Antigen-specific T-cell factors in the genetic control of the immune response to poly(Tyr,Glu)-polyDLAla--polyLys. Evidence for T- and B-cell defects in SJL mice

Identification of a genetic locus on chromosome 11 that regulates leukocyte infiltration in mouse carotid artery

OBJECTIVE

We demonstrated that inflammatory cells and intima-media thickening are increased in carotids exposed to low-blood flow in the SJL/J (SJL) strain compared with other mouse strains. We hypothesized that the extent of inflammation associated with intima-media thickening is a genetically regulated trait.

APPROACH AND RESULTS

We performed a whole genome approach to measure leukocyte infiltration in the carotid intima as a quantitative trait in a genetic cross between C3HeB/FeJ (C3H/F) and SJL mice. Immunostaining for CD45(+) (a pan-specific leukocyte marker) was performed on carotids from C3H/F, SJL, F1, and N2 progeny to measure leukocyte infiltration. We identified a nearly significant quantitative trait locus for CD45(+) on chromosome (chr) 11 (17 cM, LOD=2.3; significance was considered at threshold P=0.05). Interval mapping showed that the CD45(+) locus on chr 11 accounted for 8% of the variation in the logarithm of odds backcross. Importantly, the CD45(+) locus colocalized with the intima-modifier 2 (Im2) locus, which controls 17% of intima variation. We created 2 Im2 congenic lines of mice (C3H/F.SJL.11.1 and C3H/F.SJL.11.2) to better understand the regulation of intima-media thickening by the chr 11 locus. The C3H/F.SJL.11.1 congenic mouse showed ≈30% of the SJL trait, confirming that CD45(+) cell infiltration contributed to the intima trait.

CONCLUSIONS

We discovered a novel locus on chr 11 that controls leukocyte infiltration in the carotid. Importantly, this locus overlaps with our previously published Im2 locus on chr 11. Our study reveals a potential mechanistic relationship between leukocyte infiltration and intima-media thickening in response to decreased blood flow.

Interleukin-18 and macrophage migration inhibitory factor are associated with increased carotid intima-media thickening

OBJECTIVE

Carotid intima-media thickening (IMT) is a form of vascular remodeling that has a strong genetic component. Recently, we discovered that in response to decreased carotid blood flow SJL mice developed the largest intima among 5 inbred strains. Because the SJL strain is prone to autoimmune diseases, we hypothesized that inflammation contributed to IMT in SJL mice.

METHODS AND RESULTS

We compared vascular remodeling (induced by 2 weeks of low flow) in 2 strains with small IMT (C3H/HeJ and C3HeB/FeJ) versus 2 strains with large IMT (FVB/NJ and SJL/J). Quantitative immunohistochemistry showed a dramatic increase in inflammatory cells per intima area in SJL compared with other strains. Microarray profiling of inflammatory gene mRNAs from carotids showed significant increases in interleukin (IL)-18 and Mif gene expression in SJL compared with C3HeB/FeJ mice. Increased expression of these genes was confirmed by quantitative reverse-transcription polymerase chain reaction and immunohistochemistry. Furthermore, greater cell proliferation in the intima of SJL accounted for increased intima-media thickening, whereas a higher level of apoptosis and a lower level of proliferation were observed in C3HeB/FeJ mice.

CONCLUSIONS

The present study indicates that increased expression of Mif and IL-18 cytokines is associated with intima-media thickening in SJL mice, likely by stimulating inflammation and proliferation.

