Study ofH-2 mutations in mice

The serologically defined H-2.5 specificity was tested on spleen cells and red blood cells (RBC) of theH-2 ^b haplotype and a number of its mutants. Thebm8 (bh) mutant was barely distinguishable fromb in a variety of tests made. On spleen cells ofbm1 (ba) the H-2.5 specificity seemed to be unchanged, while it was virtually absent from RBC of this mutant. Mutantsbm4 (bf),bm5 (bg1), andbm6 (bg2) were similar tobm1, with slight differences between them. The mutantbm3 (bd) retained an unchanged quantity of H-2.5 on its spleen cells, while the specificity was substantially increased on its RBC. The H-2.5 ofbm3 is not identical to that ofH-2 ^a . Possible mechanisms causing differential serology of theH-2 ^b mutants are discussed.     

Genetic control ofH-2 alloantigens as inferred from analysis of mutations

A number of studies of phenotypic effects of anH-2D mutant, B10.D2(M504), have been reported by different laboratories. Their results show that lymphocyte-defined (LD) and serologically-defined (SD) functions of an antigenic molecule can both be controlled by a single gene,H-2D. Possible explanations of the observed phenotypic effects of 504 and other knownH-2 mutations are also discussed.     

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.     

Studies ofH-2K b mutant mice

Three newH-2 ^b mutant strains, B6.C-H-2 ^bm9 , B6.C-H-2 ^bm10 and B6.C-H–2 ^bm11 , are described. The three mutant strains are of the gain and loss type as they reject skin grafts reciprocally with the parental C57BL/6Kh. The mutations, which arose independently, are all allelic at the same locus as 11 other mutant strains already described. By complementation and other studies the mutated gene has been shown to beH-2K ^b . The strains were typed directly and by absorption with antisera specific for H-2K^b and H-2D^b private and public specificities and for Ia^b specificities. Each strain typed differently with these sera. The strain B6.C-H-2 ^bm9 was found to be serologically identical with C57BL/6. The strains B6.C-H-2 ^bm10 and B6.C-H-2 ^bm11 were found to have alterations in the private H-2K^b specificity, H-2.33, and in the public specificity, H-2.5, but to a different extent. B6.C-H- 2^bm10 had a marked decrease in the amount of H-2.33 expressed on the splenic cell surface as compared to C57BL/6 and also has a marked decrease in the expression of H-2.5 on both spleen and red blood cells. In comparison, B6.C-H-2 ^bm11 has a decrease in the expression of H-2.33 but an increase in the expression of H-2.5 on both splenic and red blood cells. The other H-2^b specificities appeared to be unaltered as compared with C57BL/6.     

Immune response to calf collagen type I in mice: A combined control ofIr-1A and nonH-2 linked genes

The genetically controlled immune response to calf skin collagen type I in mice could be demonstrated to be governed by at least two genes. One is linked to theH-2 complex and located within theIA subregion. High-responder alleles areH-2 ^b ,H-2 ^f , andH-2 ^s . The other gene(s) is not linked to theH-2 complex and high-responder allele(s) are found in the genome of B10 mice but not in the genome of DBA mice. There are strong indications that theIr-1A gene controls the response at the T-cell level, whereas it is assumed that the background gene(s) control the immune response at a different level.     

Genetic and structural characterization ofH-2-controlled allelic forms of murine C4

The patterns of expression of several types of genetic variation in murine C4 were investigated. Dominance was assessed forS-region-determined differences in molecular weight of the C4 α-chain fromS ^w7 strains relative to all other strains examined and in C4 hemolytic titers. Codominant expression in F₁ hybrids was shown for both of the above variations. Comparison of tryptic peptide profiles of radiolabeled C4β-chains encoded by differentS regions revealed differences in their primary structures. The demonstration of codominant expression for the variant C4 traits examined and the evidence from tryptic peptide maps for haplotype differences in C4 primary structure strongly support the hypothesis that polymorphism of murine C4 is controlled by structural genes which are located in theS region.     

Genetic control of sensitivity to experimental adjuvant arthritis in mice of inbred lines

Genetic control over sensitivity to experimental adjuvant arthritis was studied in different strains of inbred, recombinant and congeneic mice. The development of adjuvant arthritis is genetically regulated, with sensitivity to adjuvant arthritis controlled by H62-complex. The genes controlling sensitivity to adjuvant arthritis were shown to be located in (S-region) H-2 system.     

