Genetic linkage between immune response to GAT and the fate of RSV-induced tumors in chickens

Recent studies suggest that the gene locus controlling the fate of tumors induced by Rous sarcoma virus (RSV) is linked to theB histocompatibility complex. Birds carrying the dominant allele regress the tumor; homozygous recessives being unable to do so, develop large tumors and die. These are called progressors.The Bryan strain of RSV was inoculated into 220 6 week old Leghorns homozygous forB ¹ B ¹,B ² B ², orB ¹⁹ B ¹⁹ of which the percentages of progressors were 79, 22 and 56, respectively. The balance of each were regressors and survived.TheB ¹ B ¹ test birds were derived from special matings, i.e., high and low immune responders to the amino acid polymer, GAT. Of 67 tests progeny of theB ¹ B ¹ GAT-low mating, 63 or 94% proved to be progressors, and 6% were regressors. Of 84 test progeny of theB ¹ B ¹ GAT-high matings, 67% were progressors, and 33% were regressors. The difference between the high and low GAT responders is highly significant and indicates that the locus controlling the fate of RSV-induced tumors is closely linked to the locus controlling immune response to GAT. The latter maps within theIr region of theB histocompatibility complex.     

Lymphoma induced by herpesvirus: Resistance associated with a major histocompatibility gene

Studies with crosses of inbred chicken lines demonstrate that resistance to Marek's disease, a herpesvirus-induced lymphoma of chickens, is associated with an allele (B ²¹) of the major histocompatibility locus (theB locus). TheB ²¹ allele is thus the first genetic marker for resistance to herpesvirus-induced neoplastic disease, and our studies suggest the means whereby similar associations might be found in man.     

Biochemical confirmation of recombination within the B-G subregion of the chicken major histocompatibility complex

Analysis of the B-G antigens of eight chicken major histocompatibility complex (B) system recombinant haplotypes by high resolution two-dimensional gel electrophoresis has provided evidence for the transfer of the complete B-G subregion in seven cases. In the eighth, a partial duplication within the B-G subregion appears to have occurred. In this recombinant, the entire array of polypeptides associated with one parental allele, B-G ²³ is expressed together with nearly the entire array of B-G polypeptides of the other parental haplotype, B ². This compound polypeptide pattern corroborates the serological evidence for a partial duplication within the B-G subregion and provides indirect evidence for the existence of multiple loci within B-G and for a means by which polymorphism may be introduced into the chicken major histocompatibility complex.     

Segregation of allotypes in a strain of chickens homozygous for theB locus

Sublines homozygous for alleles controlling IgM and IgG allotypes at two linked loci (M1 andG1) were established in the B14 strain of chickens, which is homozygous for theB locus controlling major histocompatibility antigens. Transfer of lymphoid cells resulted in a permanent donor-type IgG synthesis in irradiated 12-day-old recipients, but was followed by protracted rejection in chickens injected embryonally.     

Demonstration of a new genetic locus in the major histocompatibility system of the rat

A new recombination within the major histocompatibility complex (RT1) of the rat has been detected. The recombination occurred between a wild-derived haplotype, provisionally designated p1, and the RT1 haplotype of the BN strain. The recombinant haplotype, designated p3, carries the RT1.A locus (classical histocompatibility antigens) of the BN strain, a locus from the BN strain that codes for the expression of an Ia antigen and strong mixed lymphocyte response (MLR), and a second locus derived from the p1 haplotype that controls the expression of a second Ia antigen, the ability to elicit a strong MLR and the immune response to poly(G1u⁵²Lys³³Tyr¹⁵). This recombinant therefore demonstrates the division of the RT1.B region into two loci, tentatively designated RT1.B and RT1.D, and provides evidence for the existence of at least four loci in the MHC of the rat.     

Genetic and immunological characterization of naturally occurring recombinant B3 rats

