Studies of immune responses in mice prone to autoimmune disorders. II. Decreased down-regulation by auto-anti-idiotype antibody in autoimmune-prone mice

Three lines of evidence are presented which suggest that autoimmune-prone mice are deficient in the production of auto-anti-idiotype antibody during their immune response to trinitrophenylated Ficoll (TNP-F). NZB, MRL lpr/lpr and older BXSB male mice have no hapten-augmentable plaque-forming cells (PFC). Hapten-augmentable PFC have been previously shown to be cells whose secretion of antibody has been inhibited by the binding of auto-anti-idiotype antibody to cell surface idiotype. Sera from TNP-F immunized NZB mice lack PFC inhibiting activity (anti-idiotype antibody). Spleen cells from TNP-F immune NZB mice fail to transfer anti-idiotype antibody-mediated suppression to naive mice as do spleen cells from immune non-autoimmune-prone mice. Taken together these data suggest that autoimmune-prone mice are deficient in auto-anti-idiotype antibody-mediated downward regulation of their immune responses. It was further shown that the immune response of NZB mice to TNP-F shows a slower decline in splenic PFC and a greater heterogeneity of PFC affinity than do the responses of non-autoimmune-prone strains. Since athymic (nude) mice, which were previously shown to be defective in the production of auto-anti-idiotype antibody, also show a slower decline in splenic PFC and an increased heterogeneity of PFC affinity, it is suggested that these peculiarities of the immune responses of autoimmune-prone and athymic mice are also the consequences of the lack of auto-anti-idiotype antibody-mediated down-regulation.     

Hormonal modulation of responses to thymus-independent and thymus-dependent antigens in autoimmune NZB/W mice

Previous work suggested that gonadal steroids influence immunity through the thymus, but the mechanisms were unclear. To investigate the effects of these hormones on immune responses to T1 and TD antigens in autoimmune mice, we studied hybrid NZB/W mice and the nonautoimmune DBA/2 strain. Mice castrated at 14 days of age were implanted with Silastic capsules releasing, in adults, physiologic levels of E2 in males or Te in females. Sham-operated controls received empty capsules. Splenic PFC were quantified 4 to 5 days after challenge with the TI2 antigen TNP-Ficoll, the TI1 antigen TNP-LPS, or the TD antigen SRBC. Young castrated NZB/W males implanted with E2 had striking enhancement of IgM responses to TNP-Ficoll when compared to castrated Te-treated females and comparable sham-operated controls of both sexes. E2 also stimulated responses to TNP-LPS. In response to challenge with SRBC, young E2-treated NZB/W males had a consistent trend to increased IgM PFC, and the stimulatory effect of E2 on IgG plaques was variable. Physiologic doses of Te had no consistent effect on responses in young mice. In old female NZB/W mice, Te caused PFC response after immunization with TNP-Ficoll to resemble age-matched NZB/W males. As sham-operated NZB/W females grew older, PFC responses to SRBC fell. This age-related phenomenon was delayed, however, in female castrates implanted with Te. In contrast, Te clearly suppressed responses to TNP-LPS. Implantation of E2 did not alter responses to TNP-Ficoll, TNP-LPS, or SRBC in nonautoimmune DBA/2 males. This finding suggested that exogenous E2 given in physiologic doses did not influence immunologic responsiveness in a normal strain to the degree seen in hormone-sensitive NZB/W mice. It was concluded that E2 enhanced responses to a variety of exogenous antigens in autoimmune NZB/W mice. The most consistent E2-induced increase in PFC response was observed with TI antigens, suggesting that E2 exerted its effects on B cells or Ts.     

Specific antigen-binding and antibody-secreting lymphocytes associated with the erythrocyte autoantibody responses of NZB and genetically unrelated mice.