Detection of two allotype-(Ig-1)-linked minor histocompatibility loci by the use ofH-2-restricted cytotoxic lymphocytes in congenic mice

Cytotoxic lymphocytes (CTL) were generated betweenIg-1-congenic strains BALB/c(H-2^d,Ig-1^a) andC.B-17(H-2^d,Ig-1^b) by cross-immunization in both directions and rechallenge in vitro. The effector cell populations specifically lysed target cells sharing both theH-2 haplotype and theIg-1 allele of the sensitizing strain. B- and T-cell blasts were equally good targets, suggesting thatH-2-restricted cytotoxic lymphocytes are not directed against serologically defined conventional allotypic determinants, but probably against minor histocompatibility antigens controlled by genes linked to theIg-1 complex. Competition experiments using cold target cells from a series ofIg-1^b-congenic strains of the BALB/c background (BAB-14, C.B-17, C.B-26) revealed two not yet described minor histocompatibility loci linked to theIg-1 complex: We could demonstrate that BALB/c anti-C.B-17 effector cells recognize at least two distinct antigenic determinants on C.B-17 target cells, but only one on target cells from BAB-14, which carries a recombinantIg-1 complex. From these results we conclude that one of the minor histocompatibility antigens, designated as H(C_H), is encoded by a gene linked to the heavy-chain constant-region (C_H) genes, whereas the second minor histocompatibility antigen, designated as H(V_H), is coded for by a gene linked to the heavy-chain variable-region (V_H) genes. These two new genetic markers may be useful for further analysis of the mouseIg-1 complex because the analysis of the H(C_H) and H(V_H) genes may facilitate the search for recombinants in that chromosomal region.     

Genetic control of interleukin-2 production in inbred mice

BALB/c mice (H-2d haplotype) produced IL 2 better than C57BL/6 mice (H-2d haplotype). However genetic analysis in F2 generation demonstrated independent segregation of the IL 2 production intensity and H-2 haplotype. Investigation of the IL 2 production intensity in BALB/c, C57BL/6 and their F1 and F2 generation revealed that this was controlled by only one gene.     

Genetic control of glucuronidase in mice

Two electrophoretically distinct components of glucuronidase have been resolved in extracts of murine liver. A mutation which results in a ten-fold reduction in liver glucuronidase activity leads to a reduction in intensity of both components. Since the substrate dependencies of both mutant (gg) and wild-type (GG) glucuronidase have previously been shown to be identical, it is suggested that the mutation results in a decreased concentration of liver glucuronidase molecules. Furthermore, the anodal electrophoretic component is shown to be preferentially localized in lysosomes, while the cathodal component is primarily microsomal. The difference in mobility of the two components may reflect a difference in membranous elements attached to the extracted glucuronidase molecule.This paper was presented at a symposium entitled Genetic Control of Mammalian Metabolism held at The Jackson Laboratory, Bar Harbor, Maine, June 30–July 2, 1969. The symposium was supported in part by an allocation from NIH General Research Support Grant FR 05545 from the Division of Research Resources to The Jackson Laboratory.This investigation was supported by a grant from the Pharmaceutical Manufacturers Association Foundation.     

Genetic control of catalepsy in mice

Pinch-induced immobility (catalepsy) was studied in mice of 9 inbred strains. CBA mice were found to be different from those of other strains both by the highest percent of cataleptics (56%) and by the highest duration of immobility. The Mendelian analysis of predisposition to catalepsy was performed on CBA and AKR mice strains contrasting in this feature. Reciprocal F1 hybrids did not display any catalepsy. Manifestation of cataleptics in the F2 and in CBA x F2 backcrosses suggested that catalepsy was inherited as a recessive, monogenic, autosomal feature.     

Genetic loci for diet-induced atherosclerotic lesions and plasma lipids in mice

Genetic factors independent of those affecting plasma lipid levels are a major contributor to risk for atherosclerosis in humans, yet the basis for these is poorly understood. This study examined plasma lipids and diet-induced atherosclerosis in 16-month-old female mice of strains C56BL/6J and DBA/2J. Mice of the parental strains, from recombinant inbred strains derived from these (BXD RI), and F₂ progeny were fed an atherogenic diet for 16 weeks, beginning at 1 year of age. This induced atherosclerotic lesion formation in both parental strains, accompanied by increased plasma LDL levels. However, individual BXD RI strains and the BXD F₂ mice demonstrated a range of atherosclerotic lesion formation that was not or at best weakly correlated with plasma lipid levels. Quantitative trait locus (QTL) analysis of the BXD F₂ mice identified a locus with significant linkage (lod 4.5) for aortic lesion size on Chromosome (Chr) 10 that was independent of plasma lipids. Other loci with suggestive or significant linkage for various plasma lipid measures were identified on Chr 2, 3, 4, 5, 6, 7, 11, and 17. In this intercross, the genes primarily influencing atherosclerosis are distinct from those controlling plasma lipid levels.     

Genetic control of two independently segregating loci in mice to the sequential polypeptide (Tyr-Ala-Glu-Gly)n

Immune responses to the sequential helical polypeptide (Tyr-Ala-Glu-Gly)_n [(T-A-G-Gly)_n] in mice is under the control of at least two separate genes. One gene,Ir-(T-A-G-Gly)-1, which is linked, toH-2 haplotypesb, f, andr, controls the ability to respond and maps to theIA subregion. A non-H-2-linked locus,Ir-(T-A-G-Gly)-2. is responsible for the magnitude of the antibody response, which is expressed as a high, intermediate, or low level of antibody production. The antibody produced is of the IgG class, and does not crossreact even with the closely related sequential helical polymer (Tyr-Glu-Ala-Gly)_n [(T-G-A-Gly)_n]. Immune responsiveness is a dominant trait,i.e., the F₁ generations of responder x nonresponder crosses are responders. However, the data obtained with both backcross populations are not easily interpretable. The contribution of the B-cell mitogenic activity of the sequential polymer to activation of suppressor T cells is considered as a possible explanation for the backcross results. The possible role of the Ia. W29 specificity present in the mouse strains responding to both (T-A-G-Gly)_n and calf skin collagen type I in modulating responses to the polymers is discussed.     

