Immune response genes in inbred rats. II. Segregation studies of the GT and GA genes and their linkage to the major histocompatibility locus

Genetic analysis of the high responder-non-(or low) responder differences between WF and ACI rats to the synthetic copolymers GT and GA established singleIr-genes for both antigens and dominance for high responder status.Ir-GT andIr-GA are linked to the major histocompatibility locus. It could be demonstrated that only T cells carrying the high responderIr-GT gene undergo in vitro blast transformation to GT. The advantages of the rat systems for further studies of the regulatory role ofIr-genes on the cellular level are discussed.Abbreviations cpm counts per minute - DHR delayed hypersensitivity reaction - GA random synthetic copolymer of L-glutamic acid⁵⁰, L-alanine⁵⁰, M.W. 45,000 - GT random synthetic copolymer of L-glutamic acid⁵⁰, L-tyrosine⁵⁰, M.W. 22,000 - Ir gene immune response gene - MLC mixed lymphocyte cultures - LDH lactic dehydrogenase - (T,G)-A-L branched chain synthetic polymer of poly-L (tyrosine, glutamic acid)-poly-D, L-alanine-poly-L-lysine Rat Strains ACI ACI/MaI - WF Wistar Furth - AUG August 28807/Cr     

Genetic control of IgM responses to (T,G)-A — L

The primary antibody response to aqueous immunization with a low molecular-weight lot of (T,G)-A — L (#420) was studied in congenic pairs of inbred mouse strains. Two new genetic controls were identified, both of which quantitatively regulate the production of IgM anti-(T,G)-A — L antibody. Testing of F₁ and F₂ progeny demonstrated that one of these genes is linked to the major histocompatibility (H-2) complex, and that high response is dominant over low response. Whether this gene is identical toIr-1A is not yet known. The other gene, designatedIg-TGAL _M , is linked to the immunoglobulin heavy-chain allotype locus (Ig-1) and is expressed in a genedose dependent manner. Following secondary challenge with (T,G)-A — L 420, quantitative differences in IgG antibody response were observed inIr-1A high-responder congenics differing only at theIg-1 locus. Breeding studies, however, failed to demonstrate any linkage between this locus and the quantitative control of IgG anti-(T,G)-A — L antibody. These data demonstrate thatH-2-linked immune response genes can regulate IgM as well as IgG antibody responses, that genetic control of the IgM response to (T,G)-A — L is linked toIg-1, and that bothH-2-linked andIg-1-linked genes may simultaneously affect an IgM antibody response to the same antigen.Abbreviations used in this paper are (T,G)-A — L poly-l-(Tyr,Glu)-poly-d,l-Ala-poly-l-Lys - NMS normal mouse serum - SRBC sheep red blood cells - i.p. intraperitoneal - PBS phosphate-buffered saline - RAMG polyvalent rabbit anti-mouse globulin - 2-Me 2-Mercaptoethanol - 2-MeS 2-Me-sensitive - PFC plaque-forming cells - ABC antigen-binding cells     

Antigen-Specific T-cell factors in the immune response to poly(Tyr,Glu)-poly(Pro)-poly(Lys)

The production by T cells of an antigen-specific factor capable of replacing the T-cell function in specific antibody formation was used as a tool for studying the cellular aspects of the genetic control of immune responses. The ability of different T-cell populations to produce a cooperative signal and the ability of B-cell populations to react to this signal were studied in different mouse strains. The antigen used was the synthetic polypeptide poly(LTyr,LGlu)-poly-(LPro) —poly(lXys), (T,G)-Pro -L, the response to which was found not to beH-2-linked. It was found that the SWR strain of mice, a low responder to (T,G)-Pro -L, is not capable of producing a T-cell factor specific to this antigen, but its B cells react normally to an active factor produced in a high responder strain. In the DBA/1 strain, also a low responder to (T,G)-Pro -L, the bone marrow cells are not able to cooperate with an active T-cell factor to produce anti-(T,G)-Pro —L-specific antibodies, while their T cells do produce a (T,G)-Pro -L-specific factor. The SWR (low responder) B cells can be triggered by DBA/1 (low responder) T cells factor specific to (T,G)-Pro —L to produce an antibody response to this immunogen. These results suggest that the immune response to (T,G)-Pro -L is controlled by two genes which are expressed in different lymphocyte populations.     

