Dissociation ofH-2 recognition by antibody and cytotoxic T cells of a cloned murine leukemia cell line

The differential expression of H-2 specificities recognized by antibody and by cytotoxic T lymphocytes (CTL) has been studied using a clone (FY7) of the C57BL/6 leukemia cell line FBL-3 (H-2 ^b /H-2 ^b ). Unlike C57BL/10 spleen cells, EL-4 lymphoma cells and Y57-2C leukemia cells (allH-2 ^b /H-2 ^b ), FY7 failed to induce the primary in vitro generation of anti-H-2^b CTL by (B10.A x A)F₁ (H-2 ^a /H-2 ^a or (B10.D2 x BALB/c)F₁ (H-2 ^d /H-2 ^d ) responder spleen cells. In addition, FY7 was not lysed by, and did not competitively inhibit anti-H-2^b CTL. Quantitative absorption tests with H-2K^b and H-2D^b antisera revealed that FY7 expressed these antigens in quantitatively similar amounts to EL-4. The H-2K^b product of FY7 appeared to be identical with that of C57BL/10 spleen cells both in apparent molecular weight and isoelectric point. Yet FY7 failed to inhibit anti-H-2K^b CTL competitively in a cold target inhibition assay. Possible mechanisms are discussed for the lack of T-lymphocyte recognition of the H-2K^b-gene product expressed by FY7.Abbreviations used in this paper CTL cytotoxic T lymphocytes - MHC major histocompatibility complex - MLC mixed lymphocyte culture - PAGE polyacrylamide gel electrophoresis     

A new cytotoxic lymphocyte-defined antigen coded by a gene closely linked to theH-3 locus

F₁ complementation results indicate that a new gene, putatively controlling a minor histocompatibility antigen, is closely linked to the minor histocompatibility gene,H-3, in the fifth linkage group of chromosome 2 of the mouse. This gene controls a product that was capable of inducing as well as acting as a target for cytotoxic lymphocytes (CTL). The lytic activity of CTL developed in B10.LP-H-3^b mice specific for the product of the new gene of B10 was restricted to target cells possessing H-2D^b antigens. This contrasts to the H-2K^b-restricted activity of H-3.1 specific CTL.     

Interacting genetic factors controlling the antibody response against the H-2.2 specificity

The antibody response against the H-2.2 specificity has been studied in three H-2 ^d strains, B10.D2, DBA/2, and BALB/c, and their hybrids (B10.D2 × DBA/2)F₁ and (B10.D2 × BALB/c)F₁. The genetic control of the response appears to be complex: The three pure strains are responders, whereas both hybrids when immunized with C3H-HTG are nonresponders. Individual analysis of N3 offspring is compatible with the idea that, in this combination, an Ea-4 incompatibility between donor and immunized strain is necessary for the anti-H-2.2 response to occur. H-2 ^d /H-2 ^k hybrids (B10.BR × B10.D2)F₁ or (B10.BR × DBA/2)F₁ are responders when immunized with C57BL/10 (H-2 ^b ) but not with B10.A(2R) (H-2 ^h ), indicating that simultaneously recognized H-2 specificities are necessary for the anti-H-2.2 response.     

Hybrid immune response to parental liver tissue grafts

Parental-to-F₁-hybrid liver tissue grafts in like-sex donor-recipient combinations survive indefinitely, although several F₁ recipients demonstrate an immunological response to the parental graft. Female F₁ recipients, particularly those carrying theH-2 ^b haplotype, respond vigorously to male parental liver grafts. However F₁ female responses to male parental liver tissue grafts differ substantively from the responses of parental females to syngeneic male grafts. C3H male liver grafts are rejected vigorously by F₁ females as long as the F₁ carries theH-2 ^b haplotype. These findings support previous reports of strong immunological responses to C3H H-Y antigen in female F₁ and C3H.SW animals, a response which is absent in C3H females. Female F₁ hybrids carrying theH-2 ^b haplotype do not reject grafts of B10 or B6 male liver as rapidly as do B10 or B6 parental females. This reduced F₁ response may be related to the formation of hybrid antigens and consequent alteration of the anti-H-Y response. Alternatively, cells that specifically suppress the anti-H-Y response may be present in F₁ hybrids. Factors responsible for suppression appear to be controlled by non-MHC antigens, at least in (OH x B6 or B10) F₁ hybrids.     