The B-stock population of rats was bred for homozygosity at the loci controlling coat color. In this process, theAg-B1 andAg-B3 haplotypes became fixed in Hardy-Weinberg equilibrium. Extensive immunization and absorption studies showed that the specificities in the B-stock rats homozygous for theAg-B1 haplotype were the same as those found in the inbred F344 strain (Ag-B1), and that the specificities in the rats homozygous for theAg-B3 haplotype were the same as those found in the inbred BN (Ag-B3) strain. A homozygous line derived from the rats carrying theAg-B3 haplotype (B3) has the mixed lymphocyte reactivity and antibody responsiveness to poly (Glu⁵²Lys³³Tyr¹⁵) characteristic of the inbred strains in theAg-B4 group. Thus, it represents a naturally occurring recombination between the loci controlling MLR and immune responsiveness, on the one hand, and those controlling the Ag-B antigens on the other. Antibody responsiveness segregated with theAg-B3 haplotype in crosses between the B3 homozygotes and the low responder BUF and M520 strains; hence, this recombination is a stable one. There was no linkage of antibody formation or haplotype to coat color. The finding of a strain with a naturally occurring recombination in the major histocompatibility complex between the loci controlling mixed lymphocyte reactivity and the Ag-B histocompatibility antigens provides evidence for the separateness of these loci. Since the portion of the genetically determined mechanism controlling antibody responsiveness which is linked to the MHC was that characteristic of the MLR type, it too must lie outside the region defined by the serological specificities of theAg-B haplotype.     

Genetic definition of a further gene region and identification of at least three different histocompatibility genes in the rat major histocompatibility system

Two new recombinant haplotypes of the rat major histocompatibility system,RT1, have been detected in [LEW.1A (RT1 ^a ) ×LEW.1W (RT1 ^u )] × LEW 1N(RT1 ⁿ ) segregating hybrids. Recombinantr3 carries theRTL1. A region (determining classical transplantation antigens) and theRT1.B region (determining strong mixed lymphocyte reactivity and genetic control of antipolypeptide immune responsiveness) of the RT1^a parent, bur rejects RT1^a skin grafts. Recombinantr4 carries theA andB regions of the RT1^u parent, but rejects RT1^u skin grafts. The two histocompatibility genes detected are allelic to each other. The relevant locus, designated asH-C, maps to theB-region side of theRT1 system and appears to mark a thirdRT1 gene region,RT1.C. Availability of haplotypes r3 andr4 allowed the definition of a histocompatibility locus in theB region,H-B. The products ofH-C, H-B and of the previously describedH-A gene vary in antigenic strength.     

Analysis of the B-G antigens of the chicken MHC by two-dimensional gel electrophoresis

The B-G antigens of the chicken major histocompatibility complex (MHC) have been analyzed by high resolution two-dimensional (2-D) gel electrophoresis. Monoclonal antibodies recognizing a widely shared B-G determinant were used for immunoprecipitating the B-G antigens from radioiodinated, detergent-solubilized erythrocyte membrane preparations. The B-G antigens produce a variety of patterns on 2-D gels. The number of polypeptides within a B-G pattern varies among haplotypes from single polypeptide arrays showing slight microheterogeneity to complex patterns which contain as many as four or five polypeptide arrays differing in relative mobility and isoelectric point. Many of the patterns, but not all, include a polypeptide of Mr =48 kd focusing near pH 6.9. At present it is not understood whether the multiple polypeptides within some B-G patterns represent the expression of multiple B-G genes or whether they are the result of modifications of single gene products during biosynthetic processing. 2-D gel analyses were also used to confirm the assignment of the same B-G haplotype in several different inbred flocks and the fate of the B-G antigens in two B system recombinant haplotypes. The 2-D gel patterns of these highly polymorphic antigens provide evidence for a complexity of the B-G locus not previously demonstrated. This technique may serve to define more objectively the diverse chicken MHC haplotypes which are now recognized and characterized only by serological techniques using alloantisera and monoclonal antibodies with varying cross-reactivities.     

Recombination between genes coding for immune response and the serologically determined antigens in the chickenB system

Evidence is presented for a crossover between the genes coding for the serologically determined (SD) antigens on erythrocytes and an immune response gene (Ir-GAT) controlling immune response to the synthetic polypeptide GAT within theB complex, the MHC of chickens. TheIr-GAT ¹ andIr-GAT ¹⁹ alleles control low and high immune response to GAT, respectively. Both low and high responders were recovered as recombinants fromB ¹ B ¹ andB ¹⁹ B ¹⁹ birds. The low-responder haplotypes are homozygous for theIr-GAT ¹ allele and the high-responder haplotypes carry theIr-GAT ¹⁹ allele. Mortality forB ¹ B ¹ nonresponder birds was 39%, compared with 19% for theB ¹ B ¹ high responders; this suggests the possibility that genes located within the immune response region of theB complex exert some genetic control over viability and survival.The following abbreviations are used in this paper MHC major histocompatibility complex - Ir immune response - SD serologically determined - GA (L-glutamic acid⁶⁰, L-alanine⁴⁰) n - DNP-GL dinitrophenyl-(L-glutamic acid⁶⁰, L-lysine⁴⁰) - PLL poly-L-lysine - (T,G)-A--L poly-(L-tyrosine-L-glutamic acid)-poly-D, L-alanine-poly-L-lysine - GAT, GAT¹⁰ (L-glutamic acid⁶⁰ L-alanine³⁰ L-tyrosine¹⁰) n - CFA complete Freund's adjuvant - PBS phosphate-buffered saline     

