Molecular characterization of MHC class II antigens (beta 1 domain) in the BB diabetes-prone and -resistant rat

T Cell Receptor Genotype and Ubash3a Determine Susceptibility to Rat Autoimmune Diabetes

Genetic analyses of human type 1 diabetes (T1D) have yet to reveal a complete pathophysiologic mechanism. Inbred rats with a high-risk class II major histocompatibility complex (MHC) haplotype (RT1B/D^u) can illuminate such mechanisms. Using T1D-susceptible LEW.1WR1 rats that express RT1B/D^u and a susceptible allele of the Ubd promoter, we demonstrate that germline knockout of Tcrb-V13S1A1, which encodes the Vβ13a T cell receptor β chain, completely prevents diabetes. Using the RT1B/D^u-identical LEW.1W rat, which does not develop T1D despite also having the same Tcrb-V13S1A1 β chain gene but a different allele at the Ubd locus, we show that knockout of the Ubash3a regulatory gene renders these resistant rats relatively susceptible to diabetes. In silico structural modeling of the susceptible allele of the Vβ13a TCR and its class II RT1^u ligand suggests a mechanism by which a germline TCR β chain gene could promote susceptibility to T1D in the absence of downstream immunoregulation like that provided by UBASH3A. Together these data demonstrate the critical contribution of the Vβ13a TCR to the autoimmune synapse in T1D and the regulation of the response by UBASH3A. These experiments dissect the mechanisms by which MHC class II heterodimers, TCR and regulatory element interact to induce autoimmunity.

Rat Models of Human Type 1 Diabetes

Rat models of human type 1 diabetes have been shown to be of great importance for the elucidation of the mechanisms underlying the development of autoimmune diabetes. The three major well-established spontaneous rat models are the BioBreeding (BB) diabetes-prone rat, the Komeda diabetes-prone (KDP) rat, and the IDDM (LEW.1AR1-iddm) rat. Their distinctive features are described with special reference to their pathology, immunology, and genetics and compared with the situation in patients with type 1 diabetes mellitus. For all three established rat models, a distinctive genetic mutation has been identified that is responsible for the manifestation of the diabetic syndrome in these rat strains.

Iddm30 controls pancreatic expression of Ccl11 (Eotaxin) and the Th1/Th2 balance within the insulitic lesions

The autoimmune diabetic syndrome of the BioBreeding diabetes-prone (BBDP) rat is a polygenic disease that resembles in many aspects human type 1 diabetes (T1D). A successful approach to gain insight into the mechanisms underlying genetic associations in autoimmune diseases has been to identify and map disease-related subphenotypes that are under simpler genetic control than the full-blown disease. In this study, we focused on the β cell overexpression of Ccl11 (Eotaxin), previously postulated to be diabetogenic in BBDR rats, a BBDP-related strain. We tested the hypothesis that this trait is genetically determined and contributes to the regulation of diabetes in BBDP rats. Similar to the BBDR strain, we observed a time-dependent, insulitis-independent pancreatic upregulation of Ccl11 in BBDP rats when compared with T1D-resistant ACI.1u.lyp animals. Through linkage analysis of a cross-intercross of these two parental strains, this trait was mapped to a region on chromosome 12 that overlaps Iddm30. Linkage results were confirmed by phenotypic assessment of a novel inbred BBDP.ACI-Iddm30 congenic line. As expected, the Iddm30 BBDP allele is associated with a significantly higher pancreatic expression of Ccl11; however, the same allele confers resistance to T1D. Analysis of islet-infiltrating T cells in Iddm30 congenic BBDP animals revealed that overexpression of pancreatic Ccl11, a prototypical Th2 chemokine, is associated with an enrichment in Th2 CD4+ T cells within the insulitic lesions. These results indicate that, in the BBDP rat, Iddm30 controls T1D susceptibility through both the regulation of Ccl11 expression in β cells and the subsequent Th1/Th2 balance within islet-infiltrating T lymphocytes.

