Immune response of mice to Thy-1.1 antigen: Studies on congenic lines

The primary response to Thy-1.1 antigen was measured by a plaque assay that detected cells producing antibodies lytic for AKR thymocytes (PFC). TheH-2 congenic mice (B10.K and B10.BR) carryingH-2 complexes of high responders (CBA and C57BR) on the low-responder background (B10) were found to produce significantly fewer PFC than the corresponding donor of theH-2 complex. On the other hand, C3H.B10 mice carrying theH-2 complex of a low responder on the high-responder background produced significantly more PFC than the donor of theH-2 complex. These findings were interpreted as evidence that alleles at previously described loci believed to be components of theI region of theH-2 complex and controlling immune response to Thy-1.1 are influenced by alleles at another locus. Studies of segregating populations of theH-2 congenic lines supplied evidence that this locus, tentatively calledIr-5, is in chromosome 17 (linkage group IX).     

The specificity and significance of the inhibition of Fc receptor binding by anti H-2 sera

The possibility that Ia antigens are unique among H-2 antigens in their relationship to the Fc receptor was investigated in an EA rosette assay. Antibody specific for antigens in various regions of theH-2 complex was incubated with mouse cells, and the ability of the cells to form rosettes with antibody-coated chicken erythrocytes was tested. Antibody raised against the H-2 antigens of Ia-negative tumor cells was highly effective in inhibiting rosette formation. A variety of antisera againstK-, I-, andD-region antigens tested in recombinant mice inhibited EA rosette formation, suggesting that antigens in each of these regions could be detected in rosette inhibition. The F(ab′)₂ fragments of all antisera tested also produced specific EA rosette inhibition. Finally, antibody against Ia antigens failed to inhibit bone marrow RFCs, although antibody against H-2K and H-2D antigens did inhibit. Although H-2 serology is in a state of rapid change at present, it must be concluded that in this assay, antibody against antigens in theK andD regions as well as theI region can inhibit EA rosette formation. Inhibition of these rosettes by anti H-2 sera is therefore not due to a special association of Ia antigens with Fc receptors.     

T(Iat)- and B(Iab)-cell alloantigens determined by theH-2 linkedI region in mice

The specificity of an antiserum directed againstI region associated (Ia) antigens is described. The serum was raised in (DBA/1×B10.D2)F₁ mice against lymphocytes of AQR mice, differing from the responder for theI region only. The serum reacts with Ia antigens expressed on B cells (Iab) as well as with Ia antigens expressed on T cells (Iat). Absorption studies indicate that B cells possess at least two Ia antigens, and one of these is shared by T cells. However, this shared antigen is not present on the surface of lymphocytes of thymectomized mice. Analysis of the strain distribution of Iab and Iat antigens revealed that the Iab antigens are present on lymphocytes of mice carrying theIA ^k subregion and that the Iat antigens are present on lymphocytes of mice carryingI region genes of theH-2 ^k haplotype located between theIA andIB subregions. This conclusion is based on the analysis of the antiserum's reactivity with T and B cells of the strains B10.A(2R), B10.A(4R) and B10.HTT: the serum reacts with B and T cells of B10.A(2R) but only with B cells of B10.A(4R) mice and only weakly with T cells of B10.HTT mice.Abbreviations ALG antimouse lymphocyte globulin from rabbits - B cells bone marrow derived lymphocytes - B10 C57BL/10Sn mice - D1D2F₁ (DBA/1×B10.D2)F₁ hybrid mice - GVHR graft-vs-host reaction - Ia I region associated antigen - Iab on B cells - Iat on T cells - MLR mixed lymphocyte reaction - T cells thymus-derived lymphocytes - Thy-1 thymus antigen 1, formerly called theta - Tx-Lyc lymphocytes of thymectomized, ALG treated, lethally irradiated and anti-Thy-1 treated bone marrow reconstituted mice - 2R B10.A(2R)/SgSn mice - 4R B10.A(4R) mice     

Demonstration of Ia antigens on mouse intestinal epithelial cells by immunoferritin labeling