Immunogenetic analysis ofH-2 mutations

A.BY, B10.LPa, and B10.129(5M) mice were presensitized in vivo against B10.A(5R) cells and then restimulated in vitro by the same cells in the standard CML assay. The effector cells thus generated lysed not only B10.A(5R), but also C57BL/6 targets, indicating that, in addition to anti-H-2D_d response [measured on the B10.A(5R) targets], response to minor histocompatibility (H) antigens (measured on the C57BL/6 targets) also occurred. The latter response was directed against multiple minor H antigens in the case of the A.BY effectors, and against H-1 and H-3 antigens in the case of B10.129(5M) and B10.LPa effectors, respectively. The sensitization against minor H antigens occurred in the context of H-2K^b H-2D^d antigens, but by testing the response on C57BL/6 targets, only cells reacting with minor H antigens in the context of H-2K^b were assayed. The same effector cells were then tested against H-2^b mutant strains, in which theH-2K ^b allele was replaced by a mutant one. All three effector types [A.BY, B10.LPa, and B10.129(5M)] behaved in a similar way: they all reacted with theH-2 ^bg1 mutant to the same degree as withH-2 ^b, they did not react at all or reacted only weakly with theH-2 ^bd andH-2 ^bh mutants, and they reacted moderately or strongly with theH-2 ^ba mutant. The degree of crossreactivity with the mutants reflects, with one exception, the degree of relatedness of these mutants toH-2 ^b, as established by other methods. The one exception is theH-2 ^ba mutant, which is the most unrelated toH-2 ^b, and yet it crossreacted strongly. Further testing, however, suggested that in this instance the crossreactivity was probably directed against H-2 antigens: the anti-H-2D^d effectors apparently crossreacted with the H-2K^ba antigens. This finding is an example of cell-mediated crossreactivity between the products of two differentH-2 genes (H-2K andH-2D). It is also an example of anH-2 mutation generating an antigenic determinant known to be present in another strain.     

The regulation of immune responses to multiple non-H-2 antigens on tumor cells: I. Differential responses of BALB/c F1 hybrids to the P815 mastocytoma in vivo

Factors influencing host resistance to the growth of a tumor bearing many mismatched minor histocompatibility antigens (MiHA) were studied. BALB/c (H-2^d) and several of its F₁ hybrids were injected intraperitoneally with DBA/2 (H-2^d) P815 tumor cells. Compared to BALB/c, which was moderately susceptible, F₁ hybrids of BALB/c with CBA, AKR, C3H.OH, and BIO H-2-congenic strains were highly susceptible, whereas hybrids of BALB/ c with A, A.SW, and BALB.B strains were quite resistant. Susceptibility was observed only with the intraperitoneally injected tumor, since both BALB/c and (CBA x BALB/c)F₁ were resistant to the same tumor injected subcutaneously, and survival times of DBA/2 skin grafts did not differ between susceptible and resistant strains. Susceptibility was in part a function of the number of MiHA incompatibilities between tumor and host although the specific loci involved could not be identified. For example, susceptible (CBA x BALB/c)F₁ hybrids probably shared certain MiHA with DBA/2 which BALB/c lacked, and which therefore subtracted from the net antigenic strength of the tumor in the hybrid, compared to its strength in BALB/ c. This interpretation was supported by in vitro studies which confirmed that the susceptible hybrids shared more MiHA with DBA/2, than did the resistant hybrids. Resistance was at least partially regulated by the host H-2 genotype, as shown by the observation that (BALB/ c x BALB.B)F₁ (H-2^d/b) mice were significantly more resistant than BALB/c. Segregation studies of the resistant (BALB/c x A)F₁ hybrids, indicated that in addition to H-2, a nonH-2 gene in the A background was operating to confer resistance. Thus the factors influencing susceptibility to the MiHA-incompatible tumor were: (i) site of injection; (ii) the combined strength of the disparate MiHA; (iii) the host H-2 genotype; and (iv) at least one host nonH-2 gene conferring increased responsiveness.     