Microarray studies on effects of Pneumocystis carinii infection on global gene expression in alveolar macrophages

Background

Pneumocystis pneumonia is a common opportunistic disease in AIDS patients. The alveolar macrophage is an important effector cell in the clearance of Pneumocystis organisms by phagocytosis. However, both the number and phagocytic activity of alveolar macrophages are decreased in Pneumocystis infected hosts. To understand how Pneumocystis inactivates alveolar macrophages, Affymetrix GeneChip^® RG-U34A DNA microarrays were used to study the difference in global gene expression in alveolar macrophages from uninfected and Pneumocystis carinii-infected Sprague-Dawley rats.

Results

Analyses of genes that were affected by Pneumocystis infection showed that many functions in the cells were affected. Antigen presentation, cell-mediated immune response, humoral immune response, and inflammatory response were most severely affected, followed by cellular movement, immune cell trafficking, immunological disease, cell-to-cell signaling and interaction, cell death, organ injury and abnormality, cell signaling, infectious disease, small molecular biochemistry, antimicrobial response, and free radical scavenging. Since rats must be immunosuppressed in order to develop Pneumocystis infection, alveolar macrophages from four rats of the same sex and age that were treated with dexamethasone for the entire eight weeks of the study period were also examined. With a filter of false-discovery rate less than 0.1 and fold change greater than 1.5, 200 genes were found to be up-regulated, and 144 genes were down-regulated by dexamethasone treatment. During Pneumocystis pneumonia, 115 genes were found to be up- and 137 were down-regulated with the same filtering criteria. The top ten genes up-regulated by Pneumocystis infection were Cxcl10, Spp1, S100A9, Rsad2, S100A8, Nos2, RT1-Bb, Lcn2, RT1-Db1, and Srgn with fold changes ranging between 12.33 and 5.34; and the top ten down-regulated ones were Lgals1, Psat1, Tbc1d23, Gsta1, Car5b, Xrcc5, Pdlim1, Alcam, Cidea, and Pkib with fold changes ranging between -4.24 and -2.25.

Conclusions

In order to survive in the host, Pneumocystis organisms change the expression profile of alveolar macrophages. Results of this study revealed that Pneumocystis infection affects many cellular functions leading to reduced number and activity of alveolar macrophages during Pneumocystis pneumonia.

Sequencing and genetic analysis of a bovine DQB cDNA clone

A BoLA-DQB cDNA clone (BoLA-DQ beta-1) was isolated by screening a bovine lymphoblastoid cDNA library with a HLA-DQB genomic clone. The DNA and predicted protein sequences were compared to class II sequences from cattle and other species. BoLA-DQ beta-1 has 92.0% similarity to the coding regions of two previously sequenced BoLA-DQB genomic clones and 69.6% similarity to a BoLA-DR beta pseudogene. However, the first domain encoded by BoLA-DQ beta-1 has 94 amino acids; one more than the predicted size of the products encoded by two previously sequenced bovine DQB genes (BoDQ beta-Q1 and BoDQ beta-Y1). Comparing all coding regions, BoLA-DQ beta-1 has greater nucleotide similarity to HLA-DQB sequences than to I-A beta, HLA-DRB and I-E beta sequences. Like the HLA-DQB gene product, the cytoplasmic domain of the predicted protein encoded by BoLA-DQ beta-1 is eight amino acids shorter than that of I-A beta, HLA-DRB and I-E beta molecules. Six clone-specific amino acid substitutions were identified in the beta 1 domain of BoLA-DQ beta-1, including an unusual cysteine residue at position 13 which is believed to be positioned on a beta-strand and face into the antigen recognition site. Southern blot analysis of PvuII-digested genomic DNA from a paternal half-sibling family (sire, and six dam-offspring pairs) using BoLA-DQ beta-1 as a probe, revealed five allelic PvuII RFLP patterns, including two patterns not previously described, that cosegregated with serologically-defined BoLA-A (class I) alleles. The evolution, polymorphism and function of a transcriptionally active BoLA-DQB gene can now be readily studied using this DQB cDNA clone as a source of allele and locus-specific oligonucleotide primers.