Several kinds of epithelial cells that express H-2 antigens were studied by immunoferritin labeling with an antiserum reacting only with antigens of theI region of theH-2 complex. Spleen lymphocytes were used to test the labeling system and the effect of the epithelial cell dissociation procedure on Ia antigens. Immunoglobulin-positive B10.BR lymphocytes were labeled with an anti-la^k serum (A.TH anti-A.TL serum absorbed with BALB/c and B10.D2 cells), while congenic B10.D2 lymphocytes were unlabeled. The distribution of labeled Ia antigens on living B10.BR lymphocytes was patchy, while on cells fixed in periodate-lysine-paraformaldehyde before labeling, the distribution of label was continuous. Fixation evidently immobilized Ia antigens in the lymphocyte membrane. Trypsin and collagenase, as used in the epithelial cell dissociation procedure, had no discernible effect on the Ia antigens of lymphocytes. The epithelial cells studied included the columnar absorptive cells of the small intestine, uterine lining epithelium, tracheal brush cells, and pancreatic exocrine and duct cells. These cells were fixed before dissociation from their respective tissues. Ia antigens were detected only on the columnar absorptive cells of the small intestine. These cells labeled equally well with an antiserum reacting only with theK -end of theH-2 complex. In both cases, congenic control intestinal cells were unlabeled. Thus, intestinal epithelial cells appear to express theIa, K, and presumablyD regions of theH-2 complex, while the other epithelial cell types express only the K and D antigens. On fixed intestinal epithelial cells, Ia and H-2K antigens were continuously distributed on the lateral and basal cell membranes including the zonula adherens, but the antigens were absent from the apical microvillous membrane and the zonula occludens.     

Evidence for structural homology between murine and human Ia antigens

The serological cross-reactivity and the structural homology of murine and human Ia alloantigens were analyzed. Both normal human peripheral blood B lymphocytes and chronic lymphocytic leukemia (CLL) cells were shown to be lysed in the presence of complement by both murine anti-Ia and human anti-HLA-DR alloantisera. A mouse A.TH anti-A.TL (anti-I ^k ) alloantiserum reacted with determinants expressed on all of the 20 normal human B cell populations tested. Only 3 of these 20 B cell populations were lysed with an A.TL anti-A.TH anti-I ^s alloantiserum. The frequency of cytotoxic cross-reactivity concordant with anti-I ^k appears to be greater for anti-I-EC ^k than for anti-I-A ^k alloreactivity. An immunochemical analysis demonstrated that Iaα-chain andβ-chain polypeptides may be immunoprecipitated from CLL cell lysates by either a mouse anti-I ^k alloantiserum or various human anti-HLA-DR alloantisera. The Ia molecules detected with the mouse and human antisera are coprecipitable as revealed by one-dimensional gel electrophoresis. Two-dimensional gel electrophoresis studies indicated that the human CLL cell Ia antigens analyzed possess considerable molecular heterogeneity. They are structurally more similar, with respect to molecular size and charge, to mouse Ia antigens determined by the murineH-2-linkedI-EC subregion rather than theI-A subregion. The structural, genetic and functional implications of these findings are discussed.     

Evidence for a fifth (G) region in theH-2 complex of the mouse

Antisera (B10.129×A)F₁ anti-P and (B10×A)F₁ anti-B10.P contain antibodies that define, in the PVP hemagglutination test, an antigen originally described as G or H-2.7. Of the independentH-2 haplotypes, the H-2.7 antigen is present inf, j, k, p, ands. In addition, the antisera also contain a weak cytotoxic antibody, distinct from anti-H-2.7. The cytotoxic antibody reacts with antigens controlled by theK orI regions. The hemagglutinating H-2.7 antibody does not have cytotoxic activity. The genetic determinant coding for antigen H-2.7 can be mapped into the chromosomal segment between theS andD regions. The H-2.7 antigen thus serves as a marker for a new region of theH-2 complex. The locus coding for antigen H-2.7 is designatedH-2 G and the correspondingH-2 regionG. The H-2.7 antigen has a tissue distribution distinct from that of the H-2 antigens controlled by theK orD regions. So far it could be detected primarily on erythrocytes.     

Biochemical characterization of murine Ia antigens with xenoantisera

Rabbit anti-Ia sera was produced by immunization with detergentsolubilized extracts from splenic, lymph-node and thymus cells. The antisera contained activity against H-2 as well as Ia molecules. By a sequential immunoprecipitation assay it was shown that the rabbit anti-mouseH-2 ^s serum precipitated a second Ia molecule in theH-2 ^s haplotype. Previous studies with alloantisera have shown only one Ia molecule associated with this haplotype. Sequential precipitations with alloantiserum against the wholeI region were used to show that this second Ia molecule is coded by genes within theI region. Since only I-A- and I-E-region coded molecules are immunoprecipitable in most haplotypes, we presume that the rabbit antiserum could be identifying the I-E-subregion coded molecule in theH-2 ^s haplotype. The rabbit antiserum reacts with an isotypic specificity on the molecule. The studies suggest that theI-E subregion does exist in theH-2 ^s haplotype even though alloantiserum cannot be produced to identify allotypic variants associated with this subregion.     