Brain abnormalities in immune defective mice

Mouse strains with or without immune disorders were examined in order to further assess the incidence of brain anomalies in immune-disordered strains. The brain was examined in Nissl-stained serial sections under a light microscope for the presence of abnormalities, with specific attention to ectopic collections of neurons in layer I of the neocortex, as reported in the autoimmune New Zealand Black (NZB) and BXSB strains. The present study was designed to survey additional strains with immune disorders (Snell dwarf, C57BL/6J-nu/nu, BALB/cByJ-nu/nu, and SJL) and 7 control strains without immune disorders. In addition, we attempted to replicate past findings in the highly affected BXSB strain and the MRL/1 strain, which develops autoimmune disease, but has a low incidence of brain abnormalities. The largest number of brain abnormalities (20-40%) were seen in the C57BL/6J-nu/nu, Snell dwarf and BXSB strains. The anomalies in the C57BL/6J-nu/nu and BXSB mice consisted of ectopic neurons in layer I of the neocortex, whereas the Snell dwarf mice had either neuron-free areas in the cortex, or rippling of cortical layers II-IV, and one case had agenesis of the corpus callosum. Between 4% and 8% of the mice from the SJL, MRL/1, and MRL +/+ strains had either neuron-free areas in the cortex or ectopic neurons in layer I. The BALB/cByJ-nu/nu and control strains did not have any cortical abnormalities. Future studies will be designed to determine whether immune-based alterations to the developing brain are responsible for the brain anomalies present in immune-disordered strains.

Genetic control of HLA-linked immune responsiveness to (H,G)-A-L

Fifty-three donors belonging to seven families were tested for their immune response potential to (H,G)-A-L. Most of these donors had been previously tested for their ability to respond to (T,G)-A-L and were all HLA typed as well. The heredity of the ability to respond to (H,G)-A-L by the production of an antigen-specific helper T cell factor is compatible with an autosomal dominant trait linked to HLA. The genotype of an HLA-A/B recombinant individual suggested that a gene controlling the immune response to (H,G)-A-L is linked to HLA-A. Lod scores also suggested a linkage between immune response potential to (H,G)-A-L and HLA-A. The different patterns of responses to (T,G)-A-L and (H,G)-A-L observed in many individuals are compatible with the notion that separate loci are governing the immune responses to the two synthetic polypeptides.

Two genes in the major histocompatibility complex control immune response

Sixty-four (57.6%) of 111 cancer patients with cerebrospinal fluid cytology positive for malignant cells had cranial computed tomographic (CT) scans within 2 weeks before or after a lumbar puncture. Twenty-two (34.3%) of the 64 had abnormal CT findings indicative of leptomeningeal metastasis: (1) sulcal-cisternal enhancement, (2) ependymal-subependymal enhancement, (3) widened irregular tentorial enhancement, or (4) communicating hydrocephalus. Thirteen (59.6%) of these 22 patients had associated parenchymal metastases. Recognition of leptomeningeal disease may alter the management of patients with parenchymal metastases. Communicating hydrocephalus in cancer patients should be considered to be related to leptomeningeal metastasis until proven otherwise.

Genetically regulated human (T,G)-A-L specific helper T cell replacing factors possess HLA-DR and VH determinants

Human (T,G)-A-L specific T cell helper factors secreted by in vitro activated peripheral blood lymphocytes of normal donors were characterized. Factors were passed through columns of Sepharose coupled either to antibodies against human immunoglobulin or antibodies against the variable region of the heavy (VH) and light (VL) chains of human immunoglobulin. In addition, the same factors were applied to columns of Sepharose coupled to anti-HLA-DR antibodies or to monoclonal antibodies against human Ia or beta 2-microglobulin. The activity of the antigen specific factors was removed by the anti-VH antibodies and not by anti-VL or anti-human immunoglobulin antibodies. The factors passed through Sepharose coupled to anti-DR antibodies could be removed and eluted from columns of anti-DR antibodies relevant to the donors' DR antigens. The same factors were also removed by a monoclonal antibody (anti-Ia) which recognizes a monomorphic determinant on HLA-DR, but not by monoclonal anti-beta 2-microglobulin. The results suggest that the genetically regulated (T,G)-A-L specific helper factors possess HLA-DR as well as VH determinants in their active moiety.

