Polygenic control of the immune response to F antigen

The ability to produce an autoimmune response to F antigen in mice is underH-2-linked and non-H- 2-linkedIr-gene control. There is an absolute requirement for ak allele atH-2K orI-A in order to produce anti-F antibodies. Low and high responsiveness is controlled by a non-H-2-linkedIr gene which behaves in a similar fashion toIr-3, in that as the dose of F-antigen is lowered, low responders behave as high responders and vice versa. This conversion from low to high responsiveness also occurs within a month after ATX.— Most F₁ hybrids derived from (responder x nonresponder) parents bearing identical F-types behave as dominant nonresponders. As a result of ATX, such F₁ mice convert to high responders. This conversion occurs if the animals are not immunized before day 90. If they receive F antigen prior to that time, they remain nonresponders for 7–9 months. One F₁ combination — AKD2 — behaves as a dominant high responder. Genetic analysis showed that in the presence of ak allele atH-2K orI-A, a non-H-2-linkedIr gene inherited from the AKR mice determined dominant responsivenss. No manipulation of the immune response or combination of genes converted nonresponders lacking ak allele into responders. Such complex genetic control suggests regulation by a number of independently segregating loci whose function it is to limit the autoimmune response to F antigen.     

Interaction ofH-2 and nonH-2 linked genes in the regulation of antibody response to a threshold dose of sheep erythrocytes

The antibody response to a threshold dose (¹⁰) of SE was studied in the High responder line (H) and the Low responder line (L) of mice obtained by bidirectional selective breeding for the character quantitative agglutinin response to an optimal dose of SE, and in interline hybrids: F₁, F₁ and both backcrosses. Whereas the interline difference in agglutinin responses at the optimal dose is due to the additive effect of about ten independently segregating loci, one of which isH-2 linked, the responsiveness to the threshold dose is determined by the effect of two loci. The direction of the dominance effect also varies with the antigen dose: high responsiveness is partially dominant at the optimal dose while at the threshold dose nonresponder character is partially dominant. The role of theH-2 linked locus was investigated. It has been demonstrated that on an identical background (equivalent to that of F₁ hybrids) this locus is responsible for 12% of the interline difference at the optimal antigen dose, and for 61% at the threshold antigen dose. For the two antigen doses, the quantitative effect of theH-2 locus is in agreement with the estimate of the number of loci obtained by variance analysis. The intervention of a second gene, non-H-2 linked, in the regulation of responsiveness to 10⁶ SE is demonstrated by appropriate assortative matings. The interaction between the two genes is discussed.     

Immune response to the H-X antigen on P815-X2

In a preceding report, the detection of an H-2-linked immune response to the H-X ^d antigen on the P815-X2 mastocytoma was demonstrated by the significantly increased survival of (C57BL/6 × DBA/2)F₁ (B6D2F1) male hybrids (H-X ^b ) compared with female siblings (H-X ^{b/H-X d} ) after injection with the histocompatible tumor (H-X ^d ). This interpretation was supported by the absence of this sex effect in reciprocal D2B6F1 hybrids (H-X ^d and H-X ^{d/H-X b} ). Additional findings presented in this paper support the conclusion that this sex effect is due to a true immunological response to H-X ^d : (a) Reciprocal (DBA/2 × C57BL/6 H-2 mutant)F₁ hybrids, as well as D2B6F1, failed to exhibit the sex effect: (b) the demonstration of the sex effect in (BALB/c × DBA/2)F₁ and (BALB/c-H-2 ^dm2 × DBA/2)F₁ hybrids and in (C57BL/10 × DBA/2)F₁ hybrids was consistent with the known H-X incompatibilities between the strains BALB/c and DBA/2 and C57BL/10 and DBA/2, respectively, previously demonstrated by skin grafting; and (c) the sex effect was not abrogated by castration of male B6D2F1 hybrids. Variability in the presence or absence of the sex effect was observed in various [recombinant inbred (RI) × DBA/2]F₁ hybrids and may be attributed to the influence of a regulatory non-H-2 gene which is closely linked to the gene coding for mouse kidney-androgen-regulated protein (KAP) but androgen-independent, or to variability in inheritance of the H-X ^b allele among the RI lines. It is proposed that the P815-X2 model may be utilized to type RI lines derived from a cross between C57BL/6 and DBA/2 for their H-X genotypes.Abbreviations B C57BL/6 origin allele - B6 C57BL/6 - B10 C57BL/10 - B6D2F1 (C57BL/6 × DBA/2)F₁ - B6 ^m D2F1 (C57BL/6 H-2 mutant × DBA/2)F₁ - bm10 B6.C-H-2 ^bm10 - C BALB/c - D DBA/2 origin allele - D2 DBA/2 - dm2 BALB/c-H-2 ^dm2 - H-X X chromosome-determined histocompatibility antigen of the mouse - Ir gene, immune response gene - KAP kidney androgenregulated protein - MST median survival time - RI recombinant inbred - SDP strain distribution pattern     