Analysis ofH-2 mutants: Evidence for multiple CML target specificities controlled by theH-2K b gene

C57BL/6 (H-2 ^b ) mice and two mutants derived from this strain, B6.C-H-2 ^ba (Hz1) andE6-H-2 ^bd (M505), were studied in a number of functional tests, in vitro and in vivo, that assay for differences at theH-2 complex. All three strains give rise to reciprocal mixed lymphocyte reactivity (MLR) and cell-mediated lympholysis (CML) in vitro as well as graft-host reactivity (GVHR) and skin graft rejection in vivo. Analysis for cross-reactivity between these strains in CML revealed that the gained antigens in each mutant do not cross-react, and that Hz1 has lost an antigen shared by C57BL/6 and M505 strains. In addition, spleen cells from B10.A(4R) mice, which differ from theH-2 ^b haplotype only at theK end of theH-2 complex, recognize a common antigen shared by all three strains tested. Provided that the mutations occurred in theH-2K ^b gene, these data indicate that a) there are at least three antigenic specificities coded for by theH-2K ^b gene(s) that serve as targets for receptors on thymus-derived (T) cells in CML; b) since C57BL/6 strain mice and the mutants are serologically indistinguishable on a qualitative basis, the antigens recognized by the receptors on T cells and by humoral H-2 antibody are nonidentical; and c) mutation in theH-2K ^b locus itself can give rise to allogeneic recognition phenomena such as MLR and GVHR.     

Idiotypic regulation of mouse anti-H-2 antibody responses

Mouse-immunoglobulin (MIg) tolerant rabbits immunized with mouse H-2 antibodies produced anti-idiotype antisera, which were reactive towards specific B- and T-cell receptors. One such rabbit antiserum (from rabbit 5936) defines a family of idiotypes (Id) designated 5936-idiotypes (Rubin et al. 1979). The present experiments were performed in order to establish (1) the nature of 5936-Id⁺ serum molecules, (2) the specificity of 5936-Id⁺ serum molecules, (3) the association of the 5936-Id genes to allotype and/orH-2 genes and (4) the immunological role of 5936-Id⁺ serum molecules. A sensitive, radioimmunoassay employing¹²⁵I-labelled-F(ab)₂ fragments of B6 anti-B10.BR MIg pool, 5936 antiserum, and a sheep anti-rabbit immunoglobulin antiserum, was used.—The results suggested that 5936-Id⁺ serum molecules were exclusively MIg, and that they were mainly of the IgG₁ class. Such molecules were induced in B6 mice (H-2 ^b /Ig-1 ^b ) upon immunization with H-2^k but not with H-2^q alloantigen or conventional antigens. The 5936-Id were found to be associated with Ig-1^b allotypes and theH-2 ^b complex may contain immune response (Ir) genes which, in comparison withIr genes inH-2 ^d andH-2 ^s , favor the expression of 5936-Id.—Adsorption of 5936-Id⁺ B6 anti-CBA MIg preparations on CBA (IA^k) spleen cells demonstrated that CBA antibodies were 5936-Id^?. It is dicussed whether 5936-Id⁺, IgG₁ molecules in B6 anti-CBA sera are anti-(anti-CBA) antibodies or nonspecific antibodies, the production of which is augmented by immunization with IA^k alloantigen.     

Immune response of mice to the Thy-1.1 antigen: Effect of theIr-5 alleles studied in 129/J and B10.129 (6M) mice

The primary immune response to the Thy-1.1 antigen was measured by a plaque assay that detected cells producing antibodies lytic for AKR thymocytes. B10.129(6M) mice carrying theH-2 complex of an intermediate responder (129) on a low-responder (B10) background, were low responders. Studies employing different F₁ hybrids and segregating generations of 129/J and 6M mice indicated that differences in responsiveness of those two strains depend on alleles at a single locus, loosely linked to theH-2 complex. These results lend further support to the previously advanced concept that the expression of theIr-Thy-1 allcles controlling the response to the Thy-1.1 antigen is influenced by the alleles at theIr-5 locus. In addition, studies employing F₁ hybrids produced through matings of 129/J, 6M, C3H.B10 and C57BL/6J mice to a panel of inbred strains suggested that in regard to the responsiveness to the Thy-1.1 antigen, 129/J and 6M mice are phenotypically, and presumably genotypically, similar to C3H.B10 and C57BL/6J mice, respectively.     