Genetic control of immune responsiveness to poly (LPro)--poly (LLys)-derived polypeptides by histocompatibility-linked immune response genes in the rat.

In rats responsiveness to branched synthetic polypeptides carrying a Pro--L backbone, such as (T,G)-Pro--L or (Phe,G)-Pro-L and to Pro--L itself is controlled by Ir genes which are linked to the major histocompatibility genes. The level of antibody production to these polypeptides does not fall into strict high or low responder categories but covers the range in between. (T,G)-pro--L and Pro--L elicit a very similar response pattern which, however, differs from that obtained with (Phe,G)-Pro--L. Anti-(T,G),Pro--L antibodies do not cross-react with (T,G)-A--L, but do so extensively with Pro--L. Anti-(Phe,G)-Pro--L antibodies show cross-reactivity to (Phe,G)-A--L only when the antibody-producing strain is a high responder to (Phe,G)-A--L. These results when considered in view of data obtained in mice on genetic control of the immune response to (T,G)-Pro--L suggest that at least two unlinked Ir genes are involved in controlling anti-Pro--L responsiveness.     

One I region restriction determinant can associate with multiple antigenic epitopes

Studies presented in this paper show that T cell clones recognizing different epitopes of multideterminant antigens can be restricted by the same I-A molecule. These data further support the concept that a single I-A restriction site can present more than one antigenic epitope. This concept was supported by data on the proliferation of T cell clones reactive with either poly(L-Glu60, L-Ala30, L-Tyr10)n(GAT) or poly(Tyr, Glu)-poly D,L-Ala--poly Lys [(T,G)-A--L] which recognized different epitopes on these multideterminant antigens. Two clones recognizing different epitopes on the same multideterminant antigen can be blocked by the same monoclonal anti-I-A antibody. Additionally, the mutation in the Abm12 chain utilized in [B6.C-H-2bm12(bm12) X B10.A(4R)]F1 mice can affect the restriction determinant of clones recognizing different antigenic epitopes. These results suggest that in the strictest sense, the determinant selection theory is not tenable and would support the concept that T cell specificity is controlled by the T cell repertoire.     

Genetic control of T-cell proliferative responses to poly(glu40ala60) and poly(glu51lys34tyr15): Subregion-specific inhibition of the responses with monoclonal Ia antibodies

The relationship betweenIr genes and Ia antigens was studied in the T-cell proliferative responses to two synthetic polypeptides poly(glu⁴⁰ala⁶⁰) (GA) and poly(glu⁵¹lys³⁴tyr¹⁵) (GLT¹⁵). The response to GA was found to be controlled by anIr gene in theI-A subregion, whereas the anti-GLT¹⁵ response was shown to be under dual control, oneIr gene mapping probably in theI-A subregion, and the other in theI-E subregion. We obtained two different lines of evidence suggesting identity ofIr and Ia genes. First, the presence of certain serologically identified allelic forms of the I-A-encoded A molecule correlated with the responder status to GA both in inbred strains and in B10.W lines, the latter carrying wild-derivedH-2 haplotypes. Thus the Ir and Ia phenotypes were not separable in strains of independent origin. Second, the anti-GA response was completely inhibited by monoclonal antibodies against determinants on the A molecule (Ia.8, 15, and 19), but not by a monoclonal antibody against a determinant on the E molecule (Ia.7). In contrast, the anti-GLT¹⁵ response was only inhibited by a monoclonal antibody against the E molecule, but not by antibodies against the A molecule. Our data support the hypothesis that Ia antigens, as restriction elements for T-cell recognition, may in fact be the phenotypic manifestation ofIr genes.     

Functional requirements of (Phe,G)-A--L-specific T-cell clones of (H-2 b x H-2 kF1 origin