Rat models of type 1 diabetes: genetics, environment, and autoimmunity

For many years, the vast amount of data gathered from analysis of nonobese diabetic (NOD) and congenic NOD mice has eclipsed interest in the rat for the study of type 1 diabetes. The study of rat models has continued, however, and recently there has been a reanimation of interest for several reasons. First, genetic analysis of the rat has accelerated. Ian4L1, cblb, and Iddm4 are now known to play major roles in rat autoimmunity. Second, rats are amenable to study the interactions of genetics and environment that may be critical for disease expression in humans. Environmental perturbants that predictably enhance the expression of rat autoimmune diabetes include viral infection, toll-like receptor ligation, and depletion of regulatory T cell populations. Finally, data generated in the rat have correctly predicted the outcome of several human diabetes prevention trials, notably the failure of nicotinamide and low dose parenteral and oral insulin therapies.

Open reading frame sequencing and structure-based alignment of polypeptides encoded by RT1-Bb, RT1-Ba, RT1-Db, and RT1-Da alleles

MHC class II genes are major genetic components in rats developing autoimmunity. The majority of rat MHC class II sequencing has focused on exon 2, which forms the first external domain. Sequence of the complete open reading frame for rat MHC class II haplotypes and structure-based alignment is lacking. Herein, the complete open reading frame for RT1-Bbeta, RT1-Balpha, RT1-Dbeta, and RT1-Dalpha was sequenced from ten different rat strains, covering eight serological haplotypes, namely a, b, c, d, k, l, n, and u. Each serological haplotype was unique at the nucleotide level of the sequenced RT1-B/D region. Within individual genes, the number of alleles identified was seven, seven, six, and three and the degree of amino-acid polymorphism between allotypes for each gene was 22%, 16%, 19%, and 0.4% for RT1-Bbeta, RT1-Balpha, RT1-Dbeta, and RT1-Dalpha, respectively. The extent and distribution of amino-acid polymorphism was comparable with mouse and human MHC class II. Structure-based alignment identified the beta65-66 deletion, the beta84a insertion, the alpha9a insertion, and the alpha1a-1c insertion in RT1-B previously described for H2-A. Rat allele-specific deletions were found at RT1-Balpha76 and RT1-Dbeta90-92. The mature RT1-Dbeta polypeptide was one amino acid longer than HLA-DRB1 due to the position of the predicted signal peptide cleavage site. These data are important to a comprehensive understanding of MHC class II structure-function and for mechanistic studies of rat models of autoimmunity.

Complementary DNA sequences encoding the rat MHC class II RT1-Bu and RT1-Du alpha and beta chains

The rat major histocompatibility complex loci RT1-B and RT1-D are equivalent to the human leucocyte antigens HLA-DQ and HLA-DR respectively. Here we describe the complementary DNA (cDNA) sequence encoding the alpha and beta chains of both the RT1-B and RT1-D locus genes of the rat RT1u haplotype. We have found entire sequence identity between five different inbred rat strains of the RT1u haplotype, which differs from previously published, incomplete sequences. This information is of considerable value for experimental studies of transplantation immunity and autoimmune disease.

Thymic dendritic cells express inducible nitric oxide synthase and generate nitric oxide in response to self- and alloantigens

Thymocytes maturing in the thymus undergo clonal deletion/apoptosis when they encounter self- or allo-Ags presented by dendritic cells (DCs). How this occurs is a matter of debate, but NO may play a role given its ability of inducing apoptosis of these cells. APC (a mixed population of macrophages (Mphi) and DCs) from rat thymus expressed high levels of inducible NO synthase (iNOS) and produced large amounts of NO in basal conditions whereas iNOS expression and NO production were very low in thymocytes. Analysis by FACS and by double labeling of cytocentrifuged preparations showed that DCs and MPhi both express iNOS within APC. Analysis of a purified preparation of DCs confirmed that these cells express high levels of iNOS and produce large amounts of NO in basal conditions. The capacity of DCs to generate NO was enhanced by exposure to rat albumin, a self-protein, and required a fully expressed process of Ag internalization, processing, and presentation. Peptides derived from portions of class II MHC molecules up-regulate iNOS expression and NO production by DCs as well, both in self and allogeneic combinations, suggesting a role of NO in both self and acquired tolerance. We also found that NO induced apoptosis of rat double-positive thymocytes, the effect being more evident in anti-CD3-stimulated cells. Altogether, the present findings might suggest that DC-derived NO is at least one of the soluble factors regulating events, in the thymus, that follow recognition of self- and allo-Ags.