Antigen-specific helper T cells recognize determinants encoded in the H-2D region of the H-2 gene complex

Observations have frequently been interpreted as showing that the helper T cells which collaborate with alloantigen-specific cytotoxic T-cell precursors can only recognize antigens encoded in the I region of the H-2 gene complex. An experimental system is described here that allows analysis of the recognition repertoire of these helper cells. CBA helper T-cell precursors can be primed in vitro to antigens encoded in the H-2 ^b gene complex. These helpers can then be tested for the existence of a subset of helper cells which recognize antigens encoded in the D region of H-2 ^b haplotype. CBA thymocytes were used as a source of cytotoxic T-cell precursors that respond poorly in the absence of exogeneous helper activity. The source of alloantigen was varied by using irradiated spleen cells from various (BALB/c × recombinant)F₁ hybrid mice as stimulator cells. When the stimulator cell bears BALB/c determinants recognized by the cytotoxic T-cell precursor and also bears only the D region antigens of the H-2 ^b haplotype, an anti-BALB/c cytotoxic response is generated only if the anti-H-2^b helper population contains cells able to recognize H-2D^b. A positive cytotoxic response was obtained, indicating that helper cells are not limited to recognition of I region antigens and can efficiently recognize antigens encoded in the D region of the H-2 gene complex. This was confirmed by the demonstration of helpers specific for H-2D^d. We were unable to detect any evidence for Ia-restricted recognition of the H-2D alloantigens, suggesting that, as for cytotoxic T lymphocytes (CTL), helper cell recognition of class I alloantigens is an unrestricted event.     

Genetic control of sensitivity to Moloney leukemia virus in mice V. Role of H-2-linked genes in the control of anti-FMR cytolytic T lymphocytes

Three H-2-linked genes, Rmv1, Rmv2, and Rmv3 control the resistance of mice against Moloney virus (MLV)-induced leukemias. It has been shown previously that they function as immune response (Ir) genes regulating the level of antivirus antibodies. In the present experiments, the cell-mediated anti-tumor response has been studied in a series of inbred strains selected for their resistance or sensitivity to the MLV-induced disease. We failed to detect any relationship between resistance and sensitivity and the ability to produce cytolytic T lymphocytes (CTL) directed against the virus-induced FMR cell surface antigen. Furthermore, the role of each Rmv gene has been studied separately using congenic pairs of mice differing at only one of these loci: we failed to evidence any influence of these genes in the cell-mediated antitumor reactions as measured by the ability to lyse syngeneic FMR(+) target cells. Nevertheless a gene mapping in the D region of the MHC but probably different from Rmv3 controls the response of a subset of anti-FMR CTL restricted by the H-2K^k antigens, with higher response in H-2D^d than in H-2D^b animals. This observation confirms the existence of H-2D region associated Ir genes regulating the CTL-mediated antitumor immune responses by choosing the subset of responder CTL, and suggests that a fourth H-2-linked gene plays some role in the genetic control of the anti-FMR immune response.     

Cytotoxic T-cell responses to H-Y:Ir genes and associative antigens map inH-2

The secondary cytotoxic responses to the male-specific antigen (H-Y) in mice showH-2 restriction so that the cytotoxic female cell must share the K- and/or D-end antigen with the male target cells. The association with the K and/or D end varies with differentH-2 haplotypes,e.g., H-2 ^b cytotoxic cells require the H-2D^b antigen(s) on the target cells, while cytotoxic cells fromH-2 ^b/H-2 ^d F₁ mice sensitized toH-2 ^d male cells kill only male targets having H-2K^d antigen(s). This association of H-Y with appropriate K/D antigens seems to be needed also in the induction of the cytotoxic response. Of the independent haplotypes, onlyH-2 ^b strains are capable of making secondary anti-H-Y responses and this trait seems to be dominant,i.e., the F₁ strains with oneH-2 ^b parent are able to produce anti-H-Y cytotoxic cells against both theH-2 ^b parent and the nonresponder parent. The mating of the two nonresponder strains may produce F₁ mice which are responders, thus suggestingIr gene complementation. Mapping data indicates that at least one of these complementary genes is located in theI-C region fork/s complementation.     