T-cell clones specific for the synthetic polypeptide antigen poly(LPhe, LGlu)-poly(DLAla)--poly(LLys) of (C57BL/6 x C3H/HeJ)F₁ origin were tested for their biological activities. One group of clones was restricted in its proliferative response to the H-2 ^b haplotype, the second to the H-2 ^k haplotype, and the third to the F₁ unique Ia determinants. All the clones which proliferated in response to antigen secreted interleukin-2 (IL-2) following stimulation. The H-2 restriction of the IL-2 secretion was the same as that of the proliferation. Two of the clones tested, C.6 and C.10, could provide help to B cells in antibody production. However, the genetic restriction profile of the helper activity was less stringent than that for the proliferative response. Thus, C.6, which proliferated in the presence of F₁ antigen-presenting cells only, could help B cells and accessory cells of C3H/HeJ. C.10, which was restricted in its proliferative response to the H-2 ^b haplotype, could collaborate with B cells and accessory cells of the H-2 ^k haplotype as well. The antibody response of both clones was restricted to the parental or F₁ strains.Abbreviations used in this paper (T, G)-A-L poly-(LTyr, LGlu)poly(DLAla)--poly(LLys) - (Phe, G)-A--L poly(LPhe, LGlu)-poly(DLAla)--poly(LLys) - APC antigen-presenting cells - Con A concanavalin A - FCS fetal calf serum - IL-2 interleukin-2     

Carrier design: Conformational studies of amino acid (X) and oligopeptide (X-DL-Alam) substituted poly(L-lysine)

The present study was undertaken to examine the influence of the reversal of the sidechain sequential order on the conformation of branched polypeptides. At the same time, the influence of the optically active amino acid joined directly to the poly (L -Lys) backbone and the DL -Ala oligomer grafted as chain-terminating fragment were separately analyzed. Therefore two sets of polypeptides were synthesized corresponding to the general formula poly [Lys-(X_i,)] (XK) and poly[Lys-(DL -Ala_m-X_i)] (AXK) when X = Ala, D -Ala, Leu, D -Leu, Phe, D -Phe, Ile, Pro, Glu.,D -Glu, or His. For coupling amino acid X to polylysine, three types of active ester methods were compared: the use of pentafluorophenyl or pentachlorophenyl ester, and the effect of the addition of an equimolar amount of 1-hydroxybenzotriazole. After cleavage of protecting groups, AXK polypeptides were synthesized by grafting short oligo (DL -Ala) chains to XK by using N-carboxy-DL -Ala anhydride. The CD measurements performed in water solutions of various pH values and ionic strengths were used for classification of the polypeptide conformations as either ordered (helical) or unordered. Different from what was observed with the unsubstituted poly (L -Lys), poly[Lys-(X_i)] type polypeptides can adopt ordered structure even under nearly physiological conditions (pH 7.3, 0.2M NaCl). These data suggest that the introduction of amino acid residue with either (ar) alkyl side chain (Ala, Leu, Phe) or negatively charged side chain (Glu) promotes markedly the formation of ordered structure. Comparison of chiroptical properties of poly [Lys- (DL -Ala_m-X_i)] and of poly [Lys- (X_i)] reveals that side-chain interactions play an important role in the stabilization of ordered solution conformation of AXK type branched polypeptides. The results give rather conclusive evidence that not only hydrophobic interactions, but also ionic attraction, can be involved in the formation and stabilization of helical conformation of branched polypeptides. © 1993 John Wiley & Sons, Inc.     

Genetic control of the primary humoral response to Glu56Lys35Phe9

The primary humoral responses of mice to the linear random terpolymerl-Glu⁵⁶-l-Lys³⁵-l-Phe⁹ (GLø) were studied, utilizing the Farr antigen-binding technique and a new hemagglutination assay. This new hemagglutinin assay was easier and more convenient than the conventional Farr method, and was more sensitive in detecting early IgM responses. Following primary immunization, the majority of antibodies produced by responder strains were 2-ME-sensitive. These 2-ME-sensitive antibodies chromatographed at the same relative position as IgM on a Sepharose 6B column. On the other hand, no antibodies of either the IgM or IgG class could be detected in nonresponder strains. These data are consistent with the hypothesis that two complementingIr genes are required for the primary IgM response to GLø, in contrast to findings previously reported for (T,G)-A — L, anotherH-2-linked, complementing,Ir gene system. The implications of these differences are discussed.     

Humoral immune response of asymptomatic cats naturally infected with feline leukemia virus

The humoral immune response of cats that were naturally infected with the feline leukemia virus (FeLV) was examined after antigenic stimulation with the synthetic antigen poly(L-Tyr, L-Glu)-poly(DL-Ala)-poly(L-Lys). The primary humoral antibody response in FeLV-infected cats was both delayed and greatly reduced, compared with that seen in uninfected control cats. A similar discordance was observed after secondary stimulation with the antigen, in the FeLV-infected cats had both a delayed response and a reduced response, compared with uninfected cats. The levels of total immunoglobulins of the immunoglobulin G and immunoglobulin M classes in the sera of FeLV-infected cats were significantly higher (two- and threefold, respectively) than were those of the uninfected control animals. The presence of an impaired humoral immune response to newly presented antigens in the presence of elevated immunoglobulin levels has been thoroughly documented in the case of people with the acquired immunodeficiency syndrome. This further emphasizes the potential value of FeLV-infected cats as a model for human acquired immunodeficiency syndrome.     