Development of an I-Ag7-expressing antigen-presenting cell line: intrinsic molecular defect in compact I-Ag7 dimer generation

Insulin-dependent diabetes mellitus (IDDM) results from chronic, T-cell dependent, autoimmune destruction of the insulin-producing beta-cells in the Langerhans' islets of the pancreas. Non-obese diabetic (NOD) mice spontaneously develop IDDM that resembles human type I diabetes. The susceptibility to diabetes in the NOD strain is a complex polygenic trait that determines a phenotype of immune alterations. The unique MHC class II molecule expressed by NOD mice (I-Ag7) plays a major role in the development of disease. Recently, it has been reported that I-Ag7 molecules generate a lower proportion of compact alphabeta heterodimers, compared to other haplotypes. However, it is not clear whether this reflects an intrinsic defect of this molecule to bind peptide stably or is the result of abnormal processing and/or peptide loading into the I-Ag7 molecule. Our aim was to develop and characterize a suitable antigen-presenting cell (APC) that expressed I-Ag7 in the context of a non-diabetes-prone antigen processing and presentation machinery. Here, we report the generation of a mouse DAP.3 fibroblast cell line (DAP.3Ag7) that constitutively expresses high levels of I-Ag7. Using DAP.3 cells transfected with I-Ag7 or I-Ak, we show that the expression of compact dimers in the same cell type is proportionally less for I-Ag7 molecules than for I-Ak molecules, implying an intrinsic defect of the I-Ag7 molecule as the cause for the low generation of compact dimers. However, DAP.3Ag7 cells are able to process and present antigen, as indicated by I-Ag7-dependent IL-2 production by a GAD67-specific NDO T-cell hybridoma after stimulation with GAD and live, but not fixed, DAP.3Ag7 cells. The IL-2 response to GAD when presented by DAP.3Ag7 was significantly higher than the response to GAD presented by NOD splenocytes. Based on these data, we conclude that the low generations of compact dimers is an intrinsic feature of I-Ag7 molecules and not affected by other genes in the NOD background. The DAP.3Ag7 cell line should be a valuable tool with which to dissect the role of the I-Ag7 molecule in antigen presentation and T-cell activation in NOD mice, which clearly contributes to the development of IDDM.

T-cell recognition of an allogeneic RT1-Dbu class II MHC peptide

The allo-antibody response of several rat strains to an unconjugated synthetic 20 amino acid peptide derived from the alpha helical region of the RT1-Du beta chain was tested. The LEW (RT1l) and WAG (RT1u) strains produced little or no antibody; the PVG (RT1c) and DA (RT1av1) strains produced moderate amounts of antibody; while the BN (RT1n) strain produced strong primary and secondary antibody responses. This suggested that the BN strain was able to process and present the RT1-Dbu peptide on its class II molecules. In vitro proliferation studies demonstrated that LEW T cells did not respond to the peptide, whereas BN T cells responded strongly, and that the response in the BN strain was found only in the CD4+ T-cell subset. However, immunisation of BN rats with the RT1-Dbu peptide failed to cause any acceleration of rejection of WAG skin or kidney grafts. Moreover, BN rats primed with WAG skin and kidney grafts did not produce T cells reactive to the RT1-Dbu synthetic peptide. This suggests that the T-cell response of the BN strain to the synthetic major histocompatibility complex peptide was not relevant to the indirect T-cell allo-recognition response to naturally processed RT1-Du beta chains.

The V-region disease hypothesis: new evidence suggests it is probably wrong

Repertoire analyses of activated T-cell populations specific for myelin basic protein, peptides of which cause experimental allergic encephalomyelitis in rats and mice, indicate a very limited utilization of homologous V alpha and V beta genes in both species. However, the encephalitogenic peptide fragments of myelin basic protein represent different domains of the antigen molecule and the MHC restricting elements are different. This finding has lead to an interpretation, the 'V-region disease hypothesis', which suggests that some TCR molecules may have special effector functions in addition to peptide-MHC recognition. On the basis of recent findings with the rat experimental allergic encephalomyelitis model and preliminary studies in human multiple sclerosis, we present a more conservative and conventional interpretation of the association of certain TCR V-region elements with encephalitogenicity.

