown to clearly increase proliferation of CTC, perhaps because this may deplete class II HLA-positive suppressor cells.     

Amplification of suppressor inducer pathway with monoclonal antibody, anti-2H4, identifying a novel epitope of the common leukocyte antigen/T200 antigen

The 2H4 antigen, comprised of a 200/220-kDa glycoprotein of the leukocyte common antigen (LCA) family, is expressed on a suppressor inducer, but not a helper inducer subset of T4 cells. Earlier studies have demonstrated that the T4+2H4+ subset of cells maximally responded to the AMLR and this molecule has an important role in generated suppressor signals in AMLR/Con A-activated T cell systems. In the present study, we examined the effect of a series of monoclonal antibodies including anti-2H4 antibody on the initial activation of T4 cells in response to self-Ia antigens. We found that the addition of anti-2H4 antibody resulted in an augmentation of the proliferative response of T4 cells in AMLR, whereas other antibodies reactive with LCA/T200 antigens lacked this ability. Furthermore, anti-2H4 antibody enhanced both IL-2 production and IL-2R expression in this AMLR system. This enhancing effect was inhibited by anti-T3 antibody. Moreover, the suppressor inducer function of AMLR T4 cells was enhanced with anti-2H4 antibody by increasing the number of 2H4+ cells with high antigen density. Taken together, these results suggest that the 2H4 antigen may serve as an accessory structure for enhancing the activation of the T4+2H4+ suppressor inducer subset at initiation of cell triggering.     

The T4 molecule differentially regulating the activation of subpopulations of T4+ cells

It has been demonstrated that the T4+2H4+ subset functioned as a suppressor inducer cell, whereas the reciprocal T4+2H4- subset provided help for B cell Ig production. In the present studies, a series of monoclonal antibodies to cell surface structures expressed on these subsets of cells were examined for their effects on the proliferative and immunoregulatory functions generated in AMLR. We demonstrated that anti-T4 antibody preferentially inhibited the proliferative response of the T4+2H4+ but not T4+2H4- cells against self-MHC antigens. In contrast, anti-T3 and anti-Ia antibodies inhibited the response of both subsets of cells. This subset preference of anti-T4 antibody was not attributable to either the isolation procedures used or a shift in the kinetics of proliferation to autologous self-MHC antigens. Moreover, both IL 2 production and the immunoregulatory function of the T4+2H4+ subset was profoundly inhibited by anti-T4 antibody, whereas the T4+2H4- subset was minimally influenced. In the absence of Ia molecules, T4+2H4+ but not T4+2H4- cell proliferation was inhibited with anti-T4 antibody. Together, these results suggest that the T4 molecule plays a distinct functional role in the differential triggering of subsets of T4+ cells.     

Activation of antigen-enriched B cells. II. Role of linked recognition in B cell proliferation to thymus-dependent antigens

The responsiveness to T-dependent (TD) and T-independent (TI) TNP-antigens of murine splenic B cells previously enriched for antigen-binding cells (ABC) was examined. TNP-TI antigens induced B cell proliferation. TNP-TD antigens did not induce a proliferative response regardless of the physical form or nature of the TNP-TD antigen (e.g., soluble vs particulate, low or high haptenation of carrier, TNP on various insoluble matrices, etc.). TNP-TD antigens were effective in enhancing the response of the TNP-ABC to all concentrations of lipopolysaccharide (LPS) tested, indicating that binding of antigen to surface immunoglobulin alters the LPS responsiveness of the cell. Irradiated, keyhole limpet hemocyanin- (KLH) primed T cells induced a threefold to fourfold greater B cell proliferative response with TNP-KLH than with fluoresceinated KLH (FLU-KLH) or FLU-KLH together with TNP-human serum albumin (TNP-HSA). Therefore, linked recognition appears essential for optimal T cell-mediated B cell proliferation, whereas the induction of B cell proliferation via nonlinked, carrier-activated T cells is a minor component of the response.     

Analysis of Ir gene function using monoclonal antibodies: independent regulation of GAT and GLPhe T cell responses by I-A and I-E subregion products on a single accessory cell population

T cell proliferative responses to the synthetic polypeptides GAT and GLPhe are under Ir gene control. GAT responses are regulated by gene(s) in the I-A subregion, and GLPhe responses are controlled by a pair of complementing genes mapping to the I-A and I-E subregions. We demonstrate that monoclonal antibody to the I-A gene product inhibits GAT proliferation but not the GLPhe response, whereas a monoclonal antibody to the I-E associated Ia-7 determinant inhibits GLPhe but not GAT proliferation, which indicates independent involvement of each Ia determinant in antigen presentation for the T cell response to these antigens. Use of the same subregion-specific monoclonal antibodies in complement-dependent lysis demonstrates that the antigen-presenting cells for GAT and GLPhe express both I-A and I-E products. The possibility that an Ia subregion-specific "self-receptor" functions on the reactive T cells as a regulatory element is discussed.     