Molecular events in the processing of avidin by antigen-presenting cells (APC)

The immune response of T lymphocytes to avidin was measured by proliferative assays, antibody production and delayed-type hypersensitivity. Mice ofH-2 ^k haplotypes were found to be low responders, whereas mice of other haplotypes, and particularly ofH-2 ^s , were high responders.Ir genes controlling this response were mapped to theI subregion ofH-2. Helper T cells were found to be responsible for the Ir phenotype of antibody production. These results indicate the feasibility of using the avidin-biotin complex as a tool for studying molecular mechanisms by which antigens underIr gene control are processed and presented to T lymphocytes.Abbreviations used in this paper Ir genes, immune-response genes - H-2 murine major histocompatibility complex - APC antigen-presenting cell - OA ovalbumin - BSA bovine serum albumin - DNP dinitrophenyl - DNP-OA DNP-ovalbumin - DNP-Av DNP-avidin - DNP-BSA DNP-bovine serum albumin - CFA complete Freund's adjuvant - PPD purified protein derivative - PBS phosphatebuffered saline - IP intraperitoneal - LNC lymph-node cells - DTH delayed-type hypersensitivity     

Antigen-specific T cell factors: a fine analysis of specificity.

The specificity of T cell factors produced in presence of synthetic polypeptide antigens was studied. Factors prepared with either one of the three antigens: poly(Tyr,Glu)-poly(DLALa)--poly(Lys), (T,G)-A--L, poly(Phe,Glu)-poly(DLALa)--poly(Lys), (Phe,G)-A--L, and poly(His,Glu)-poly(DLALa)--poly(Lys), (H,G)-A--L, successfully cooperated with B cells for antibody production to the homologous as well as to the other two immunogens. Furthermore, the activity of a (T,G)-A--L-specific factor was removed after passage through immunoadsorbents built of Sepharose coupled to: (T,G)A--L, (Phe-G)-A--L and poly(Glu)-poly(DLAa)--poly(Lys), (G)-A--L, but not to poly (DLALa)--poly(LLys),A--L. No cross-reactivity was observed between (T,G)-A--L and poly(Tyr,Glu)-poly(Pro)--poly(Lys), (T,G)-Pro--L, at the level of T cell factors, as shown using the above approaches. These results lead to the conclusion that specificity of T cell factors, although not identical, is similar to that of antibodies.     

Characterization and biologic activities of an anti-idiotype-specific T cell line and its derived clones

Monoclonal anti-idiotypic antibodies were prepared against monoclonal antibodies (mAb103) specific to the synthetic polypeptide antigen (T,G)-A-L. A cell line was established by the stimulation of C3H.SW mouse T cells with one of the monoclonal anti-idiotypes (mAbA-6) that reacted with both mAb103 and conventional (T,G)-A-L-specific antibodies. The T cell line proliferated specifically in the presence of the homologous mAbA-6 and to a lesser degree when triggered with (T,G)-A-L. The line could help (T,G)-A-L primed B cells in the production of (T,G)-A-L-specific antibodies when stimulated in vitro with either (T,G)-A-L or mAbA-6. Clones obtained from the line were stimulated and maintained in culture in presence of mAbA-6 whereas others were stimulated and grown in the presence of (T,G)-A-L. Both types of clones proliferated only in the presence of mAbA-6 although (T,G)-A-L could inhibit efficiently and specifically the latter proliferation. A significant number of the (T,G)-A-L-stimulated clones could collaborate with (T,G)-A-L primed B cells in the presence of either (T,G)-A-L or mAbA-6 for the production of specific antibodies. Immunoblotting experiments indicated that mAbA-6 reacted with both the T cell receptor of the mAbA-6-specific T cell line and of a (T,G)-A-L-specific T cell line but not with that of a line specific to a nonrelated antigen.     