Genetic regulation of delayed-type hypersensitivity responses to poly (Tyr,Glu)-poly(DLAla)--poly(Lys): expression of the genetic defect in the induction and manifestation phases in H-2s and H-2f mice

The genetic defect of H-2s and H-2s non-responder mouse strains in both the induction and manifestation phases of delayed-type hypersensitivity (DTH) responses to poly(LTyr,LGlu)-poly(DLAla)--poly(LLys)[(T,G)-A--L] was analysed. Utilizing an in vitro system to activate DTH effector T cells, we observed that non-adherent T cells of (H-2f X H-2b) F1 or (H-2s X H-2b)F1 responder mice, could not be activated on antigen bearing adherent cells of H-2f or H-2s haplotypes. On the other hand, these T cells were effectively sensitized on adherent cells derived from either F1 or parental (H-2b) responder mice. These results indicate that in these mouse strains the genetic defect, in the induction phase of DTH, is expressed at the level of the antigen presenting cell. In subsequent experiments, we were able to "correct' the non-responsiveness of H-2s recipients by transfer of educated and irradiated (H-2s X H-2b)F1 T cells together with normal F1 adherent cells. Normal non-adherent and nylon wool enriched T cells failed to restore these responses. Similarly, antigen-pulsed F1 irradiated peritoneal exudate cells could stimulate DTH responses in SJL recipients of (SJL X C57BL/6)F1 (T,G)-A--L educated cells. The genetic defect of H-2s mice in the manifestation phase of the DTH reaction is thus also expressed on the antigen presenting cell.

The role of H-2 I region genes in regulation of the immune response

The evidence of the past 10 years indicates that genes mapping in the I region of the mouse major histocompatibility complex (H-2) regulate a bewildering array of immunologic functions. A survey of H-2-linked specific immune response (Ir) genes shows that the phenotypic effect of these genes is to enable a particular inbred strain to discriminate and recognize remarkably precise chemical specificities, such as one or two amino acid interchanges in a polypeptide chain. The only I region gene products which have been identified to date are the Ia antigens. These include five readily detectable polypeptide chains (Aa, Ab, Ae, Ea, and Ii) and several other serologically distinct entities which are selectively expressed on functionally distinct T cell subsets (J1, J2?, J3? and C). The specificity of recognition of Ir genes would seem to require a larger number of I region gene products than can be generated even by combinatorial association of the four readily identifiable peptides (to give eight combinatorial associations) and the other serologically identified gene products. If the Ia antigens are to function as an antigen specific receptor system, separate from immunoglobulin molecules, there must be other, as yet undetected, I region gene products (e.g. Ia antigens). Alternatively, the known I region gene products could function by any one of several postulated mechanisms to generate an antigen specific T cell receptor system. The available evidence for the total number of I region gene products is reviewed, and the alternate possibilities are briefly discussed in this presentation.

Immune response potential to poly(Tyr,Glu)-poly(DLAla)--poly(Lys) of human T cells of different donors

Human peripheral blood T cells of normal donors were activated in vitro with autologous adherent cells pulsed with poly(LTyr,LGlu)-poly(DLAla)--poly(LLys) [abbreviated (T,G)-A--L]. The "educated" T cells were tested: (i) for their ability to produce a (T,G)-A--L-specific T cell-replacing factor in the cooperation with B cells for antibody responses in vivo or in vitro and (ii) for their ability to proliferate in the presence of a second stimulus of (T,G)-A--L. Results of screening of 66 donors demonstrated that educated T cells of about 50% of the donors produced an active (T,G)-A--L-specific factor, whereas activated cells of only half of the factor producers were capable of proliferating in the presence of the antigen. Thus, as reported for all other species studied, human individuals differ in their response potential to (T,G)-A--L.

Antigen-specific T-cell factors

Antigen-specific T-cell factors are mediator molecules which are produced by helper and suppressor T cells and which can perform the function of those cells in an antigen-specific manner. They probably play an important part in immunoregulation. The major histocompatibility complex has a controlling influence on their structure and activity, while their antigen-recognition properties may be conferred by immunoglobulin V regions. Interest in the factors derives from three related areas of research, namely (i) the problem of T-cell recognition of antigen; (ii) the mechanisms of cellular interactions in antibody production and cell-mediated immunity; and (iii) the genetic control of immune responses. This review discusses the literature up to June 1980 on their production, structure, genetic restriction and mechanism of action.