The receptor characteristics as well as incidence of antigen-binding lymphocytes (ABL) or B and T cell classes with membrane receptors specific for the exposed (X) and cryptic (HB) murine erythrocyte autoantigens were examined in NZB and nine control strains of mice. Whereas only NZB and NZB hybrid mice synthesize anti-X autoantibody pathogenetically implicated in the genetically determined autoimmune hemolytic anemia, the NZB as well as control strains synthesize the ubiquitous anti-HB anti-erythrocyte autoantibody. By utilizing immunocytoadherence assays, maximum numbers of specific ABL of both B and T lymphocyte classes were optimally demonstrated at erythrocyte:lymphocyte ratios of 20:1 and after lymphocyte fixation at 56 degrees C for 20 min. Surface membrane receptor specificity was established by inhibition with semi-purified soluble X or HB autoantigen. Inhibition of immunocyto-adherence with class specific antisera to mouse immuno-globulins demonstrated that the receptors on both B and T cells were of IgM class. Specific receptors regenerated in vitro after trypsinization which excluded the role of cytophilic antibody in the immunocytoadherence reactions. B lymphocyte ABL reactive with the X autoantigen were demonstrable in NZB, NZB hybrid, and control mice. Only in NZB and NZB hybrid mice, strains that uniformly synthesize anti-X autoantibody, were X ABL of T lymphocyte class demonstrated. The presence and incidence of T lymphocyte X ABL is compatible with the expression of a single dominant gene carried by the NAB strain. The incidence of B lymphocyte X ABL increased with age, suggesting proliferation of this cell population. HB ABL of both B and T lymphocyte classes were observed in all strains, concordant with the ubiquitous presence of humoral anti-HB autoantibodies. Differentiation of precursor B cells are evaluated by PFC assay of cells secreting specific autoantibodies. Anti-X PFC were observed only in NZB and NZB hybrid mice; and the observed frequency suggested that less than 3.5% of the specific ABL were differentiated for the secretion of anti-X autoantibody. Anti-HB PFC were observed in all strains and represented as high as 11.8% of specific ABL. Genetic determination of the anti-X anti-erythrocyte autoantibody response does not prescribe the presence of precursors of the antibody-forming cell, but rather appears to influence regulation of the differentiation of these cells. These data suggest that circumvention of immunologic tolerance to this specific erythrocyte autoantigen may occur at the level of the T lymphocyte; or alternatively, that T lymphocytes as well as B lymphocytes, are induced to proliferate and differentiate in the NZB strain.     

Evidence for histamine-induced auto-anti-idiotypic antibody immunoregulation in vivo

The in vivo effects of histamine injection in LAF₁ male mice on the immune reactivity to trinitrophenylated bovine γ-globulin was studied using plaque-forming cell (PFC) responses and their avidity distributions. Splenic anti-trinitrophenyl (anti-TNP) PFC responses of mice treated with histamine (5 × 10^?6 mol or 1 mg, intravenously) were significantly reduced in number and restricted in heterogeneity and characterized by a preferential loss of high-avidity IgG PFCs. The reduced PFC response in histamine-treated mice was dose and time dependent. No evidence of suppressor cell activity in the spleens from histamine-treated mice was demonstrable. Only histamine-treated mice produced a significantly high percentage of anti-idiotype-blocked, hapten-augmentable IgG PFCs, suggesting the presence of auto-anti-idiotypic activity. Immune sera taken from histamine-treated mice caused an inhibition of anti-TNP PFC in vitro. This PFC-inhibiting factor in immune sera of histamine-treated mice was an antibody of the IgG₁ and IgG_2a class, lacked anti-TNP antibody activity, but reacted with anti-TNP antibody of LAF₁ origin. Passive hemagglutination study of this sera showed anti-(anti-TNP F(ab′)₂-IgG) titer. Thus, the results of this study suggest that histamine in combination with antigen induces auto-anti-idiotypic antibody which, in turn, is involved in the normal regulation of the immune response to trinitrophenylated bovine γ-globulin in vivo.     