Selective expression of murine lymphocyte alloantigens controlled by the X-chromosome

Alloantisera specific to X-chromosome linked lymphocyte membrane antigens (Ly-X) were prepared by immunizing F1 male mice with identical F1 female lymphocytes. Independent B cell specific (anti Lyb-X) and T cell specific (anti Lyt-X) antibodies were detected. The Lyt-X antigen was expressed on Lyt-2⁺, 3⁺, and on Tla^–, Lyt-1⁺, 2⁺, 3⁺ T cell subpopulations. The problem of X-chromosome inactivation and the relationship ofH-2-linkedIr genes and Ia antigens, with X-linkedIr genes and lymphocyte alloantigens are discussed.     

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.     

Antigenic competition and genetic control of the immune response. A hypothesis for intramolecular competition

A study has been made of antigenic competition between the (Phe,Glu) and Pro-Lys regions of three synthetic multichain polypeptides, (Phe,Glu)-Ala-Lys, (Tyr,Glu)-Pro-Lys and (Phe,Glu)-Pro-Lys. Two strains of mice have been compared, C3H/HeJ, potentially high responders to both (Phe,Glu) and Pro-Lys, and DBA/1, high responders to (Phe,Glu), but genetic low responders to Pro-Lys. In C3H/HeJ, both intramolecular competition, within the (Phe,Glu)-Pro-Lys molecule, and intermolecular competition, with mixtures of (Tyr,Glu)-Pro-Lys and (Phe,Glu)-Ala-Lys occur. In general, Pro-Lys is the dominant determinant and suppresses the response to (Phe, Glu). In DBA/1, on the other hand, intramolecular competition is absent, but intermolecular competition is still present. The injection of the polyribonucleotide poly (A)·poly (U) corrects the low response to Pro-Lys in DBA/1, and at the same time restores intramolecular competition. Intramolecular competition is, therefore, related to the level of the antibody response to the dominant antigenic region, Pro-Lys. In contrast, intermolecular competition is independent of the antibody response to Pro-Lys, but is related to the ratio of the antigens (Tyr,Glu)-Pro-Lys and (Phe,Glu)-Ala-Lys in the mixture injected.A model is suggested in which intramolecular competition is a result of competition between specific B cells for limiting antigen. The model relates competition to original antigenic sin and the enhancement and suppression mediated by antibody. Intermolecular competition seems to have a different mechanism and to be a T cell effect. The relevance of these findings to studies on the genetic control of the immune response is discussed.     

Cellular analysis of the phenotypic correction of the genetically controlled low immune response to the polyproline determinant by macrophages

SJL mice are high responders to the polyproline region of poly(Tyr,Glu) -polyPro-polyLys, (T,G)-Pro-L and of poly (Phe,Glu) -polyPro-polyLys, (Phe,G)-Pro-L, whereas DBA/1 mice are the low responders to this moiety. The low responsiveness of DBA/1 mice to polyproline could be enhanced by immunization with (T,G)-Pro-L 4 days after stimulation of peritoneal cells by thioglycolate. The same effect was observed when DBA/1 mice were immunized with 10⁷ syngeneic peritoneal exudate cells (PEC) preincubated in vitro with the immunogen. Similar treatments of SJL mice did not enhance the high response to polyproline, nor did it enhance low responses to other synthetic polypeptides tested.The enhancing effect of PEC on immunocompetent cells was established by transferring graded numbers of spleen cells together with 10⁷ PEC into irradiated syngeneic DBA/1 recipients. The effective cell type in the PEC was found to be the macrophage as the same results were observed with the adherent-cell population. Furthermore, the effect was not abolished after in vitro irradiation of PEC with 5000 R or by anti-θ treatment. In vivo irradiation of the PEC donors 2 days before the cells were harvested also did not influence the phenotypic correction of the low responsiveness.Transfer experiments in which graded inocula of either marrow cells or thymocytes from DBA/1 donors were transferred into syngeneic recipients in the presence of an excess of the complementary cell type together with PEC indicated that the enhancing effect was reflected in the bone-marrow-cell population only.     