Genetic analysis of anH-2 mutant,B6.C-H-2 ba,using cell-mediated lympholysis: T- and B-cell dictionaries for histocompatibility determinants are different

B6.C-H-2 ^ba [H (z1)] is a mutant derived from C57BL/6. The two strains mutually reject their skingrafts and are incompatible in the mixed leucocyte reaction (MLR) and in cell-mediated lympholysis (CML) assays. They are serologically indistinguishable. This report shows that H(z1) carries a new, privateK end CML specificity clearly distinguishable from that of B6 by a third party strain, HTG. Antisera directed against the private H-2K specificity of B6 present on H(z1) cells) can block CML between the two strains in either direction. The new CML specificities of H(z1) cross-react with (public) CML specificities controlled by bothK andD regions of other unrelated haplotypes. The results suggest that H(z1) carries a mutation in theH-2K locus itself or in a closely linked gene, the product of which is also physically associated with the H-2K molecule corresponding to the cis-configuration of the alleles in both loci. These findings indicate that T- and B-cell dictionaries for histocompatibility determinants are different.     

H-2 restriction of cytolysis after immunization of minorH congenic pairs of mice

Mice of three congenic resistant lines differing from C57BL/10 at theH-3, H-13, H-7, andH-8 minor histocompatibility loci were used to immunize, and were immunized with, C57BL/10. Cytotoxic cells which were capable of causing rapid lysis of cells from the immunizing strain were generated at least one-way in all combinations tested. In order for a target to be susceptible to cytolysis, it had to carry both the sameH-2 ^b haplotype and the same differential minor histocompatibility alleles as the immunizing strain. That is, B10.C(47N) (H-2 ^b ,H-7 ^b ) anti-C57BL/10 (H-2 ^b ,H-7 ^a ) cytotoxic cells lysed C57BL/10 targets but not B10.BR (H-2 ^k ,H-7 ^a ) targets, nor BALB.B (H-2 ^b ,H-7 ^b ) targets. Crossreactions in the cytotoxic assay suggest that theH-3, H-13 congenic pair —B10.LP and C57BL/10 —may differ in at least two more minor histocompatibility loci which have not yet been defined. Although 6 x 10⁶6 C57BL/10 lymphoid cells primed B10.D2(57N) (H-8 ^b ) mice for a secondary in vitro cytotoxic response, a tenfold higher dose apparently made them tolerant. It is concluded that all minor histocompatibility differences can generate cytotoxic T cells which show specificity both for the minor and major histocompatibility alleles.     

Multigenic control of immune responses of inbred mice against the terpolymers poly(Glu57Lys38Ala5) and poly(Glu54Lys36Ala10) and linkage withH-2 haplotype

Results of immunizations of recombinant inbred and congenic strains of mice with the random polymers poly(glu⁵⁷ lys³⁸ala⁵) or GLA⁵ and poly(glu⁵⁴lys³⁶ala¹⁰) or GLA¹⁰ indicate that there is an association of the responsiveness with theH-2 haplotype. Although the C57BL/6J mice (H-2 ^b haplotype) are “non responders”, the C57BL/6By originally derived from mice of the same haplotype are responders. The immune response pattern of recombinant strains carrying haplotypes derived by crossing over within theH-2 complex indicate that the responsiveness is under control of anIr gene which maps to the left of theIB subregion. Studies with the backcross mice indicated multigenic control of the responsiveness, with one locus beingH-2 linked and another locus segregating independently ofH-2.     