Aberrant maturational characteristics of the immune responses of NZB mice to autologous and heterologous erythrocyte antigens

The maturational characteristics of the humoral immune responses of C3H and NZB mice to autologous and heterologous erythrocyte antigens were investigated. Clonal selection of antibody-secreting B lymphocytes was examined at the plaque-forming cell level of analysis of changes in mean antibody affinity and the heterogeneity of binding affinities. The primary immune response of C3H mice to SRBC exhibited a progressive temporal increase in mean relative antibody affinity and a concomitant restriction in the heterogeneity of binding affinities consistent with clonal selection and restriction of B lymphocytes to high affinity antibody-secreting cells. By contrast, the anti-SRBC immune response of NZB mice displayed aberrant maturational characteristics with a progressive decrease in mean relative antibody affinity but also clonal restriction with selection of clones of cells secreting low affinity antibodies. The spontaneous autoimmune responses of NZB mice to autologous erythrocyte surface autoantigens X and HB were different from the response to heterologous erythrocytes in that there was neither a progressive change in mean relative binding affinity nor evidence of progressive clonal restriction. Although the precise mechanisms responsible for the aberrant selection and derepression of B lymphocyte clones in NZB mice have not been identified, the very nature of the aberration suggests the existence of one or more defects which may be intrinsic to the B lymphocytes of NZB mice.     

Genetic control of the immune response of mice to type III pneumococcal polysaccharide

BALBc mice immunized with Type III pneumococcal polysaccharide (SIII) had higher numbers of IgM plaque-forming cells (PFC) in the spleen than similarly immunized C57BL/Ks mice. The F₁ hybrids of these two strains had intermediate numbers of SIII-specific PFC. Analysis of the responses of F₂ and backcross strains indicated that the observed responses were compatible with results expected for control of the immune response to SIII at a single autosomal locus.     

Failure of CBA/N mice to respond to thymus-dependent and thymus-independent phosphorylcholine antigens.

CBA/N mice have an X-linked defect of B lymphocyte differentiation. We have studied their responsiveness to different antigenic forms of the phosphorylcholine (PC) epitope which induce IgM responses of restricted heterogeneity. Although previous work had emphasized a defect of T.I. responses in CBA/N we found that both T.D. and T.I. anti-PC responses are severely depressed in CBA/N, in spite of the use of bacterial adjuvants or repeated immunizations; however, with certain immunization protocols we could detect in CBA/N direct and indirect PFC whose specificity was not limited to PC but included the PC-protein bridge. Transfer experiments involving normal or irradiated immunodeficient F₁ hybrid males as recipients of normal spleen or bone marrow cells failed to implicate suppressive mechanisms in the unresponsiveness to PC antigens. Our results indicate that the defect in antigen-induced humoral responses in CBA/N mice is not simply related to the thymus-dependence of the antigen used but rather a consequence of selective maturational defects of subpopulations of B lymphocytes and of subsets within each subpopulation.     

Effect of fish oil diet on immune response and proteinuria in mice

In this study, we examined the immune response and proteinuria caused by dietary polyunsaturated fatty acids in normal NZW/N and autoimmune NZB/NZW mice. Mice were maintained more than one year on five dietary groups: normal (5% corn oil), calorie-restricted, high fat (20% corn oil), high fat (20% fish oil), and Purina laboratory rodent chow. Normal mice fed with the fish oil diet had a more reduced anti-sheep red blood cells (SRBC) plaque-forming cell (PFC) response and less interleukin-2 (IL-2) enhancement of PFC than did the group with the restricted diet and the young control group. The corn oil (5 and 20%) diet animals also showed reduced PFC response and IL-2 utilization. NZB/NZW mice fed with the fish oil diet showed similar reduced PFC response but had a significantly lower response to IL-2 than did those on the corn oil diets and the restricted diet. The IL-2 production by macrophages from NZW/N mice was reduced in both the fish oil and corn oil diet groups. However, mice fed with the fish oil diet had less proteinuria and good survival rates, similar to the group with the restricted diet. These results suggest that the beneficial effect of the fish oil diet in these animals may be attributed in part to the immunosuppression mechanism.     

Studies on the control of antibody synthesis. XIV. Role of T cells in regulating antibody affinity.