I-A Mutation resulted in a selective loss of an antigen-specific Ir gene function

The immune responses to several antigens were compared in the I-A mutant mouse strain B6.C-H-2^bm12 and the wild-type strain C57BL/6. With a lymph node cell proliferation assay, the response to two of these antigens, beef insulin and (TG)A-L, was demonstrated to be controlled by a gene in the I-A^b region. B6.C-H-2^bm12 mice failed to respond to beef insulin, while their responses to (TG)A-L, DNP-OVA and PPD were comparable with those of the wild-type strain C57BL/6. Taken together with previous studies, these data suggest that the product of a single pleiotropic I-A gene, an la molecule, functions as a histocompatibility, la, and MLR antigen, as well as a necessary component for Ir gene function. Furthermore, the data reported here demonstrate that la molecules have multiple functional “Ir determinants,” one of which has been altered in the B6.C-H-2^bm12 mutant. The B6.C-H-2^bm12 mice, therefore, represent a powerful analytical tool for the understanding of the cellular and molecular basis for Ir gene control of the immune response.     

H-2 effects on cell-cell interactions in the response to single non-H-2 alloantigens

Immune response (Ir) genes mapping in theI region of the mouseH-2 complex appear to regulate specifically the presentation of a number of antigens by macrophages to proliferating T cells. We have investigated the possibility that similarIr genes mapping in theH-2K andH-2D regions specifically regulate the presentation of target antigens to cytotoxic effector T cells. We report that the susceptibility of targets expressing specific non-H-2 H alloantigens to lysis by H-2-compatible, H-antigen-specific cytotoxic effector T cells is controlled by polymorphicH-2K/D genes. This control of susceptibility to lysis is accomplished through what we have defined operationally as antigen-specific regulation of non-H-2 H antigen immunogenicity. High immunogenicity of the H-4.2 alloantigen is determined by a gene mapping in theH-2K region ofH-2 ^b . However, high immunogenicity of H-7.1 is determined by a gene mapping in theH-2D region ofH-2 ^b . High immunogenicity of the H-3.1 alloantigen is determined by genes mapping in both theH-2K andH-2D regions ofH-2 ^b . Therefore, genes mapping in theH-2K andH-2D regions serve a function in presenting antigen to cytotoxic effector T cells. This function is analogous to that played byI-regionIr genes expressed in macrophages which present antigen to proliferating T cells. We present arguments for classification of theseH-2K/D genes as a second system ofIr genes and discuss the implications of twoH-2-linkedIr-gene systems, their possible functions, and their evolution.     

The influence of the side-chain sequence on the structure-activity correlations of immunomodulatory branched polypeptides. Synthesis and conformational analysis of new model polypeptides

New branched polypeptides were synthesized for a detailed study of the influence of the side-chain structure on the conformation and biological properties. The first subset of polypeptides were prepared by coupling of tetrapeptides to poly[L-Lys]. These polymers contain either DL-Ala3-X [poly[Lys-(X-DL-Ala3)n]] or X-DL-Ala3 [poly[Lys-(DL-Ala3-X)n] (n less than or equal to 1)] tetrapeptide side chains. Another group of branched polymers comprise a mixture of DL-Alam and of DL-Alam-X oligomeric branches in a random distribution [poly[Lys-(DL-Alam-Xi)] (i less than 1, m approximately 3)]. In each subset the X = Leu or Phe derivatives were prepared. The N-protected tetrapeptides were synthesized by conventional liquid phase methods and were coupled as active esters. The degree of racemization was found relatively high both for active esters and coupled derivatives, when optically active amino acids were in the C-terminal position of the tetrapeptides. In the case of the poly[Lys-(Leu-DL-Ala3)n] derivative, comparative experiments were carried out using various methodical alterations. The highest stereochemical homogeniety could be achieved when the tetrapeptide active ester was synthesized by the "backing off" method. CD spectra of poly[Lys-(Xi-DL-Alam)] (i less than 1, m approximately 3) and of poly[Lys-(X-DL-Ala3)n] were analyzed and compared to those of poly[Lys-(DL-Alam-Xi)] and of poly[Lys-(DL-Ala3-X)n]. All measurements were performed in water solutions of varying pH values and ionic strengths. The data obtained suggest that branched polypeptides containing a mixture of two different types of oligomeric side chains (DL-Alam and DL-Alam-Xi or Xi-DL-Alam) distributed randomly adopt an almost identical conformation to those that comprise only the respective tetrapeptide (DL-Ala3-X or X-DL-Ala3) branches. The results also indicate that the tendency to form an ordered structure is determined by the identity and the position of the chiral amino acid X (Phe or Leu) in the side chain.