A detailed serological analysis of a xenogeneic anti-Ia serum

Rabbit anti-mouse-Ia serum was raised against Ia specificities present in CBAJH (H-2 _k) serum. This xenogeneic antiserum was considered to react with similar specificities to those detected by mouse anti-Ia^k alloantisera and more evidence is now presented for this contention. By absorption, the xenogeneic antiserum was found to react with spleen, lymph node, bone marrow, and thymus, reactions similar to that found with the allogeneic anti-Ia^k antiserum. Furthermore, red cells, platelets, brain, kidney, and liver could not absorb the activity from the xenogeneic antiserum, demonstrating the selective tissue distribution of the antigens reactive with this serum. This reactive population was previously shown to consist of B cells and a subpopulation of T cells. In a backcross study of (C57BL/6 × A)F₁ × C57BL/6, the rabbit anti-Ia and mouse anti-Ia reactions were found to segregate together, and some evidence for the genetic regulation of the expression of Ia specificities was also found. By direct testing, and by absorption testing using a number of strains, the xenogeneic antiserum was shown to contain high titers of antibody to Ia.1, 3, 7, 15, and 17; lower titers to Ia.19, and 22; little antibody to Ia.18, and no reaction for the private specificity Ia. 2, although the multiple absorptions required to define these specificities may have observed some reactions. The data indicate that the xenogeneic and allogeneic anti-Ia_k antisera recognize similar Ia determinants, which map to theLA, IE andIC subregions of theH-2 complex. These have been given the same specificity designation as the allogeneic specificities, but they are separately identified by a prime (').     

Enhanced in vitro cytotoxic anti H-2 responses in the presence of Ia antigens

Because surface Ig and Ia antigens cap independently, A.TH anti-A.TL serum combined with the indirect immunfluorescence technique could be used to test defined murine cell populations ofH-2 ^k haplotype for the presence of Ia antigens. Mitogen induced T- and B-cell derived blast cells, purified by velocity sedimentation at 1g, were tested for the expression of Ia^k antigens and then used both as stimulator cells and as target cells, in primary and secondary in vitro cytotoxic allograft responses. Fibroblasts, cortisone-resistant thymocytes, and nylon column purified splenic T cells were also included in these tests. Ia antigens were detected on 100% of LPS-induced blast cells, on 20%–30% of ConA-induced blast cells (100%Θ Thy-1 or antigen positive), but only to 5%–10% on PHA-blasts (100% Thy-1 antigen positive). Fibroblasts and nylon column purified splenic T cells were essentially Ia negative. Ia-positive allogeneic stimulator cells induced a far stronger in vitro cytotoxic T-cell response compared to Ia-negative stimulator cells; that is, there was a positive correlation between the expression of Ia antigens on the stimulator cells and the magnitude of cytotoxicity induced. This correlation was restricted to primary allograft responses. Ia antigens could not be detected as a target for killing in the cytotoxic effector phase, using both different target cells as well as the approach of “PHA dependent lysis” for detecting cytotoxic T lymphocytes.     

The mouse primed lymphocyte typing (mPLT) test

A murine primed lymphocyte typing (mPLT) assay, based on the sequential selective isolation of specific immunocompetent, alloantigen-reactive T blast cells, has been utilized to define the H-2-associated lymphocyte-stimulating (LS) determinants. Data obtained using mPLT cells indicate that both the Ia molecules of the J region and the SD molecules of theK or D regions possess LS determinants. Isolated Ia molecules as well as isolated SD molecules induce mPLT cell proliferation irrespective of the genetic background, thus revealing that both classes of H-2 LS antigens function in an autonomous manner. Restimulation data of mPLT cells sensitized toI-region gene products indicate that the LS determinants of the Ia molecules are the Ia specificities. However, whereas subregionI-E (I-C) determines one stimulating moiety, ia.7, subregionI-A determines multiple stimulating Ia determinants associated with each allelic product. Genetic analysis, in combination with known serology, suggests that each allelic product of theK andD regions possesses a unique LS determinant. Based on specific cross-reactivities exhibited by mPLT cells sensitized against SD molecules, the recognition of the SD-associated LS determinant appears to be distinct from the recognition of SD specificities by antibody and recognition of the target moiety by cytotoxic T lymphocytes. Thus, this mPLT assay provides a positive approach to defining the H-2 LS determinants as well as a technique for isolating cells with functionally restricted, clonal responses. Furthermore, we propose here a nomenclature for the designation of mPLT-defined LS determinants.     