Variation in T cell responses to ovalbumin in cattle: evidence for Ir gene control

Genetic control of immune responsiveness in cattle was investigated using an antigen-dependent T cell proliferation assay in vitro. Bovine T cell proliferative responses to ovalbumin were dependent upon major histocompatibility complex (MHC) class II molecules. Responses of an unrelated panel of animals to a limiting concentration of ovalbumin after a single immunization were compared. Two discrete patterns of response were observed. One group of animals had low or non-responses which were not significantly different from the preimmune levels. Another group of animals showed significant responses. After a second immunization the majority of low responders remained low responders. There was no significant correlation between bovine MHC class I BoLA haplotype and magnitude of response within this group of unrelated animals. However, the magnitude of the T cell responses by two half-sib family groups segregated with BoLA haplotypes inherited from the sire. In contrast no significant correlation with antibody responses in vivo could be demonstrated. We suggest that the observed variation in T cell response is linked to bovine MHC class II immune response (Ir) genes.     

Role of individual chains of HLA-DR antigens in activation of T cells induced by alloantigens

The role of HLA-DR antigens in the activation of T cells in the allogeneic mixed lymphocyte reaction (MLR) was studied by using antibodies raised against the alpha, beta or the complex of both chains of the HLA-DR antigens. Antisera directed against the alpha or the beta chain strongly inhibited the T-cell proliferative response when added at the begining of MLR cultures but not 72 h later. T cells from MLR cultures treated with either alpha-chainor beta-chain-specific antibodies did not respond to interleukin-2 (IL-2) by proliferating, whereas T cells from non-anti-DR-treated cultures showed a proliferative response to IL-2 stimulation. However, neither the anti-alpha chain nor the anti-beta chain serum was able to inhibit continuous proliferation of already activated, IL-2-reactive T cells supported by IL-2. In MLR, OKT4⁺ but not OKT8⁺ lymphocytes synthesized IL-2. This function was abrogated by the alpha-chain-specific antibody but not by the anti-beta chain serum. Interleukin-1 (IL-1) did not reverse the inhibitory activity on IL-2 synthesis of the alpha-chain antibody, while IL-1 promoted the production of IL-2 in MLR cultures not exposed to the anti-DR sera. In addition, nonstimulated OKT4⁺ cells were unresponsive to IL-1 and did not produce IL-2. From these results, it is concluded that HLA-DR antigens participate actively in the activation of T cells by allogeneic non-T cells. Thus, both the alpha and beta chains of HLA-DR antigens render resting T cells sensitive to IL-2. In addition, the alpha but not the beta chain participates in the production of IL-2 by enabling OKT4⁺ lymphocytes to respond to IL-1 and subsequently to synthesize IL-2. Once T cells have acquired responsiveness to IL-2 and this growth factor has been produced there is no further requirement for HLA-DR antigens. Continuous proliferation and growth of IL-2-reactive T cells depends on the availability of interleukin-2.     

Ag-B-linked analogue of Ia antigens in the rat.

The reactions of Lewis rat lymphocyte membrane antigens with two alloantisera, BN anti-Lewis and BN anti-Fischer have been studied. Three lines of evidence indicated that these antisera reacted with cell surface antigens homologous to Ia antigens of the mouse. 1) After absorption with Lewis platelets, the antisera killed only 40 to 50% of Lewis spleen cells. The majority of such cells were shown to be Ig-positive B cells by the examination of reaction patterns on lymphocytes after separation on nylon wool into T cell- and B cell-enriched subpopulations. 2) SDS-PAGE analysis of solubilized Lewis spleen cell antigens precipitated with these antisera revealed that the platelet-absorbed antisera reacted with molecules comparable in size to mouse Ia antigens (mw approximately equals 35,000 and 28,000). The unabsorbed sera reacted with these molecules and with additional molecules corresponding in size to mouse K and D antigens (m.w. = 45,000). 3) Neither of these antisera killed significant numbers of spleen cells from the partially congenic strain F.BN (seventh backcross homozygotes), a Fischer rat to which the Ag-B.3 allele is being transferred by repetitive backcrossing, indicating that the genes coding for these Ia-like antigens in the rat are linked to the Ag-B locus.