The effect of limiting the number of helper T cells on the affinity of the primary antibody response to a T-dependent antigen (DNP-BGG) was evaluated in a cell transfer system. Lethally irradiated, thymectomized mice were reconstituted with either bone marrow or anti-brain θ antiserum plus complement-treated spleen as the source of B cells. In addition, they received various numbers of thymus cells as a source of helper T cells. The animals were immunized with DNP-BGG 1 day after cell transfer and their splenic anti-DNP PFC response was assayed for magnitude and affinity 3 weeks later. A marked restriction in helper T-cell activity resulted in a primary response which was of low magnitude, which lacked indirect PFC, and which had a very low affinity and restricted heterogeneity. When sufficient thymus cells were given to permit a switch to indirect plaque formation, a highly heterogeneous, high-affinity primary response was elicited. Further increase in the number of thymic cells resulted in a progressive increase in the magnitude of the primary response but had no effect on affinity. Thus, a reduction of 50% in the magnitude of the response as a consequence of limiting the number of T-helper cells had no effect on the affinity of the PFC. The results are consistent with the interpretation that the effect of restriction in T-cell help on antibody affinity is not due to a direct effect on precursors of high-affinity PFC but is secondary to inefficient selection for high-affinity cells when the degree of cell proliferation is markedly reduced.     

Hyper IgE in New Zealand black mice due to a dominant-negative CD23 mutation

Immunoglobulin E (IgE) plays a critical role in both resistance to parasitic infection and allergy to environmental antigens. The IgE response is in turn regulated by the B-cell co-receptor CD23, and CD23-deficient mice show exaggerated IgE responses and airway hyper-responsiveness. In this report, we show that New Zealand black (NZB) mice express a variant CD23 allele, with mutations in both the C-lectin-binding domain and stalk region, which fails to bind IgE at high affinity and has reduced expression on the cell surface. Expression of the variant CD23 chain interferes with trimerisation of the receptor and has a dominant-negative effect leading to reduced IgE binding in crosses between NZB and other strains. Genetic mapping shows that the variant CD23 leads to an exaggerated primary IgE response, which is independent of other strain-specific effects. These results suggest that NZB mice or mice carrying the variant allele will be useful models for studying both allergy and quantitative traits associated with atopy. The exaggerated IgE response provides an explanation for the natural resistance of NZB mice to parasitic infection by Leishmania.     

The P2X<Subscript>7</Subscript>receptor is a candidate product of murine and human lupus susceptibility loci: a hypothesis and comparison of murine allelic products

Systemic lupus erythematosus and its murine equivalent, modelled in the New Zealand Black and New Zealand White (NZB × NZW)F₁ hybrid strain, are polygenic inflammatory diseases, probably reflecting an autoimmune response to debris from cells undergoing programmed cell death. Several human and murine loci contributing to disease have been defined. The present study asks whether the proinflammatory purinergic receptor P2X₇, an initiator of a form of programmed cell death known as aponecrosis, is a candidate product of murine and human lupus susceptibility loci. One such locus in (NZB × NZW)F₁ mice is lbw3, which is situated at the distal end of NZW chromosome 5. We first assess whether NZB mice and NZW mice carry distinct alleles of the P2RX ₇ gene as expressed by common laboratory strains, which differ in sensitivity to ATP stimulation. We then compare the responses of NZB lymphocytes, NZW lymphocytes and (NZB × NZW)F₁ lymphocytes to P2X₇ stimulation. NZB and NZW parental strains express the distinct P2X₇-L and P2X₇-P alleles of P2RX ₇, respectively, while lymphocytes from these and (NZB × NZW)F₁ mice differ markedly in their responses to P2X₇ receptor stimulation. NZB mice and NZW mice express functionally distinct alleles of the proinflammatory receptor, P2X₇. We show that current mapping suggests that murine and human P2RX ₇ receptor genes lie within lupus susceptibility loci lbw3 and SLEB4, and we argue that these encode a product with the functional characteristics consistent with a role in lupus. Furthermore, we argue that aponecrosis as induced by P2X₇ is a cell death mechanism with characteristics that potentially have particular relevance to disease pathogenesis.     