Antigen specific T cell factors

Antigen specific helper and suppressor factors have a similar structure, with two major sections, a 'variable region', determining antigen specificity which is likely to be controlled by Immunoglobulin VH genes, with which it shares idiotype and framework determinants. Specific factors also have a 'constant region' which does not vary between strains and minimally between species or with the antigenic specificity of the factors, which are defined by rabbit anti-helper or anti-suppressor antisera. This region determines the biological function of the molecule. Anti-Ia antisera react with factors, but the nature and function of Ia molecules on T cell factors is still unclear. The model of specific factor structure, with C and V regions resembles that of immunoglobulin, and it is thus possible that the C region of factors, like the V region is Ig linked. Because there are multiple T cells, helping and suppressing antibody responses specifically, it seems improbable that all of these cells could interact directly with rare antigen-specific B cells. Thus we propose that macrophage presenting cells are the key to the integration of signals for immune induction and regulation for T and B cells. Since Ir genes have been identified in the macrophage presenting cells interacting with both T and B cells, this suggests that macrophage Ia antigens are of importance in the integration of triggering signals for the lymphoid pool.

Natural killer cell activity associated with reticulum cell neoplasms

A marked increase in natural killer (NK) activity is observed with lymphoid cells prepared from SJL/J mouse spleen and lymph nodes, in which a transplantable reticulum-cell neoplasm (RCN) is growing. The killer cells are non-adherent, non-phagocytic, relatively resistant to X-ray, and scarcely or only partially inactivated by treatment with anti-Thy 1.2 serum and complement. The killer activity is directed against a wide variety of tumor target cells, not requiring homology in histocompatibility, but is selective and not indiscriminate. Kinetics of in vivo development on NK activity, competitive inhibition of in vitro cytotoxicity by target cells and their membrane extracts are described. The NK activity appears to increase in parallel with the infiltration and growth of RCN in these organs. No such augmented NK activity was observed with other types of tumors that grew in these organs of SJL/J mice. (C57BL/6 X SJL/J)F1 mice pretreated with silica to abrogate Hh restriction and subsequently injected with RCN of SJL/J (H-2s) origin supported the growth of transplanted RCN. The high NK activity associated with this RCN was markedly reduced by in vitro treatment with anti-H2b serum plus complement, indicating the host origin of NK cells. However, the close association of RCN growth with elevated NK activity may indicate a special function of RCN in promoting NK activity by an unknown mechanism(s) of cellular interactions.

Genetic regulation of delayed-type hypersensitivity responses to poly(LTyr,LGu)-poly(DLAla)--poly(LLys). I. Expression of the genetic defect at two phases of the immune process

Delayed-type hypersensitivity (DTH) responses served in this study as an experimental model for the analysis of genetic regulations of T-cell responses. Educated irradiated cells from H-2b mice mediated responses in syngeneic recipients, whereas mice of the a, d, f, k, and s haplotypes were nonresponders to poly(LTyr,LGlu)-poly(DLAla)--poly(LLys)[(T,G)-A--L]. These results suggest that cell-mediated immune responsiveness to (T,G)-A--L is linked to the H-2 complex, as was shown for humoral responses. Educated irradiated T cells of F1 hybrids between high and low responders mediated DTH responses, which indicates that the gene(s) controlling the DTH responses is dominant. To analyze the genetic defect in DTH responses to (T,G)-A--L, we separated the T-cell activation phase from the effector phase that was determined in recipient mice. Two types of nonresponders were observed: (a) When lymphocytes of the a or k haplotypes were educated in a syngeneic environment and then transferred into hybrids between the parental (nonresponder x responder) F1 recipients, DTH responses could have been manifested. (b) On the other hand, no DTH responses could be mediated by transferring educated cells of the H-2s or H-2f origin into the appropriate F1 recipients. In addition, irradiated F1 cells that had been activated to (T,G)-A--L could not mediate DTH responses in both types of nonresponder recipients. These results suggest that T cells of H-2k or H-2a mice can be activated to generate DTH responses to (T,G)-A--L and that the defect in these mouse strains is expressed in another cell population needed for the manifestation of the DTH reaction in the recipient mice. In contrast, T cells of H-2s and H-2f origin cannot be activated to (T,G)-A--L and, thus, fail to manifest DTH responses.