Comparison of patterns of hybrid resistance to the BALB/c plasmacytomas LPC-1 and MPC-11

Summary Patterns of genetic control of hybrid resistance to the BALB/c plasmacytoma LPC-1 were studied for comparison with those to MPC-11, a plasmacytoma investigated previously. The overall patterns of hybrid resistance to the two tumors were similar, i.e., hybrids between BALB/c and BALB congenic resistant (CR) strains, A and A CR strains, SJL and DBA/2 were as susceptible to LPC-1 as BALB/c mice themselves, whereas hybrids between BALB/c and AKR, C57BL/Ks, DBA/1, C57BL/6 (B6), C57BL/10 (B10) and B10 CR strains were resistant to LPC-1 as previously shown with MPC-11. Heterozygosity within the H-2 complex alone was insufficient for resistance to either tumor. Among hybrids between BALB/c and the B10 CR strains, however, the presence of certain H-2 haplotypes influenced the degree of resistance seen and this H-2 effect was different for the two tumors. A sex effect on resistance to LPC-1, but not to MPC-11, was seen among F₁ hybrids between BALB/c and DBA/1 although not in any other F₁ hybrids. Among ((B10×BALB/c)F₁×BALB/c) and (BALB/c×(B10×BALB/c)F₁) and ((BALB/c×B10)F₁×BALB/c) and ((BALB/c×B10)F₁×BALB/c) backcross mice, however, significantly more males than females were resistant to LPC-1 and the results of this study are compatible with the idea that in F₁ hybrids between BALB/c and B10, resistance to LPC-1 is controlled by two dominant autosomal genes, one of which is sex-limited and neither of which is linked to H-2. In contrast, hybrid resistance to MPC-11 in this cross is controlled by a single gene. Cross-protection experiments indicated that the two tumors share at least one tumor-associated transplantation antigen.     

Non-H-2 and H-2-Linked immune response genes control the cytotoxic T-cell response to H-Y

The immunoregulation of cytotoxic T-cell responses to the male-specific antigen H-Y in mice has been found to be genetically controlled by genes of the major histocompatibility complex (H-2). Responsiveness was mainly confined to H-2 ^b strains, but it has also been found in recombinant strains, F₁ hybrids, and chimeras that carry at least part of the H-2 ^b haplotype. By using a different immunization procedure it has been shown recently that an H-2 ^k mouse strain (CBA) is also able to mount an equivalent H-Y-specific response. We investigate here, by applying this immunization technique, the responsiveness of other H-2 ^k strains and of strains of other independent H-2 haplotypes. Both responders and nonresponders are found in three haplotypes: k, s, and d. The strain distribution pattern of responsiveness shows a combined influence of non-H-2 and H-2 genes. In certain strains there is a high variability in responsiveness between genetically indentical individual animals. We discuss a model of immune response (Ir) gene function which could account for these observations.     