Functional evidence for abnormal maturation within a B-cell subpopulation of NZB mice

NZB mice develop a systemic autoimmune disease and have a subpopulation of B lymphocytes that spontaneously produce excessive amounts of IgM. These abnormal B cells reside within a specific B-cell subset that is affected by the CBA/N defect. In normal mice, this B-cell subset acquires in vitro responsiveness to certain thymus-independent antigens (TI-2) relatively late in ontogeny. We compared the functional development of neonatal B cells from NZB mice to that of normal mice of the same H-2 type. The acquisition of in vitro responsiveness to the TI-1 antigen, TNP-LPS and the TI-2 antigens, TNP-Dextran, TNP-Ficoll, and FITC-Ficoll was examined. TNP-LPS could elicit a response from both normal and NZB neonates. In contrast, responses to the TI-2 antigens were elicited early in life (<1 week) only from or at a higher level from NZB neonates. However, an accelerated appearance of B-cell differentiation antigens was not detected in NZB neonates compared to normal strains. We conclude, therefore, that a maturation or triggering defect occurs in a small B-cell subpopulation of NZB mice very early in life.     

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.     

Numbers and avidity of anti-DNP antibody plaques in different inbred mouse strains

Spleen cells of mice from eight inbred strains and three F₁ hybrids, undergoing a secondary immune response to dinitrophenylated keyhole limpet hemocyanin (DNP-KLH), were examined for numbers of indirect DNP-specific plaque forming cells (PFC) as well as avidity of anti-DNP antibodies. The results indicated that the magnitude of the immune response is under genetic control. Differences in average avidity and heterogeneity of avidity were found among different mouse strains, suggesting genetic control of these parameters. However, no simple pattern of inheritance for these characteristics emerged from the study.     

Impairment of primary in vitro response of New Zealand mouse spleen cells to a thymic-dependent antigen.

New Zealand Black (NZB) and NZB by New Zealand White (NZW) F₁ hybrid ($\text{B}\text{W}$) mice develop clinical signs of autoimmune disease between 6 and 10 months of age but spleen cells from these strains have a greatly reduced in vitro response to sheep erythrocytes (SRBC) as early as 5–6 weeks of age. This hyporesponsiveness can be only partially restored with 2-mercaptoethanol, allogeneic macrophages or spleen cells, or allogeneic factor. The response of NZB and $\text{B}\text{W}$ spleen cells to the thymic independent antigen DNP-Ficoll is nearly normal. The reduced in vitro SRBC response was found to be attributable to splenic T and B cells rather than macrophages. Macrophages from NZB mice were found to function normally. The in vitro behavior of NZB lymphocytes is very similar to non-autoimmune mice infected with common murine viral pathogens. NZB and $\text{B}\text{W}$ mice may be making an active immune response as early as 5 weeks of age.     

Genotype-specific environmental impact on the variance of blood values in inbred and F1 hybrid mice

Mice are important models for biomedical research because of the possibility of standardizing genetic background and environmental conditions, which both affect phenotypic variability. Inbred mouse strains as well as F₁ hybrid mice are routinely used as genetically defined animal models; however, only a few studies investigated the variance of phenotypic parameters in inbred versus F₁ hybrid mice and the potential interference of the genetic background with different housing conditions. Thus, we analyzed the ranges of clinical chemical and hematologic parameters in C3H and C57BL/6 inbred mice and their reciprocal F₁ hybrids (B6C3F1, C3B6F1) in two different mouse facilities. Two thirds of the blood parameters examined in the same strain differed between the facilities for both the inbred strains and the F₁ hybrid lines. The relation of the values between inbred and F₁ hybrid mice was also affected by the facility. The variance of blood parameters in F₁ hybrid mice compared with their parental inbred strains was inconsistent in one facility but generally smaller in the other facility. A subsequent study of F₁ hybrid animals derived from the parental strains C3H and BALB/c, which was done in the latter housing unit, detected no general difference in the variance of blood parameters between F₁ hybrid and inbred mice. Our study clearly demonstrates the possibility of major interactions between genotype and environment regarding the variance of clinical chemical and hematologic parameters.     

Interference between Neisseria meningitidis and PC-KLH Induced Anti-Phosphorylcholine PFC Responses in NZB/W Autoimmune Mice

In this work, we demonstrate that the simultaneous injection of PC-KLH and Neisseria meningitidis-derived antigens [NMB or PC-(NMB)HI] induced in old NZB/W mice defective responses as does PC-KLH challenge. On the other hand, the simultaneous injection of both immunogenic preparations of N. meningitidis evoked responses similar to those shown by old mice challenged with NMB alone. Alteration in PC-specific PFC responses also affected hapten-free inhibition profiles and their heterogeneities. The increase in PC₅₀s of anti-phosphorylcholine PFC responses and their heterogeneities induced by certain antigens with aging is correlated with a decrease in T15 idiotype expression, suggesting that after the T15 dominant clone disappears no other clone takes control of the anti-PC response. These results suggest that the mechanism(s) involved in the regulation of T15 marker expression play an important role in the inability of old NZB/W mice to mount good anti-PC responses and suggest that regulatory mechanisms induced by PC-KLH dominate those elicited by NMB.     