Recognition of antigens by T lymphocytes

The present review briefly summarizes our knowledge of antigen-specific B and T lymphocyte receptors. Antigen-specific receptors on mammalian B lymphocytes are mainly monomeric IgM and IgD consisting of conventional immunoglobulin heavy and light chains. The nature of the T lymphocyte receptor which can specifically recognize antigens is not yet fully defined. However, it seems that conventional light chains do not participate in the build up of this receptor, and that the receptor is made up of heavy chains of a new immunoglobulin class which has to be further characterized and which we call Tau-chain. The variable region of the T lymphocyte receptors share idiotypic determinants with the corresponding B lymphocyte receptors. The possible linkage between the T cell idiotypes present on the Tau-chains and molecules which are under the control of genes of the Major Histocompatibility Complex of the species are discussed. In the last part of the review two methods for the induction of specific transplantation tolerance in adult animals are described. These methods are based on the concept that T lymphocytes reactive against alloantigens bear idiotypic determinants against which a specific auto-immune response can be initiated.

Antigen-specific helper factor in man

Supernates of tetanus toxoid (TT) antigen-stimulated human T cells were studied for the presence of an antigen-specific T-cell helper factor (ASF). Supernates were circulated over an immunosorbent column consisting of insolubilized TT antigen. The material which bound to the column was eluted with 3 M NaCNS and was shown to contain a factor which in the presence of TT-induced specific IgG anti-TT antibody synthesis in autologous B cells without causing readily detectable proliferation. ASF activity was partially inhibited by antisera directed against the B-cell alloantigens of the ASF donor. Immunosorbent columns containing such antisera removed ASF activity. Immunosorbent columns containing antisera to human immunoglobulin heavy chain determinants did not remove ASF activity; whereas immunosorbent columns containing rabbit idiotypic antiserum directed against anti-TT antibodies completely removed ASF activity. ASF was destroyed by treatment with proteolytic enzymes; its molecular weight was estimated by Sephadex G-100 gel column chromatography to be between 25,000 and 75,000 daltons.

The role of H-2-linked genes in helper T-cell function. III. Expression of immune response genes for trinitrophenyl conjugates of poly-L(Tyr, Glu)-poly-D,L-Ala--poly-L-Lys in B cells and macrophages

Using lymph node T cells from poly-L(Tyr,Glu)-poly-D,L-Ala--poly-L-Lys[(TG)-A--L]-primed animals and B cells from animals primed with trinitrophenylated (TNP) protein or lipopolysaccharide, we have obtained anti-TNP-(TG)-A--L direct plaque-forming responses in vitro. Response to this antigen was shown to be controlled by the H-2 haplotype of the animal studied. The strain distribution of in vitro response was very similar to that previously reported by others for in vivo secondary IgG responses to (TG)-A--L. We investigated the cell types expressing the Ir gene(s) for (TG)-A--L in our cultures. F1, high responder x low responder mice were primed with (TG)-A--L. Their T cells were active in stimulating anti-TNP-(TG)-A--L responses of high responder but not low responder B cells and macrophages (MPHI), even though both preparations of B cells and Mphi were obtained from mice congenic at H-2 with one of the parents of the F1. For three low responder strains tested, of the H-2h2, H-2k, and H-2f haplotypes, the anti-TNP-(TG)-A--L response of low responder B cells and Mphis in the presence of high responder, F1 T cells could not be improved by the addition of high responder, antigen-bearing Mphis to the cultures. In one strain of the H-2a haplotype, it was shown that neither the B cells nor Mphis could be functional in anti-TNP-(TG)-A--L responses. Our results therefore suggested the Ir genes for anti-TNP-(TG)-A--L responses were expressed at least in B cells in all the low responder strains we studied, and, in mice of the H-2a haplotype, in Mphis too.

Expression of a single major histocompatibility complex locus controls the immune response to poly-L-(tyrosine, glutamic acid)-poly-DL-alanine-poly-L-lysine