Inheritance of annual habit in celery: cosegregation with isozyme and anthocyanin markers

Summary Vernalization response was determined in an annual and two biennial celery strains, Apium graveolens L. and their F₂ hybrids. Although the annual strain did not require vernalization to bolt, plants exposed to 10°C for 7 days bolted 2 weeks earlier than non-treated plants. Inheritance studies based on F₂ and backcross segregations demonstrate that annual habit in celery is partially dominant over biennial and determined by a single gene designated Hb. Cosegregation studies of this trait with nine isozyme loci and a gene determining petiole anthocyanin pigmentation disclosed the following linkage relationships: Adh-1-Sdh-1-Mdh-1, and Got-1-Mdh-2-Hb-A. The recombination frequency observed for Hb and Mdh-2 was too large to use the latter as a useful marker for annual habit.     

Experimental allergic orchitis in mice

Inbred strains of mice were studied for their susceptibility to the induction of experimental allergic orchitis after sensitization with mouse testicular homogenate in complete Freund's adjuvant accompanied by injections of extract from Bordetella pertussis. Susceptibility to autoimmune orchitis was found to be linked to the major histocompatibility complex in BALB/c and C57BL/10 mice and mapped to genes encoded within the H-2D ^dregion. In five of six groups of bidirectional (susceptible × resistant) F₁ hybrids, H-2D ^d-linked susceptibility was inherited as a dominant autosomal trait. However, in (BALB/cByJ × DBA/2J)F₁ and (DBA/2J × BALB/cByJ)F₁ hybrids, dominant autosomal resistance to the induction of autoimmune orchitis was observed. Backcross analysis between the resistant F₁ hybrid and the susceptible BALB/cByJ parent suggests that a single independently segregating DBA/2J locus is capable of negating H-2D ^d-linked susceptibility, and controls resistance to the induction of autoimmune orchitis.Abbreviations used in this paper BP extract Bordetella pertussis extract - CFA complete Freund's adjuvant - EAO experimental allergic orchitis - Ir immune response - MHC major histocompatibility complex - MLH mouse liver homogenate - MTH mouse testis homogenate - PI pathology index     

Immune suppression genes control the anti-F antigen response in F1 hybrids and recombinant inbred sets of mice

The immune response to the liver protein F antigen which, in the mouse, occurs in two allelic forms, is under sharp immunogenetic control in that only mice that possess the A^k molecule can respond to allo-F antigen. This response has been studied in a number of F₁ hybrids between inbred strains and with recombinant inbred lines all of which express A^k, and which thus enable immune suppression effects to be detected. In the AKXL and AKXD sets, the hybrids with CBA are responders if H-2 ^k/H-2^k, and usually nonresponders if H-2 ^k/H-2^b or H-2 ^k/H-2^d. Although this may be due to gene dosage effects, this cannot be the explanation for the low responsiveness of the H-2 ^k/H-2^b relative to the H-2 ^k/H-2^d mice found in CBA × BXD hybrids. For this, and other reasons, it seems likely that low responsiveness in any mouse possessing a responder A ^k allele is due to suppression, and that this is mediated by the immune suppression effects of the non-H-2 ^k haplotype. These H-2-mediated effects can be modified, both positively and negatively, by background genes. Thus, of the ten H-2^k/H-2^d members of the CBA × AKXD cross, seven are low responders and three are high responders. No other typed marker has the same strain distribution pattern at present. Major unresolved questions, therefore, concern the location and mechanism of action of the background genes and the mechanism of action of the H-2 immune suppression genes.     

Genetically controlled IgM hyporesponsiveness to aK. pneumoniae polysaccharide

Examination of the immune response to aKlebsiella pneumoniae polysaccharide (K47-PS) has revealed that BALB/c mice demonstrate only a very weak primary response to this antigen. The low response does not result from either a peculiar dose response curve for BALB/c mice or from differing optimal antigen concentrations for high and low responder mice. Genetic analysis indicates that this variability of response is explicable assuming two alleles at a single locus; high responsiveness is dominant. Variability of response is probably not linked to theH-2 complex since the low and high responder mice, BALB/c and B10.D2/Sn new line, respectively, share the sameH-2 haplotype (H- 2_d). Tests of F₂s, backcrosses, and appropriate congenics have not shown evidence of linkage to sex, the albinism gene, the genes controlling coat color (agouti, black, brown), or the allotype-constant-region genes. The hyporesponsiveness is apparent only in the primary (IgM) response; hyperimmunization evokes similar antibody titers in high and low responding strains.     