Murine responses to (Tyr-Glu-Ala-Gly)n

A series of known sequential polypeptides is being synthesized and used in our laboratory to study the contribution of antigen structure, i. e., amino acid sequence and conformation in antigen recognition and specificity of the immune response. The capacity to respond to one such -helical polypeptide (T-G-A-Gly)_n, is T-cell dependent and restricted to mice of theH- 2^b haplotype. The response is controlled by anIr gene mapping to theK region and/or theIA subregion which allows the animal to make both a T-cell mediated response, as well as a humoral response to the polypeptide. The response of three mutant strains at theK end of the major histocompatibility locus (MHC) need not differ from that of the responder parental haplotype.PETLES obtained from mice possessing a responder haplotype proliferate when cultured in vitro with (T-G-A-Gly)_n. The antibody level of individual inbred mice of a given strain at a given time differs significantly (from 80% binding to less than 10% antigen bound in 3 out of 57 mice). There is also great individual variability in time of appearance of the antibody response and where peak optimal levels are seen. Possible explanations for the variation in the antibody expression include: (a) the polymer is a weak immunogen, (b) the presence of modifier gene(s) outside of the major histocompatibility complex controlling the magnitude of the antibody level, (c) the possible effect of the polymer which is a B cell mitogen as a generator of suppressor T cells and, (d) a feedback mechanism effect on B cells controlling the antibody level.This work was supported in part by the following grants: The National Institute of Allergy and Infectious Diseases A107825; American Cancer Society Grant IM-5F; National Foundation-March of Dimes 1-492.     

Tissue graft rejection in mice

A liver-slice to kidney-bed grafting system was used to study the course of rejection of a specific tissue across various genetic barriers in inbred strains of mice. Rejection or survival, scored histologically at various times after grafting, demonstrated that multiple nonH-2 differences cause rejection at least as rapidly asH-2 differences. Differences at theK end of the mouse major histocompatibility complex cause tissue rejection more rapidly than do differences at theD end of the complex. The latter differences cause chronic rejection similar to that found across several minorH locus barriers. TheH-2 haplotype carried by the recipient or the strength of theH-2 antigens of the donor affect the survival time in liver tissue grafts. Studies employing this model system will contribute to the definition of different immunogenetic parameters affecting survival of various tissues in a genetically well-defined animal model.     

Genetic control of Rous sarcoma regression in chickens: Linkage with the major histocompatibility complex

Studies with two closely related inbred chicken strains show that regression of Rous sarcoma virus-induced tumors is a dominantly inherited trait, controlled by a gene within, or closely linked to, the major histocompatibility complex (B region). Strain G-B2 birds are capable of regressing Rous tumors, while strain G-B1 birds are uniformly susceptible to progressive Rous tumor development. Evidence for crossing over between the genes controlling serologically determined MHC antigens on erythrocytes and genes controlling Rous sarcoma growth was obtained. The MHC-linked gene which confers the ability to regress Rous sarcomas is designatedR-Rs-1. The allelic gene which allows for progressive tumor growth in homozygous birds is designatedr-Rs-1.     

Genetic analysis of resistance to Type-1 Diabetes in ALR/Lt mice,a NOD-related strain with defenses against autoimmune-mediated diabetogenic stress

ALR mice are closely related to type-1 diabetes mellitus (T1DM)-prone NOD mice. The ALR genome confers systemically elevated free radical defenses, dominantly protecting their pancreatic islets from free radical generating toxins, cytotoxic cytokines, and diabetogenic T cells. The ALR major histocompatibility complex (MHC) (H2^gx haplotype) is largely, but not completely identical with the NOD H2^g7 haplotype, sharing alleles from H2-K through the class II and distally into the class III region. This same H2^gx haplotype in the related CTS strain was linked to the Idd16 resistance locus. In the present study, ALR was outcrossed to NOD to fine map the Idd16 locus and establish chromosomal regions carrying other ALR non-MHC-linked resistance loci. To this end, 120 (NOD×ALR)×NOD backcross progeny females were monitored for T1DM and genetic linkage analysis was performed on all progeny using 88 markers covering all chromosomes. Glucosuria or end-stage insulitis developed in 32 females, while 88 remained both aglucosuria and insulitis free. Three ALR-derived resistance loci segregated. As expected, one mapped to Chromosome 17, with peak linkage mapping just proximal to H2-K. A novel resistance locus mapped to Chr 8. A pairwise scan for interactions detected a significant interaction between the loci on Chr 8 and Chr 17. On Chr 3, resistance segregated with a marker between previously described Idd loci and coinciding with an independently mapped locus conferring a suppressed superoxide burst by ALR neutrophils (Susp). These results indicate that the Idd16 resistance allele, defined originally by linkage to the H2^gx haplotype of CTS, is immediately proximal to H2-K. Two additional ALR-contributed resistance loci may be ALR-specific and contribute to this strain's ability to dissipate free-radical stress.     