Genetic control of the immune response linked to the major histocompatibility (H-2) complex in the mouse has been described for synthetic polypeptide antigens and for low doses of native proteins. The phenomenon is well documented(1,2). Extensive screening of intra-H-2 crossover-derived recombinant strains has localized H-2-linked immune response (Ir) genes to the I-immune response region of the H-2 complex (3). For most antigens, Ir genes are autosomal, dominant, and they segregate as single loci. It is not known whether these crossover-defined loci respresent single genes with multiple alleles or clusters of tightly linked genes (4). In 1972, Stimpfling and Durham (5) postulated that two interacting loci within the H-2 complex were required for the response to the alloantigen, H-2.2 (6), and, in 1975, Dorf et. al. (7) observed a responder phenotype in a recombinant derived from two strains which were nonresponders to the synthetic linear terpolymer, L-glutamic acid, L-lysine, L-phenylaline (GLPhe). Analysis of additional recombinants and complementation tests with F(1) hybrids clearly demonstrated that genes in two intra-I-region loci controlled the immune response to GLPhe. Subsequently, requirement for genes mapping in two intra-I-region loci were reported for porcine LDH(B)(8), the alloantigen Thy-1.1 (9), and for the synthetic terpolymers L-glutamic acid, L-lysine, L-tyrosine and L-glutamic acid, L-lysine, L- leucine (6,10). Demonstration that responses to both synthetic polypeptide and native protein antigens can be controlled by genes in two distinct I-region loci prompted speculation that the phenotypic expression of two I-region genes is a general phenomenon which may provide the key for understanding the mechanism of Ir gene function and cellular collaboration in the immune response. Benacerraf and Dorf (10) have shown that Ir gene complementation is often more effective in the cis than in the trans configuration. This concept is further supported by the data reported for GLPhe (10-12) which indicate that both of the complementing genes must be expressed in each of the cell types participating in the interaction. Failure to detect complementation for the majority of antigens under H-2-linked Ir-gene control might be attributed to the limited number of available intra-I- region recombinant strains.

Complexity of cell interactions: analysis using antigens under Ir gene control

The properties of three I region associated immunoregulatory factors involved in cell interactions are described. These are antigen specific T helper factor, suppressor factor produced by metabolically active T cells and genetically restricted factor, which is produced by macrophages and is involved in T helper cell induction. The use of these factors to analyse cell interactions is discussed.

Idiotype suppression by maternal influence

In BALB/c mice, antibodies to the alpha-(1-3) glucosidic linkage of some dextrans (Dex) carry the idiotype of the BALB/c myeloma protein J558. Both specific antibody and idiotype are inherited in a dominant fashion, linked to the immunoglobulin (Ig) (heavy chain) allotype Igla of BALB/c mice (Eur. J. Immunol. 1975. 5: 775). In F1 hybrid mice from the parent strains SJL and BALB/c, we were able to suppress the expression of anti-Dex antibodies by immunizing prospective SJL mothers to the J558 idiotype. The state of suppression in the progeny was ascertained by immunization with Dex, and tests for the following were carried out: (a) antibodies specific for Dex; (b) inhibition of such antibodies (if present) by antiidiotypic serum to protein J558; (c) presence of the J558 idiotype; and (d) concentration of lambda1 chains (which are associated with the 558 idiotype) in the serum. SJL mothers, once immunized, conferred suppression upon several successive litters, spanning a period of 4-5 months. Suppression in F1 progeny animals lasted for 16 weeks or more. Spleen cells from suppressed F1 mice which had neither been treated with Dex nor with J558 protein, were able to confer suppression to further F1 newborn mice.

In vitro studies on H-2-linked unresponsiveness to synthetic polypeptides. III. Production of an antigen-specific T helper cell factor to (T,G)-A--L

The in vitro production, assay and partial characterization of an extremely potent antigen-specific T helper cell factor to poly-L-(Tyr, Glu)-poly-DL-Ala--poly-L-Lys [(T,G)-A--L] which may be an important physiological mediator of T cell function in vivo is described. The factor has an antigen-binding site, Ia and Ig-like determinants on the same molecular complex. The response to (T, G)-A--L is under H-2-linked Ir gene control, some but not all low responder haplotypes will produce the factor.

Suppressor cell induction in vitro. III. Antigen-specific suppression by supernatants of suppressor cells

Antigen-specific suppressor T cells induced in vitro release, after a further period of culture in vitro with antigen factors into the supernatant which have suppressor activity. These suppressor factors (SF) have the same antigen specificity as the suppressor cells (SC). SF only works on the early phase of thymus-dependent responses in cultures. SF inhibits thymusdependent IgM, but not thymus-independent IgM responses in vitro. SF is is destroyed by proteolytic enzymes, and inactivated at 80 degrees C for 30 min. The release of SF from SC is dependent on the presence of antigen and metabolically active cells.