Polymorphism of genes involved in anti-tubular basement membrane disease in rats

Inbred strains of rats differ widely in their susceptibility to interstitial nephritis induced by rabbit renal tubular basement membrane (TBM) preparations. We now report that susceptibility is determined in part by an RTI-linked gene for effector cell responsiveness producing interstitial lesions. Furthermore we also obtained evidence that the gene determining expression of the target TBM antigen is linked to the gene for albinism on the first linkage group. When non-susceptible rats lacking the TBM antigen but having the gene for cellular responsiveness were mated with non-susceptible rats which had the TBM antigen but lacked the gene for cellular responsiveness, the F₁ hybrids were susceptible to the induction of interstitial nephritis. Although strains varied widely in the amount of anti-TBM antibody (αTBM-Ab) they produced, this variation does not appear to be controlled by RTI-linked genes, nor does the isotype or amount of antibody appear to be related to the susceptibility to infiltrating cellular lesions.     

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.     

ORIGIN OF FRAGARIA POLYPLOIDS. II. UNREDUCED AND DOUBLED-UNREDUCED GAMETES

Offspring from natural hybrids between octoploid Fragaria chiloensis (2n = 56) and diploid F. vesca (2n = 14) backcrossed under natural conditions to F. chiloensis were studied. The natural F₁ hybrids themselves were of three kinds: (1) The expected pentaploids which resulted from the union of normally reduced gametes of diploid F. vesca and octoploid F. chiloensis; (2) A hexaploid F₁ hybrid which resulted from the union of an unreduced gamete from diploid F. vesca with a normally reduced gamete from octoploid F. chiloensis; and (3) A 9-ploid F₁ hybrid which probably arose from the union of an unreduced gamete of the octoploid F. chiloensis with a normally reduced gamete of diploid F. vesca. The progenies that resulted from the natural backcrossing of each of the three sorts of F₁ hybrids to F. chiloensis were as follows: The pentaploid F₁ hybrids (2n = 35) yielded mostly 9-ploid offspring from unreduced 5X gametes; a relatively high percentage of 14-ploid plants arising from doubled-unreduced 10 X gametes and a few 2N = ±46 aneuploids from reduced gametes. The hexaploid F₁ hybrid (2n = 42) on backcrossing yielded over 50% 10-ploid offspring with the rest 2n = ±50 aneuploids from reduced gametes. The 9-ploid F₁ hybrid (2n = 63) on backcrossing yielded mostly aneuploids normally distributed about a modal 2n = 59 chromosome class resulting from a 31 chromosome gamete, with a few 2n = 56 and 2n = 63 euploids. The 9-ploids may facilitate diploid Å octoploid introgression. Screening of the open-pollinated offspring from F. chiloensis revealed almost 2% 12-ploid (2n = 84) offspring from the union of the reduced and unreduced F. chiloensis gametes. The probable genomic constitution of the observed novel ploidy levels and those that theoretically may be generated from the known hybrids are presented. The origin of the existing polyploids from diploids through simple unreduction is postulated.     

The genetics of teratocarcinoma transplantation: tumor formation in allogeneic hosts by the embryonal carcinoma cell lines F9 and PCC3

Two cultured lines of murine embryonal carcinoma, F9 and PCC3, have been grafted to a variety of allogeneic hosts. The host strains have been classified by their resistance or sensitivity to these carcinomas. Resistance seems to be immunological in nature.Allograft rejection does not correlate withH-2 haplotype, and seems to be controlled by a limited number of recessive factors, presumably histocompatibility genes. We infer that these factors have limited polymorphism in the mouse species. Recombinational analysis of strain A/He has revealed the presence of a recessive factor linked to theH-2 locus. Tumor resistance of strains C57BL/6 and AKR appears to result from the interaction of dominant or semi-dominant factors in theH-2 region with other recessive elements in the genetic background.Though F₁ hybrids between resistant mouse strains and the syngeneic strain 129 are largely tumor-sensitive, a low level of hybrid resistance to F9 has been observed and shown to be eliminated by X-irradiation.     