Production of anti-self-H-2 antibodies by C3D2F1 mice hyperimmune to L cell/L1210 hybrids and L1210 leukemia cells

During the course of immunization of (C3H × DBA/2)F₁ mice (genotype H-2^k/b) with L cell (H-2^k/k)/L1210 leukemia cell (H-2^d/d) hybrids and L1210 leukemia cells, some of them produced a good titer of anti-self-H-2 (H-2^d) antibodies. Antigens recognized by this anti-self-H-2 antiserum were shown to be controlled by the H-2K-IA-IB-IJ-IE subregions of the H-2^d but not H-2^k nor H-2^b haplotypes of parental as well as F₁ origins and to have a tissue distribution identical to that of class 1 H-2 (H-2K/D) antigens.     

Cytolytic T lymphocyte-defined retroviral antigens on normal cells: Encoding by the Akv-1 proviral locus

We previously described the generation and specificity of H-2-restricted cytolytic lymphocytes (CTL) directed against tumors induced by AKR/Gross murine leukemia viruses (MuLV). Such anti-AKR/Gross virus CTL demonstrated type specificity; only tumors induced by endogenous MuLV that expressed the Gross cell-surface antigen were lysed. These CTL and their precursor also recognized normal spleen cells from AKR-H-2 ^b , but not AKR-H-2 ^b , Fv-1 ^b mice, however, suggesting that N-ecotropic, retrovirus-associated antigens were primarily involved. Here, expression of these CTL-defined retroviral antigens by H-2^b-positive AKR × C57L recombinant inbred strains was examined by using normal spleen cells as stimulators in the generation of specific anti-AKR/Gross virus CTL. Analysis of the strain distribution pattern of stimulation indicated that a single proviral locus, Akv-1, was primarily, if not entirely, responsible for CTL-defined retroviral antigen expression. The lack of correlation with two other well-defined proviral loci was interesting. Whereas Akv-3 is known to encode a defective virus, Akv-4 has been shown to code for an infectious virus thought to be very similar or identical to that of Akv-1. Although quantitative differences cannot be formally excluded, dose response experiments argued against this possibility and suggested that Akv-1 and Akv-4 may exhibit qualitative differences germane to antiviral CTL recognition.     

Genetic and functional analyses of the primary in vitro CTL: Response of NZB lymphocytes toH-2-compatible cells

Spleen cells from NZB mice make an unexpected primary cytotoxic T lymphocyte (CTL) response to BALB/c cells in vitro. In this study, it is shown that this response is comprised of at least three independent components. These include a response to antigens recognized in association with H-2^d products, a response to Qa-1^b-associated antigens which is notH-2-restricted and a response directed toward antigens not associated with either H-2^d- or Qa-1^b-coded determinants. The last response appears to be the weakest of the three. In addition, cells from NZB F₁ mice which were either homozygous (Qa-1 ^a /Qa-1 ^a ) or heterozygous (Qa-1 ^a /Qa-1 ^b ) forQa-1 alleles, all responded to BALB/c cells. These data suggest that the NZB CTL response to BALB/c cells is not solely dependent on antigens coded for by genes in theH-2D-Tla region for either the sensitization or effector phases of the response. The ontogeny of the NZB anti-BALB/c CTL response coincides with that of a number of B-cell abnormalities but is shown in experiments with-suppressed NZB mice to be independent of B-cell dysfunction. Studies with (NZB x B10.D2)F₁ + B10.D2 mice demonstrated that the anti-BALB/cCTL response to antigens coded for outside ofQa-1 is governed by at least two genes. Finally, it is shown that another conventionallyH-2-restricted response, that to TNP-modified isologous cells, is neither significantly cross-reactive nor markedly elevated in NZB mice. — The foregoing observations suggest that some subsets of NZB T lymphocytes are intrinsically abnormal. The possibilities that the apparent hyperreactivity of NZB CTL precursors, evidenced in the response to BALB/c cells, is primary or results from the secondary effects of excess T-cell help are discussed.     