The immune response of allophenic mice to the synthetic polymer L-glutamic acid, L-lysine, L-phenylalanine. II. Lack of gene complementation in two nonresponder strains

The genetic control of the immune response of inbred strains of mice to certain antigens has been demonstrated to be governed by a set of Ir genes linked to the major histocompatibility complex (H-2) of mice (1,2). Until recently, the control was thought to be governed by single, dominant genes, located within the I region of the H-2 complex. Merryman et al. (3) originally demonstrated that the immune response to the synthetic terpolymer L-glutamic acid, L-lysine, L-phenylaline (GLphi) is under dominant, H-2-linked Ir gene control (4-7). This was shown both by crossing two nonresponder parental strains to produce responder offspring in the F(1) generation, and by the analysis of appropriate recombinant stains of mice. The two complementing genes have been mapped in the IA and IC regions of the H-2 complex, and have been termed beta and alpha, respectively (5,6). Thus, any strain of mouse may contain neither, one, or both genes. Only mice containing both genes are capable of responding to GLphi. It has been shown using F(1) hybrid and recombinant strains of mice, that the alpha- and beta-genes can complement each other in either the cis (on the same chromosome) or in the trans (on different chromosomes) position (8). In this paper we report the results of studies aimed at answering the question of whether or not the alpha- and beta- genes can complement each other when they are present in different lymphoid cells. To this end we have constructed allophenic mice composed of two nonresponder strains (A and C57BL/6), which show gene complementation in the F(1) generation. Allophenic mice are chimeras containing two cell types coexisting in a "normal" environment. The mice were tested for the specific cellular composition of the two parental cell types and were found to possess a complete range in the relative proportion of the two cell types. This report demonstrates that regardless of the mixture of cell types present in the allophenic mice, none of them were responders to GLphi. Thus no complementation of the alpha- and beta-genes is seen when the two genes are present in different cells.

In vitro studies on H-2 linked unresponsiveness. 1. Normal helper cells to (T,G)-A-L and GAT in low and non-responder mice

Lymphoid cells from unprimed high responder (C57BL/10) and low responder mice (B10.Br, B10.A, CBA) to (T,G)-A-L and high responder (B10, B10.A) and non-responder (B10.G, DBA/I) mice to GAT can be induced to form antigen specific T-helper cells in vitro under identical culture conditions. The helper cells induced from high and low or non-responder mice appear to be identical in efficiency, antigen concentration requirement for induction and induction kinetics.

Products of the major histocompatibility complex and their relationship to the immune response

The genes of the major histocompatibility complex were first known for the part they played in transplant rejection. Recently, however, it has become clear that the products of that region have an important part to play in the control of the immune response, through their effects both on cooperative and on aggressive interactions between cells. It is now possible to guess at the mechanisms which may underly the association of some major histocompatibility antigens with disease.

Specific enrichment of antigen-binding receptors from sensitized murine lymphocytes

Splenic T and B lymphocytes from sensitized mice were adsorbed to antigen-coated nylon discs and realesed from the discs by temperature shift as described by Kiefer, H., (Eur. J. Immunol. 1973. 3: 181 and 1975. 5:624). After cell release, lymphocyte-derived antigen-binding material could be recovered from the discs. A major fraction of the activity (70 -80%) binds to anti-immunoglobulin immunosorbents. A minor fraction does not detectably cross-react with gamma, mu, alpha and kappa immunoglobulin poly-peptide chains. When filtrated through Sephadex G-200, the bulk of activity of both fractions elutes in the region of 7 S serum antibody. However, as demonstrated for (4-hydroxy-3-nitro-phenyl)acetyl (NP)-binding material from C57BL/6 lymphocytes, the average affinity for antigen of the two fractions is drastically lower than that of humoral antibody, and the average affinity of the minor fraction is lower than that of the major fraction. The fraction of lymphocyte-derived antigen-binding material that does not adsorb to insolubilized anti-immunoglobulin serum was found to be proportional to the fraction of T lymphocytes in the input cell population and may therefore represent antigen-binding T lymphocyte surface receptors.