Selective improvement of thymus and some T cell dysfunctions in NZB mice by in utero thymulin treatment

NZB mice were treated during gestation with thymulin, a thymus-secreted, zinc-associated nonapeptide. Control pregnant NZB mice received either zinc alone or saline alone. Offspring from all three groups of NZB mothers, and age-matched DBA/2 mice, were tested for the following immunologic parameters: thymulin serum levels at 2 and 5 wk of age; splenic anti-sheep red blood cell (anti-SRBC) plaque-forming cell (PFC) numbers after immunization at birth or at 2 wk of age; anti-human gamma-globulin (anti-HGG) antibody titers after immunization at 2 wk of age, with or without prior tolerance induction at birth with deaggregated HGG; spontaneous IgM serum levels at 2 and 5 wk of age; spontaneous splenic anti-trinitrophenyl (anti-TNP) PFC numbers at 2 wk of age. As compared with DBA/2 mice, young NZB mice exhibited low circulating thymulin titers, high antibody responses to SRBC and to HGG, resistance to tolerance induction by deaggregated HGG, increased spontaneous IgM serum levels, and increased spontaneous anti-TNP PFC numbers. However, marked reductions in anti-SRBC and anti-HGG antibody production, both thymus-dependent responses, were observed in the young NZB offspring of thymulin-treated mothers as compared with NZB controls born from zinc- or saline-treated mothers. A delay in the postnatal decrease of serum thymulin levels was also noted in the offspring of thymulin-treated mothers. Interestingly, these effects of in utero thymulin treatment tended to become more pronounced with advancing age during the postnatal period. Conversely, IgM serum levels, spontaneous anti-TNP PFC and sensitivity to tolerance induction were not affected by thymulin treatment during fetal life. Taken together, the data suggest that in utero exposure to pharmacologic concentrations of thymulin induces a persistent and selective improvement of some thymus and T cell dysfunctions but has no effect on intrinsic B cell abnormalities of NZB mice.     

TNP-LPS induces an IgG anti-TNP immune response in mice.

The trinitrophenylated derivatives of lipopolysaccharide (TNP-LPS) elicit a specific anti-TNP, thymus-independent immune response in mice. After a single injection of antigen, anti-TNP antibodies of IgM and IgG isotypes are detected at the cellular and at the humoral levels, in athymic nude mice as well as in conventional (C57B1/6 × DBA/2)F₁ mice. The immune sera were resolved into IgM and IgG molecules by gel filtration; both fractions showed an anti-TNP activity, thus confirming the data obtained by the cellular analysis.     

Polymorphism of minor histocompatibility genes in wild mice

H-2^b-restricted cytolytic T lymphocytes (CTL) were generated against H-1, H-3, and H-4 antigens and tested against target cells of F₁ hybrids between wild mice and inbred H-2 ^b mice. The congenic strain combinations for the CTL production were such that they tested one allele each at the H-1 and H-4 loci and four alleles at the H-3 locus. Most of the wild mice tested came from Southern Germany, but a few mice came from other European countries and Egypt and Israel. Virtually all wild mice typed as positive with CTL directed against H-3^b and H-4^b antigens; 32% of the F₁ hybrids tested reacted with anti-H-1^cCTL and 9% reacted with anti-H-3^d CTL. The positive results were not caused by cross-reaction with allogeneic H-2 antigens controlled by the major histocompatibility complex (Mhc) genes of the wild mice. At least some of the H-3 and H-4 antigens detected by the CTL in the F₁ hybrid were not identical with antigens of the immunizing strains. These results suggest a relatively low degree of polymorphism of the tested minor H loci in wild mice and further support the notion that minor H loci are unrelated to the Mhc.