Induction of immunity and oral tolerance with polymorphic class II major histocompatibility complex allopeptides in the rat

We studied the immunogenicity and tolerogenicity of class II major histocompatibility complex (MHC) allopeptides in the rat. Inbred LEW (RT1l) rats, used as responders, were immunized in the foot pad with a mixture of eight synthetic class II MHC allopeptides emulsified in complete Freund's adjuvant. These sequences represent the full-length second domain of RT1.Bu and RT1.Du (WF) beta chains. In vitro, responder lymphocytes harvested from popliteal and inguinal lymph nodes of immunized animals exhibited significant proliferation to the MHC allopeptide mixture. In addition, these responder lymphocytes had significantly increased proliferation to allogeneic WF (RT1u) stimulator cells, when compared to naive controls in the standard one-way mixed lymphocyte response. In vivo, peptide-immunized LEW animals were challenged in the ear 2 weeks after immunization with the allopeptide mixture, the individual allopeptide sequences, or allogeneic WF splenocytes. When compared to controls, these animals had significant delayed-type hypersensitivity responses to the allopeptide mixture, to the beta-pleated sheet allopeptide sequences, and to allogeneic WF splenocytes but not to the alpha-helix allopeptide sequences, to syngeneic LEW splenocytes, or to third party allogeneic BN splenocytes. Oral administration of the allopeptide mixture to LEW responder rats daily for 5 days before immunization effected significant reduction of delayed-type hypersensitivity responses both to the allopeptide mixture and to allogeneic splenocytes. This reduction was antigen-specific, since there was no reduction of delayed-type hypersensitivity responses to mycobacterium tuberculosis. These data demonstrate that lymphocytes from animals immunized with polymorphic class II MHC allopeptides can recognize and proliferate to the same amino acid sequences on allogeneic cell surface MHC molecules. In addition, oral administration of these peptides down-regulates the systemic cell-mediated immune response in a specific fashion. Synthetic MHC allopeptides should allow the study of alloimmunity in vivo, including induction of immune tolerance.

T cell recognition of donor major histocompatibility complex class I peptides during allograft rejection

LEW (RTI1) recipients of DA (RTIav1) skin and kidney allografts were tested for the capacity of their T lymphocytes to proliferate to three 22-24-amino acid peptides from the hypervariable regions of the RTI-Aav1 classical MHC class I molecule. Ten days after rejecting second-set DA kidney allografts, spleen cells (but interestingly not lymph node cells) from LEW recipients showed strong, LEW antigen-presenting cell-dependent, CD4+ T cell proliferation to peptide 1 (from the alpha helical region of the alpha 1 domain). CD8+ T cells showed no response to peptide 1. There was no response by the spleen cells to peptide 2 (from the beta sheet of the alpha 2 domain) or peptide 3 (from the alpha helical region of the alpha 2 domain). Immunization of LEW rats with pure RTI-Aav1 class I H chain in Freund's adjuvant gave responses identical to that seen after grafting, i.e. good CD4+ T cell proliferation to peptide 1, but none to peptides 2 and 3. However, immunization of LEW rats with peptides 1, 2 and 3 in Freund's adjuvant resulted in good CD4+ T cell proliferation responses to each of the peptides. These data demonstrate that indirect allorecognition can be stimulated by allograft rejection, and emphasize that the physiological processing of donor antigens will influence which peptides will be important in indirect allorecognition in transplantation.

Rejection of skin allografts by indirect allorecognition of donor class I major histocompatibility complex peptides

LEW (RT1l) rats were immunized with peptides corresponding to the alpha helical region of the alpha 1 domain (peptide 1), the beta sheet of the alpha 2 domain (peptide 2), and the alpha helical region of the alpha 2 domain (peptide 3) of the RT1-Aav1 classical class I molecule of the DA (RT1av1) strain. The immunizations were without carriers, and the objective was to prime to indirect allorecognition without influencing direct recognition of the RT1-Aav1 molecule. The LEW rats mounted strong primary and secondary antibody responses to peptides 1 and 3, but only weak secondary responses to peptide 2. None of the antipeptide antibodies crossreacted with intact RT1-Aav1 class I molecules. The immunization also resulted in LEW antigen-presenting cell-dependent, CD4+ T cell proliferative responses, which were very strong against peptide 1 and weakest against peptide 2. LEW rats immunized with peptides 1 or 3, but most effectively with both peptides 1 and 3 together, showed accelerated rejection of DA skin allografts. This effect was not observed in LEW rats immunized with peptide 2. In response to the DA skin allograft, the peptide-immunized LEW rats showed markedly accelerated kinetics of antibody production to the intact RT1-Aav1 molecule. These data demonstrate that indirect allorecognition can play an important role in allograft rejection and have important implications for understanding allograft rejection and its regulation.