Control of t-lymphocyte and B-lymphocyte activation by two complementing Ir-GLphi immune response genes

The possibility that the two complementing alpha- and beta-Ir-GLphi genes are independently responsible for controlling events in T lymphocytes and B lymphocytes, respectively, has been tested in double adoptive transfer experiments utilizing cells from appropriate inbred strains of mice. The results of these studies show that the functions of T lymphocytes and B lymphocytes and the cooperative interactions between T and B cells require the presence of both alpha- and beta-genes in each respective cell type. Moreover, evidence has been obtained in these studies that indicates a preference for the alpha- and beta-Ir-GLphi genes in the cis position to obtain the most effective T-B-cell interactions. The possible implications of these findings are discussed.

Suppression of IgE antibody production in SJL mice. I. Nonspecific suppressor T cells

High titer and persistent antihapten IgE production in SJL mice can be obtained using appropriate immunization and radiation. Nonirradiated mice rapidly terminate this antihapten IgE production. Radiation was not necessary to prolong antihapten IgE production in other strains of mice. Termination can be obtained even in irradiated SJL mice by transferring normal SJL spleen cells. That the suppressor cells are T cells is shown by using thymocytes or cells treated with anti-Thy 1.2 and complement. No appreciable suppressive effect by normal spleen cells could be demonstrated on IgG1 production in SJL mice. The characteristic of low and transient IgE antibody response in SJL mice is inherited as a recessive trait controlled by a single Mendelian autosomal gene and is not linked to the H-2-gene complex. This characteristic does not depend on the infectivity of Nippostrongylus brasiliensis, the effect of anticarrier antibody, or the recognition of antigen.

In vitro proliferative reactions by lymphocytes from both responder and "low" responder mice to (T,G)-A--L

In summary (T,G)-A--L can induce specific in vitro lymphoproliferative reactions in LNC from immunized mice. From 3-8 weeks after immunization lymphocytes from responder mice react to a much greater degree than from low responders. These proliferative reactions are not specifically enhanced by supernatants of "educated" T cells. However, 2 to 3 months after immunization the lymphoproliferative response of the low responders rises to the same level as that of responder mice.

The role of receptors for T cell products in antibody formation

Immunocompetent cell interactions are achieved via direct contact between functionally different cell types or via interactions between soluble factors elaborated by regulatory T cells and specific receptors on responding cells for the T cell factors. In either case, there exist certain restrictions with respect to the effective interactions, which depend on the state of differentiation and genetic background of the responding cell type. Such restrictions are considered to be mainly determined by the development and nature of the receptor site on responding cell types for different T cell factors, which is now refered to the "acceptor" for the T cell factors. The presence of such acceptor sites on different populations of both T and B cells has been demonstrated in various experimental systems, and they are now considered to be the site by which responding cells receive appropriate signal for destination of their further differentiation. We have tried to review the nature and possible role of acceptor sites on both B and T cells for different T cell factors with respect to the induction and regulation of immune responses. A special emphasis was put on the genetic nature of the acceptor site. The observed genetic restrictions in the acceptance of T cell factors by responding cells suggest that such restrictions are needed for meaningful and unmistakable communications between funcionally different immunocometent cells. Furthermore, the presence or absence of acceptor sites for certain T cell factors is supposed to be a very important factor for determination of the immune responsiveness of animals against certain antigens, and thus in some cases the Ir gene effect may predominantly affect the expression of acceptor site. Possible implications of acceptor site in the regulation of antibody response and in the network of immunocompetent cell interactions are discussed.

Antigen-specific T-cell factor in cell cooperation. Mapping within the I region of the H-2 complex and ability to cooperate across allogeneic barriers

Further mapping of the mouse T-cell factor specific for poly(Try,Glu)-polyD-LAla--polyLys is reported. It is shown to be a product of the I-A subregion of the H-2 complex by the use of antisera either raised specifically against or made specific, by absorption, for different regions of the H-2 complex. The factor cooperates across allogeneic barriers, e.g., when factor produced by one strian is combined with bone marrow cells of other H-2 incompatible strains.