Genetic control of the target structures recognized in hybrid resistance

Hybrid resistance of lethally irradiated (C57BL/6 × DBA/2)F₁ and (C57BL/10 × C3H)F₁ hybrid mice to the engraftment of parental C57BL/6 or C57BL/10 bone marrow cells is controlled by the H-2-linked Hh-1 locus. This resistance can be specifically blocked or inhibited by the injection of irradiated spleen cells from lethally irradiated, marrow reconstituted donor mice of certain strains. By testing the ability of regenerating spleen cells from various donor strains to block the resistance, we studied the genetic requirements for the expression of putative cell-surface structures recognized in hybrid resistance to H-2^b marrow cells. Strains of mice bearing informative intra-H-2 or H-2/ Qa-Tla recombinant haplotypes provided evidence that the Hh-1 locus is located telomeric to the H-2S region complement loci and centromeric to the H-2D region class I locus in the H-2 ^b chromosome. Two mutations that affect the class I H-2D ^b gene have no effect on Hh-1 ^b gene expression. The H-2D region of the H-2 ^S haplotype contains an allele of the Hh-1 locus indistinguishable from that of the H-2D ^b region, as judged by the phenotypes of relevant strains and F₁ hybrids. Collectively these data indicate that the Hh-1 locus is distinct from the class I H-2D (L) locus in the H-2 ^b or H-2 ^s genome, and favor the view that the expression or recognition of the relevant determinants is not associated with class I gene products.Abbreviations used in this paper BM(C) bone marrow (cells) - CML cell-mediated lympholysis - CTL cytotoxic T lymphocytes - FBS fetal bovine serum - HBSS Hanks' balanced salt solution - SC spleen cells from irradiated, bone marrow-reconstituted mice Address correspondence to: Dr. I. Najamura, Department of Pathology, School of Medicine, State University of New York at Buffalo, Buffalo, NY 14214, USA     

Responses against antigens encoded by theH-3 histocompatibility locus: Antigens stimulating class I MHC- and class II MHC-restricted T cells are encoded by separate genes

The purpose of this work was to study the genetic basis of histocompatibility antigens encoded by the mouse minor histocompatibility (H) locusH-3. Both class I major histocompatibility complex (MHC)-restricted cytotoxic T lymphocytes (CTL) and class II MHC-restricted helper T cells (TH) specific for antigens encoded by genes within theH-3 locus were isolated and analyzed. Typing a number of mouse strains for expression of antigens recognized by these TH and CTL suggested that there was a different strain distribution pattern of expression of the antigens recognized by TH compared with those recognized by CTL. Separation of the genes whose products stimulate TH from those whose products stimulate CTL was suggested by: (1) analysis of the strain B10.FS(92NX)/Grf that has undergone recombination within theH-3 region; (2) genetic segregation studies of (B10.UW-H-3 ^b/Sn×C57BL/10Sn)F₂ mice; and (3) F₁ complementation studies in which CTL specific for products of the TH-defined gene(s) could not be detected, even in the absence of immune responses to products of the CTL-defined genes. Taken together, these data suggest that in addition to two genes (B2m andCd-1) within theH-3 region whose products typically stimulate class I MHC-restricted CTL, there is at least one additional gene whose product selectively stimulates class II MHC-restricted TH. This new gene is located telomeric from the CTL-defined genes and between the lociwe andun on chromosome 2. These data demonstrate a novel degree of complexity of theH-3 “locus” and suggest selective presentation of minor H gene products in the context of class I or class II MHC proteins.     