Polygenic control of quantitative antibody responsiveness: restrictions of the multispecific effect related to the selection antigen

Among the differences observed between the various high (H) and low (L) antibody responder lines of mice resulting from distinct bidirectional selective breedings, one of the most puzzling is the variation in the multispecific effect, i. e., in the modification of antibody responses to antigens unrelated to those used during the selection. The best examples are the H and L lines of selection IV, selected on the basis of responses to somatic antigen of Salmonella which do not differ in their antibody responses to sheep erythrocytes (SE). However, a wide range of variability is observed in the responses of (H_IV x L_IV)F₂ hybrids to this antigen, and it was therefore hypothesized that distinct groups of genes might regulate antibody responses to SE and the somatic antigen. Indeed, a new selection (IV-A) for anti-SE responsiveness started from these (H_IV x L_IV)F₂ successfully produced a high and a low anti-SE responder line. The results of selection IV-A and the variance analysis of (H_IV-A × L_IV-A)F₂ hybrids are reported. They are roughly similar to those in selection I, also carried out for anti-SE responsiveness. In vivo attempts to identify the major regulatory mechanism which contributes to the interline difference indicate that the efficiency of macrophage accessory function has been modified in selection IV-A, as was observed in selection I, whereas this function did not differ in Hév and Lév lines. Probably in relation to the involvement of macrophage function there is a notable increase of the multispecific effect in selection IV-A when compared with selection IV. The results of selection IV-A demonstrate that responsiveness to heterologous erythrocytes and to somatic antigen of Salmonella are under separate polygenic control operating through distinct regulatory mechanisms. The choice of the selection antigen and immunization procedure is of major importance for defining the gene interaction operating in each selective breeding experiment and the extent of its multispecific effect.Abbreviations used in this paper f. ag. S. flagellar antigen of Salmonella - H high responder line (roman numeral is the selection number) - h₂ heritability - HE human erythrocytes - HoGG horse gamma globulin - L low responder line (roman numeral is the selection number) - PE pigeon erythrocytes - R response to selection - RGG rabbit gamma globulin - S selection differential - s. ag. S. somatic antigen of Salmonella - SE sheep erythrocytes     

H-Y antigen: No evidence for alleles in wild strains of mice

H-Y antigen(s) coded or controlled by the Y chromosome in a variety of wild mouse strains have been compared with those of the inbred laboratory strains C57BL/6 (B6) and C57BL/10 (B10). H-Y antigen(s) were detected by H-2-restricted cytotoxic T cells from B6 and B10 female mice primed in vivo and boosted in vitro with syngeneic male spleen cells: There was no difference in the degree of H-Y specific lysis of male cells from the C57BL strains and of F₁ hybrids or B6 congenic mice carrying the Y chromosome from the wild mouse strains examined. This result indicated that at the level of target cell specificity the H-Y antigen(s) from wild and laboratory strains were indistinguishable. H-Y antigen(s) were also found to be indistinguishable at the level of the in vitro induction of the anti H-Y cytotoxic response: F₁ female mice, primed in vivo and boosted in vitro with homologous F₁ male cells, all made H-Y-specific responses and where it could be examined, the target cell specificity of the anti-H-Y cytotoxic cells showed that B10 male cells as well as the homologous F₁ male cells (where the Y chromosome was derived from the wild strain) were good targets. Finally, possible differences in H-Y transplantation antigens between the wild strains and the B10 laboratory strain were examined by grafting F₁ male mice, the progeny of B10 females, and wild strain males with B10 male skin. These grafts were not rejected during an observation period of more than 9 months. Taken together, neither the cytotoxic data nor the skin graft data provide any evidence for allelism of H-Y even though the mouse strains examined were collected from widely disparate geographical locations.     

B-Cell responses to male-specific antigen(s) in mice

It has been found that B-cell responses to male-specific antigen(s) can be clearly demonstrated by reversed plaque assays. Female mice injected with syngeneic male spleen cells showed significant increases (greater than 100 × in some strains) in the number of immunoglobulin-secreting cells in lymph nodes draining the injection site. There was a variation in B-cell responsiveness between strains and this correlated only partially with previously reported T-cell responsiveness to the H-Y antigen. C57BL (H-2 ^b ) mice were among the most responsive, while CBA (H-2 ^k ), (CBA × C57BL)F₁, and BALB/c (H-2 ^d ) were all much less responsive. These results apparently open up a new approach to the investigation of B-cell responses to male-specific antigen(s).     