Genetic control of lymphocyte antigens in sheep: TheOLA complex and two minor loci

Lymphocytotoxic reagents allowed us to define 11 lymphocyte factors in sheep. After a genetic control of monospecificity had been made, a genetic study based on 400 crossings indicated that nine factors are transmitted in two haplotypes containing 0.1 or 2 factors. The linked factors of the bifactorial haplotypes are the products of two genes at two closely linked loci,OLA- A andOLA- B, having a recombination rate of about 0.6%. The nine factors are the products of fiveOLA- A and fourOLA- B alleles. Allelic frequencies at the two loci, ranging from 0.05 to 0.23 were obtained by two methods. A linkage disequilibrium between the loci is described. Among the possible causes of this, inbreeding is excluded, whereas selective pressure or more probably old fusions between sheep populations must be retained. A tenth factor (frequency 0.33 to 0.35) has a 26% recombination with OLA factors; its locus (OL-X) would be on the same chromosome but very far from theOLA complex. An 11th factor (frequency 0.30) is probably independent ofOLA; its locus (OL-Z) may be on another chromosome. The two linkedOLA loci give evidence of a major histocompatibility complex in sheep; the observed linkage disequilibrium allows one to foretell certain applications in phylogeny and perhaps in selection.     

Study ofH-2 mutations in mice VI. M523, a newK end mutant

A newH-2 mutation was found in a mouse belonging to CBA/CaLacSto (H-2 ^k ) strain and designated 523, the proposed haplotype symbol for which isH-2 ^ka . The line CBA.M523 carries this mutation and is fully congenic with the parental strain, except for the mutant site 523. The mutation 523 is located within theK- end of theH-2 gene complex. Phenotypically, it causes prompt skin graft rejection and pronounced graft-versus-host activity in strain combination CBA/Sto⇄C-BA.M523. Attempts to produce active alloantisera in the same strain combination have so far been unsuccessful.     

Expression of the H-Y Antigen on thymus cells and skin: Differential genetic control linked toK end ofH-2

The strength of the H-Y antigen on thymus cells and on skin was compared in differentH-2-congenic mouse strains using a host-versus-graft reaction popliteal lymph node assay, and skin grafts from males of parental strains grafted to F₁ hybrid females. The results revealed considerable differences in the strength of the H-Y antigen among different congenic strains; these differences demonstrate the effect of theH-2-linked gene on the expression of the H-Y antigen. The linkage withH-2 was also confirmed in tests with segregating F₂ generations. In the strains bearing recombinantH-2 haplotypes, the strength of the H-Y antigen is similar to that of parental strain from which the recombinant received itsK end, and the responsible gene (or genes) map to the left ofI-C. The effect of theH-2-linked gene(s) on thymus cells and skin is different. The gene linked to theK end ofH- 2^b determines a strong H-Y antigen on thymus cells, but a relatively weak H-Y antigen on skin. The gene linked to theK end ofH- 2^k determines a weak H-Y antigen on thymus cells, but a strong H-Y antigen on skin. The gene linked to theK end ofH- 2^d determines a weak H-Y antigen on both thymus cells and skin. Our observations raise the possibility that the structural gene for the H-Y antigen is linked toH-2. Alternative (but not exclusive) explanations invoke regulatory effects ofH-2 on the expression of the H-Y antigen, possibly by means of the control of the cellular andogen receptors.     

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.     

Genetic control of immunologic unresponsiveness to adjuvant-free solutions of beta-D-galactosidase. I. Inheritance of the Ir-Z1 and ir-Z2 loci in mice.

Two genetic loci, Ir-Z1 and ir-Z2, controlling the immune response to adjuvant-free bacterial beta-D-galactosidase (Z) are present in inbred mouse strains SJL/J and CE/J, respectively. Each locus segregates as a single, autosomal gene: Ir-Z1 as dominant and ir-Z2 as recessive. The response is characterized by production of activating and precipitating IgG. Maximal levels of circulating IgG occur between 16 and 20 days after immunization with a single, 50-microgram dose of enzyme. Failure of proteins other than Z to elicit an immune response indicates that the Ir-Z control is specific for determinant(s) of this enzyme. The immunogenicity of beta-D-galactosidase preparations cannot be attributed to either the catalytic activity of the enzyme or adjuvant contamination. Non-responder mice acquire immunologic memory without detectable increase in circulating specific IgG under the same conditions that elicit antibody production in responder strains.