H-2 antigen variants in a cultured heterozygous mouse leukemia cell line

An H-2 antigen variant, referred to as ?4 + 31 clone 1, was selected by its resistance to an anti-H-2D^d antiserum (BALB.G anti-BALB/c.H-2 ^g antiH-2 ^d ). When tested by cell-mediated cytolysis, this variant was found to be sensitive to cytolytic T lymphocytes raised in the same donor-host combination as that used in raising the antiserum. Further CML characterization of this variant, reported here, indicates that the cell line is in fact resistant to anti-H-2D^d killer cells raised in a more restricted immunization, viz. BALB.G anti-BALB/cH-2 ^db ,H-2 ^g anti-H-2 ^db . It is, however, sensitive to cytolytic cells raised in (BALB.B xBALB/c-H-2db) F¹ H-2 ^b /H-2 ^db ) against the BALB/c strain. These results suggest that the variant does not express H-2D^d itself, but probably expresses CML target antigens that are missing in theH-2 ^db mutation. This in vitro-isolated variant might thus be the complementary mutation to the in vivoobtainedH-2 ^db mutation.     

Homopoietic histocompatibility (Hh-1) phenotype and the regulation of its expression

Hybrid resistance (HR) is primarily controlled by the genes of the Hemopoietic histocompatibility-1 (Hh-1) locus within the H-2 complex. HR is a consequence of the Hh-1-controlled target determinants in homozygous parental strain mice and their absence in heterozygous F₁ hybrid mice. To examine the mechanism that controls the Hh-1 phenotype, three independent clones of somatic cell hybrids between parental lines EL-4 (C57BL/6 origin, H-2 ^b ) and R1 (C58 origin, H-2 ^k ) were studied. The line EL-4 is Hh-1^b-positive and is subject to HR by H-2 ^b heterozygous F₁ mice, but R1 lacks the Hh-1 ^b allele and is not susceptible to HR. Of the three hybrid clones, F263.2 is Hh-1^b-positive, whereas the other two, F262.2 and F264.2, are Hh-1-negative, as judged by these cells' capacity to compete in vivo with the grafted parental C57BL/6 bone marrow cells in the resistant (C57BL/6 × C3H)F₁ mice. All three clones express the H-2^b and H-2^k class I antigens equally well, are susceptible to activated NK cells to the same extent, and all carry four copies of chromosome 17. However, Southern analysis reveals that clone F263.2 contains three copies of H-2 ^b chromosome and one H-2 ^k , whereas the other two clones carry two copies each of the parental chromosome 17. The results suggest that the relative copy number of specific alleles is the crucial determinanr of the Hh-1 phenotype, and render unlikely both the gene dosage hypothesis and the trans-acting dominant suppression hypothesis to account for the noncodominant expression of the Hh-1 phenotype.     

A study of the ability of H-2Kk-Iak containing subcellular fractions to elicit primary anti-H-2 cytotoxic T lymphocytes

In order to identify an antigen required for elicitation of anti-H-2 cytotoxic T lymphocytes (CTLs), we have purified the H-2-K^k glycoprotein, incorporated it into a lipid vesicle, and tested it for its ability to elicit anti-H-2K^k CTLs. The results indicate that a lipid vesicle containing purified H-2K^k can elicit specific secondary anti-H-2K^k CTLs. In addition it was shown that in association with a partially purified Ia^k fraction the primary anti-H-2K^k CTL response was enhanced. It was also shown that Ia^k antigens alone could elicit an anti-H-2^k CTL response. Although a low primary response was found with purified H-2K^k, it was observed that lipid vesicles containing both H-2K^k and Ia^k glycoproteins could elicit a significantly enhanced primary anti-H-2K^k CTL response. Lipid vesicles containing H-2K^k-Ia^k were tested for their enhanced capacity to elicit anti-H-2 CTLs as well as for their ability to elicit anti-H-2K^k CTLs in the presence of supernatants from concanavalin A-stimulated spleen cells.     