Genetic control of murine hemagglutinin formation to H-2.5

When B10.D2 (H-2^d) mice are immunized with lymphoid cells from C57B1/10 (H-2 ^d ) and their antisera tested against B10.A (H-2 ^a ) target cells, only antibodies to H-2.5 are measured. The same is true for immunization of DBA/2 (H-2 ^d ) mice when their antisera are absorbed with B10.D2 cells prior to testing. Irrespective of the dose of immunogen administered, the primary hemagglutinin response of B10.D2 mice is significantly lower than that of DBA/2 mice and (B10.D2 × DBA/2)F₁ hybrids, but the secondary responses are similar. The low responsiveness of B10.D2 mice appears to be determined by a single dominant gene with incomplete penetrance; the gene is not linked to eitherH- 2, Hc, or the immunoglobulin allotype loci. In addition, the H-2.5 hemagglutinin response is susceptible to nongenetic influences. When antisera from B10.D2, devoid of H-2.5 hemagglutinins, were assayed in a complement-mediated cytotoxic test, they contained almost as much anti-H-2.5 activity as did the antisera from DBA/2 mice or (B10.D2 × DBA/2)F₁ hybrids. The possibility is discussed that the locus responsible for the deficient primary hemagglutinin response of B 10.D2 may not be determinant-specific but may affect hemagglutinin responses in general.     

Separating Effects of Gene Flow and Natural Selection along an Environmental Gradient

Genetic differentiation along environmental clines is often observed as a result of interplay between gene flow and natural selection. In order to understand the relative roles of these processes in shaping this differentiation, we designed a study in which we used two approaches that have not previously been combined, the Q _ST–F _ST comparison and crossbreeding. We examined (1) interpopulation phenotypic and genetic (AFLP) variation, and (2) performance of interpopulation hybrids in a common annual Senecio glaucus. Fitness of interpopulation hybrids (F1 and F2) was tested under simulated population natural conditions in terms of aridity and analyzed for a relationship with (1) spatial distance and (2) environmental differences (amount of annual rainfall). While phenotypic variation corresponded to the clinal changes in aridity along population locations, viz. narrower and longer leaves, longer leaf outgrowths and advanced flowering in more arid environments, the F _ST < 0.1 calculated from AFLP data suggested intensive interpopulation gene flow, with little if any contribution of genetic drift. Performance of hybrids in simulated natural environments revealed heterosis in F1, but a hybrid breakdown in F2 generation. These effects were related to both the spatial distance between hybrid parents and their population rainfall differences. The detected clinal phenotypic variation and outbreeding depression in F2 strongly support presence of aridity-induced clinal natural selection, which is matched by the observed Q _ST ≫ F _ST. From this we conclude that Q _ST–F _ST comparison can detect effect of diversifying selection when patterns of phenotypic variation across sampled locations can be reliably predicted from environmental variation.     

Suppressor cell influence in selected strains of inbred rats: I. Strain-dependent mitogen- and antigen-related low responsiveness

Lymphocytes derived from Lewis (LE), Brown-Norway (BN), or the F₁ hybrid (LBNF₁) rats respond in vitro to the mitogens phytohemagglutinin, concanavalin A, and pokeweed mitogen. The magnitude of the response, as determined by incorporation of ³H-thymidine, ¹⁴C-adenine, and ³H-leucine, was highest for LE and lowest for BN animals. These proliferation response differences were observed for lymph node lymphocytes and peripheral blood lymphocytes. The response to antigen, as measured by lymphocyte transformation, reflected the mitogen responsiveness of the strains tested, i.e., LE animals responded to a higher level than did BN animals. Equivalent levels of antibody were found in all animals immunized with antigen. In addition, BN rats are suppressed to a greater magnitude than are LE rats when both strains are primed, rechallenged, and assayed via lymphocyte transformation to the test antigen.     

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.