Activation of T lymphocytes results in an increase inH-2-encoded neuraminidase

The endogenous neuraminidase activity of various mouse lymphoid subpopulations and tissue compartments was examined by a sensitive fluorometric assay. These analyses indicated that activated T lymphocytes possessed a significantly higher level of intracellular neuraminidase than activated B or resting T or B lymphocytes. Examination of the level of neuraminidase in bone marrow, thymus, lymph node, and unfractionated spleen indicated that these lymphoid tissues contained significantly less neuraminidase than was detected in stimulated T cells. Kinetic studies revealed that the majority of the increase in neuraminidase activity occurred between 24 and 48 h following stimulation. Analysis of activated T lymphocytes prepared from a panel of inbred mouse strains indicated that cells from mice of theH-2 ^v haplotype, which possess theNeu-1 ^a allele and are deficient in liver neuraminidase, exhibited a level of activity which was significantly lower than that detected in stimulated T cells from other mouse strains. These results indicate that the endogenous neuraminidase activity of T lymphocytes increases upon stimulation, and that the level of this enzyme activity in lymphoid cells is also controlled by theNeu-1 locus, which is located in theH-2 region of the major histocompatibility complex.Abbreviations used in this paper MHC major histocompatibility complex - LPS lipopolysaccharide - DXS dextran sulfate - IL-2 interleukin 2 - NANA N-acetylneuraminic acid - sIg surface immunoglobulin - Con A concanavalin A - C57BL/10 B10     

The genetic control of the immune response to murine histocompatibility antigens

The genetic control of the immune response to H-4 histocompatibility alloantigens is described. The rejection of H-4.2-incompatible skin grafts is regulated by anH-2-linkedIr gene. Fast responsiveness is determined by a dominant allele at theIrH-4.2 locus. TheH-2 ^b ,H-2 ^d , andH-2 ^s haplotypes share the fast response allele;H-2 ^a has the slow response allele. Through the use of intra-H-2 recombinants, we have mapped theIrH-4.2 locus to theI-B subregion of theH-2 complex; theH-2 ^h4 ,H-2 ¹⁵, andH-2 ^t4 haplotypes are fast responder haplotypes. These observations suggest that the strength of non-H-2 histocompatibility antigens is ultimately determined by the antigen-specific recipient responsiveness.     

The chicken erythrocyte-specific MHC antigen. Characterization and purification of the B-G antigen by monoclonal antibodies

Mouse monoclonal antibodies with B-G antigen (major histocompatibility complex class IV) specificity were obtained after immunization with erythrocytes or partially purified B-G antigen. The specificities of the hybridoma antibodies were determined by precipitation of B-G antigens from ¹²⁵I-labeled chicken erythrocyte membranes (CEM) followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and autoradiography. The B-G antigen had an approximate molecular mass of 46–48 kd in reduced samples, depending on the haplotype, and in unreduced samples contained either dimers (85 kd), when labeled erythrocytes were the antigen source, or trimers (130 kd), when B-G was purified and precipitated from CEM. The B-G antigen was unglycosylated as studied by (1) in vitro synthesis in the presence or absence of tunicamycin, (2) binding experiments with lectin from Phaseolus limensis, and (3) treatment of purified B-G antigen with Endoglycosidase-F or trifluoromethanesulfonic acid. Two-way sequential immunoprecipitation studies of erythrocyte membrane extracts with anti-B-G alloantisera and monoclonal antibodies revealed only one population of B-G molecules. Pulse-chase experiments have shown B-G to be synthesized as a monomer, with dimerization taking place after 20–30 min. No change in the monomer's molecular mass due to posttranslational modifications was revealed. The antigen was purified from detergent extract of CEM by affinity chromatography with a monoclonal antibody, and then reduced and alkylated and affinity-purified once more. Finally, reverse-phase chromatography resulted in a pure product. The B-G antigen was identified in the various fractions by rocket immunoelectrophoresis. The final product was more than 99% pure, as estimated by SDSPAGE analysis followed by silver stain of proteins. The yield from the affinity chromatography step was 3–4 g B-G/ml blood, calculated from Coomassie-stained SDS-PAGE of B-G using ovalbumin standards. The monoclonal antibodies were also used to identify the B-G (class IV) precipitation arc in crossed immunoelectrophoresis. No common precipitate with the B-F (class I) antigen was observed.     