Evidence for a third,Ir-associated histocompatibility region in theH-2 complex of the mouse

Skin grafts transplanted from B10.HTT donors onto (A.TL × B10)F₁ recipients are rapidly rejected despite the fact that the B10.HTT and A.TL strains should be carrying the sameH-2 chromosomes and that both the donor and the recipient contain the B10 genome. The rejection is accompanied by a production of cytotoxic antibodies against antigens controlled by theIr region of theH-2 complex. These unexpected findings are interpreted as evidence for a third histocompatibility locus in theH-2 complex,H-2I, located in theIr region close toH-2K. The B10.HTT and A.TL strains are postulated to differ at this hypothetical locus, and the difference between the two strains is explained as resulting from a crossing over between theH-2 ^t1 andH-2 ^s chromosomes in the early history of the B10.HTT strain. TheH-2 genotypes of the B10.HTT and A.TL strains are assumed to beH-2K ^s Ir ^s / ^k Ss ^k H-2D ^d andH-2K ^s Ir ^k Ss ^k H-2D ^d , respectively. Thus, theH-2 chromosomes of the two strains differ only in a portion of theIr region, including theH-2I locus. The B10.HTT(H-2 ^tt) and B10.S(7R)(H-2 ^th) strains differ in a relatively minor histocompatibility locus, possibly residing in theTla region outside of theH-2 complex.     

Susceptibility to db gene and streptozotocin-induced diabetes in C57BL mice: control by gender-associated,MHC-unlinked traits

H-2 haplotype differences distinguish the related C57BL/KsJ (BKs) and C57BL/6J (B6) inbred strains. BKs mice are more susceptible to diabetes induction by a recessive obesity gene, diabetes (db), or by multi-dose streptozotocin (MSZ) administration. The purpose of this study was to evaluate whether the H-2 differences were the important genetic background modifiers determining inbred strain susceptibility or resistance to these diabetogenic stresses. Diabetes susceptibility of BKs.B6-H-2 ^b congenic mice was compared with that of the parental BKs and B6 stocks. In addition, diabetes severity was studied in (B6 × BKs)F₁ and F₂ db/db mice and an H-2 segregation analysis was performed. BKs susceptibility genes expressed in a dominant fashion in the F₁ generation, and were transmitted to F₂ db/db males without apparent segregation. No association between H-2 ^b haplotype and B6-type diabetes resistance was found in response to either the db mutation or to MSZ. Insulitis, associated with development of hyperglycemia in BKs males, also occurred in the H-2 ^b congenic stock. However, an apparent interaction between H-2 ^b haplotype, the db mutation (on chromosome 4), and male gender (Y chromosome?) was indicated by a segregation ratio distortion in recovery of this genotype. A more moderate diabetes in some F₂ db/db females suggested that non-MHC-linked genes controlling sex steroid metabolism were the important determinants of diabetogenic sensitivities in the C57BL stocks. In support of the latter, strain differences were demonstrated in activity levels of steroid sulfatase, which is regulated by a sex-linked gene likely expressed on both the X and Y chromosome, and which may control tissue levels of active androgens and estrogens. We show that the diabetes-susceptible F₁ hybrids exhibit the higher activity associated with the BKs strain.     

Isolation and characterization of murine Ia antigens

The isolation and characterization of Ia antigens from both lymphoid and nonlymphoid cells was attempted by SDS-polyacrylamide gel electrophoresis of radiolabeled, NP-40 solubilized, and anti-Ia precipitated lysates. The profiles obtained indicate that membrane proteins with a molecular weight of approximately 30,000 can be isolated from peripheral B but not from peripheral T cells. Ia antigens cannot be immunoprecipitated from cortisone-resistant thymocytes, total thymocytes, allogeneically activated T cells, Con A stimulated T cells, and anti-Ig immunoadsorbent purified T cells. Ia antigens seem to comprise only 1%–2% of labeled splenic intracellular and membrane-associated proteins. They differ from H-2 antigens and immunoglobulin H and L chains with respect to size and serological reactivity. Ia antigens cannot be found to be secreted from lymph node cells or splenocytes into the extracellular incubation media. Tissue distribution studies indicate that Ia antigens are present on macrophages, fetal liver cells, epidermal cells, and bone marrow cells. They have not been found on such tumor cells as myelomas, teratomas, and lymphocytic leukemias.     

Genetics of histocompatibility in mice

Twenty-five new congenic lines with distinctive BALB/cBy-strain histocompatibility alleles introduced onto the C57BL/6By-strain background by a regimen of backcrossing and tailskin grafting have been established. Twenty-one of the histocompatibility loci represented by these lines are new, while four duplicate theH-1, H-2, H-7, andH-8 loci identified by Snell.