H-2 class I antigen expression on mouse teratocarcinoma cell lines

Immunity against PCC3 teratocarcinoma cells (129, H-2 ^b) was induced in allogeneic (C3H, H-2 ^k) mice by preimmunization with L cells (C3H, H-2 ^k) expressing cosmid-introduced K ^b or D ^b genes, but not with nontransfected L cells. In addition, the growth of PCC3 cells in sublethally irradiated (C3H × B6-H-2 ^bm1)F₁ and (C3H × B6-H-2 ^bm13 )F₁ mice bearing the K ^bm1 and D ^bm13 mutations, respectively, was either prevented, stopped, or delayed in comparison with the (C3H × B6)F₁ (k × b) mice, which failed to reject the PCC3 cells. The teratocarcinoma line OC15S was exceptional because it reacted specifically with K^b- and D^b-specific (but not I^b-specific) alloantisera, and because K^b- and D^b-specific antibodies could be absorbed by OC15S cells. The subpopulation of OC15S cells bearing the ECMA-7 antigen characteristic for embryonic carcinoma (EC) cells was isolated by the fluorescence-activated cell sorter and was shown to react specifically with K^b- and D^b-specific antisera. These experiments show that teratocarcinoma cells express antigens similar or identical to the K-and D-region products of differentiated cells. The lack of expression of class I antigens is thus neither a condition nor a consequence of the pluripotentiality of the EC cells. The exact nature of the major histocompatibility complex antigens on EC cells has yet to be established using the methods of molecular biology and biochemistry.     

Differential effect of hybrid resistance on the localization of virus-immune effector T cells to spleen and brain

The hybrid resistance (Hr) effect operates in the lymphocytic choriomeningitis (LCM) in vivo transfer model to inhibit both the level of cytotoxicity T lymphocyte (CTL) generation in spleen and the induction of inflammation in cerebrospinal fluid (CSF). The effect is seen when LCM virus-immune T cells that are homozygous for H-2D ^b are injected into virus-infected, immunosuppressed recipients that are heterozygous for this allele, or into radiation chimeras that express an appropriate F₁ phenotype. Evidence that Hr to T -cell transfer is cell-dose-dependent and tends to diminish with age was found in both chimeric and normal F₁ mice. Inhibition of the capacity of injected T cells to cause meningitis is a more sensitive measure of Hr than is the further stimulation of CTL effectors in recipient lymphoid tissue. The injection of large numbers of H-2^b virus-immune T cells into (H-2 ^k X H-2 ^bF₁H-2 ^k) virus-infected recipients did not induce any cellular extravasation into CSF, though potent H-2^b-restricted CTL effectors were generated in recipient spleen. Evidence of minimal inflammatory process was found in one experiment where these chimeras were given a comparable dose of (H-2 ^b X H-2 ^d)F₁ immune spleen cells. Development of this Tcell-mediated immunopathological process depends essentially on the expression of the appropriate H-2 restriction element on radiation-resistant host cells which, in this case, presumably constitute part of the physiological barrier between blood and CSF.     

Xid-defective male (CBA/N x C57BL/6)F1 accessory cells present bovine insulin to long-term cultured F1-restricted T-cells

The reactivity of H-2^b-restricted murine T cells towards bovine insulin was reported to depend on the expression of Ia.W39, a private specificity of I-A^b, on antigen-presenting cells. Cells of male (CBA/N x B6)F₁ mice carrying the mutation xid on the X chromosome lack Ia.W39 on the cell surface. These cells are unable to present bovine insulin to primed T cells derived from female (CBA/N x B6)F₁ mice. We show here that spleen cells of male (CBA/N x B6)F₁ hybrids served perfectly as accessory cells for the insulin-dependent induction of a proliferative response of long-term cultured T cells with (B10 x B10.BR)F₁ genotype, restricted to recognizing insulin in the context of F₁-unique I-A determinants. The epitope on the insulin molecule essential for stimulation was determined to depend on the glutamic acid residue in position 4 of the A chain of insulin. This contrasts with the H-2^b-restricted response of B6 mice to bovine insulin, which appears to be directed at the A chain loop determinant (amino acids A8 and A10). These data suggest that distinct I-A^b-encoded structures, the expression of which is regulated independently, may serve as components of restriction elements for H-2^b and (H-2^b x H-2^k)F₁ restricted T cells, which are specific for different epitopes of bovine insulin.