Extended sequence of the turkey MHC <Emphasis Type="Italic">B</Emphasis>-locus and sequence variation in the highly polymorphic B-G loci

Genetic variation in the major histocompatibility complex (MHC) is directly correlated to differences in disease resistance. Immunity is greatly dependent on highly polymorphic genes in the MHC, such as class I, class II, and class III complement genes. Preliminary studies of wild turkey populations show extreme polymorphisms in a family of genes exclusive to the avian MHC, the class IV or B-G genes. Significance of this variation is unclear as there are few and conflicting studies of the expression of these genes. Confounding understanding of B-G variation is the lack of a complete delineation of the number of loci in the turkey genome. Direct 454 sequencing of a clone from the CHORI-260 BAC library was used to extend the turkey MHC B-locus sequence, identifying five additional complete B-locus genes including two B-G loci. Sequences of the new B-G genes were compared with those of other turkey gene (BG1–3) and sequences available for other galliformes. Phylogenetic analysis shows species-specific gene evolution supporting a birth–death model of evolution for the B-G gene family. Analysis of variation within the signal peptide sequence (exon 1) found two clusters of polymorphism among the turkey B-G genes. Resequencing of exon 1 in a diverse sample including wild, heritage, and commercial turkeys confirmed multiple alleles at each B-G gene. Future studies aim to correlate B-G variation with group and individual immunological differences.     

The “Sardinian”HLA-A30,B18,DR3,DQw2 haplotype constantly lacks the21-OHA andC4B genes. Is it an ancestral haplotype without duplication?

TheC4 and21-OH loci of the class III HLA have been studied by specific DNA probes and the restriction enzymeTaq I in 24 unrelated Sardinian individuals selected from completely HLA-typed families. All 24 individuals had theHLA extended haplotypeA30,Cw5,B18, BfF1,DR3,DRw52,DQw2, named “Sardinian” in the present paper because of its frquency of 15% in the Sardinian population. Eighteen of these were homozygous for the entire haplotype, and six were heterozygous at theA locus and blank (or homozygous) at all the other loci. In all completely homozygous cells and in four heterozygous cells at theA locus, the restriction fragments of the21-OHA (3.2 kb) andC4B (5.8 kb or 5.4 kb) genes were absent, and the fragments of theC4A (7.0 kb) and21-OHB (3.7 kb) genes were present. It is suggested that the “Sardinian” haplotype is an ancestral haplotype without duplication of theC4 and21-OH genes, practically always identical in its structure, also in unrelated individuals. The diversity of this haplotype in the class III region (about 30 kb less) may be at least partially responsible for its misalignment with most haplotypes, which have duplicatedC4 and21-OH genes, and therefore also for its decreased probability to recombine. This can help explain its high stability and frequency in the Sardinian population. The same conclusion can be suggested for the Caucasian extended haplotypeA1,B8,DR3 that always seems to lack theC4A and21-OHA genes.     

Genetic influences on spontaneous autoimmune thyroiditis in (CS x OS)F2 chickens

Genetic effects on spontaneous autoimmune thyroiditis in chickens were assessed by measuring phenotypic symptoms, the titer of circulating antibody to thyroglobulin, and the pathological change in the thyroids of young chicks. One or more loci within theB complex (the major histocompatibility complex of the chicken) are responsible for the expression of autoimmunity, and evidence is provided for an interaction of theB haplotype with genes at other loci. The influence of theB complex component on genetic susceptibility is more visible in animals with limited susceptibility at other loci and becomes indistinguishable as the frequency of other genes determining thyroid autoimmunity increases.     

Attempt to detect recombination between B-F and B-L genes within the chicken B complex by serological typing,in vitro MLR,and RFLP analyses

In search for recombinants within the chicken major histocompatibility B complex, 1155 animals from crosses between the congenic lines CB (B¹²) and CC (B⁴) were tested with alloantibodies and monoclonal antibodies for the B-F (class I), B-L (class II), and B-G (class IV) antigens and by mixed lymphocyte reaction. The absence of detectable recombination was confirmed by restriction fragment length polymorphism analysis with B-L and B-F probes. Together with previous reports, this indicates that the distance between the B-F and B-L loci is below 0.01 centimorgan.