V beta repertoire in rats and implications for endogenous superantigens

Endogenous superantigens of mice, encoded by mammary tumor virus proviral integrants, induce intrathymic deletion of entire T cell populations that express specific V beta gene products, a phenomenon proposed to be important in self-tolerance and prevention of toxic responses to exogenous microbial superantigens. Evidence for the presence of V beta selecting/deleting endogenous superantigens in other species is lacking. We report here that rats do not exhibit endogenous superantigen-induced V beta clonal deletions despite their strong response to bacterial superantigens. These findings indicate that endogenous superantigens are not obligatory in V beta repertoire shaping.

Diabetes segregates as a single locus in crosses between inbred BB rats prone or resistant to diabetes

Diabetes-prone (DP) BB rats spontaneously develop insulin-dependent diabetes resembling type 1 diabetes mellitus in man. They also exhibit lifelong T cell deficiency. The segregation of both diabetes and lymphopenia was studied in crosses between this inbred line of rats and the related but nondiabetic and nonlymphopenic inbred diabetes-resistant (DR) BB rat line. Diabetes segregated as a single, autosomal recessive trait and was always accompanied by lymphopenia. Among the limited number of differences in the genomic DNA sequences of the two lines, DP and DR BB, one may account for the development of diabetes and lymphopenia in the DP BB rats. It may be possible to screen the genomic DNA for such differences to detect a marker for the phenotypes.

The recognition of self-antigens and autoimmune disease

Recent studies have increased our understanding of the nature of autoimmune recognition and of the identity of autoantigens, at least in model systems. Knowledge of the autoantigens and the process of recognition is suggesting new therapies for autoimmune disease.

Human HLA-DR beta gene hypervariable region homology in the biobreeding BB rat: selection of the diabetic-resistant subline as a rheumatoid arthritis research tool to characterize the immunopathologic response to human type II collagen

Collagen arthritis (CA), an autoimmune model of rheumatoid arthritis (RA), has been studied in various animals. However, it has not been studied in an animal with a genetic background relevant to RA. We selected rats from a diabetic-resistant (DR) subline of the diabetic BB rat because they have an autoimmune disease-prone background, but not the immunodeficiencies of the diabetic BB rat, and the third hypervariable region (HVRIII) of the BB RT1.D beta gene appeared to encode a nucleotide sequence of the human HLA DR beta gene, which has been reported to be associated with susceptibility to RA. We synthesized oligonucleotide primers flanking the RT1.D beta HVRIII, cloned polymerase chain reaction-amplified DNA into M13mp18, and confirmed the presence of the susceptibility sequence (SS) (RRRAA) by the dideoxy sequencing method in a colony of DR BB/Wor-UTM rats. When immunized with human type II collagen (CII) in incomplete Freunds adjuvant (IFA), arthritis developed rapidly by day 10 with 100% incidence. Light and electron microscopy revealed an unusually severe and aggressive, bidirectional pattern of cartilage resorption by synovial and subchondral mononuclear and multinucleated inflammatory cells. These findings coincided with a predominant humoral response to the cyanogen bromide (CB) 11 fragment of the human CII molecule by the pathogenic IgG2a isotype. This study provides further support to the role of CA as a relevant RA model, the specific roles of the CB11 fragment as a major site of arthritogenic epitopes, and of antibody mechanisms in the pathogenesis of CA. Furthermore, the identification of an RA SS in an immune response gene of the DR BB rat presents a novel opportunity to determine with an animal model the role of other antigens as well as this SS in RA.

Genetic susceptibility to the development of spontaneous insulin-dependent diabetes mellitus in the rat

Spontaneous insulin-dependent diabetes mellitus in the rat is a multigenic, multifactorial condition. We have identified three phenotypic characteristics of the syndrome. The first is an association with the RT1u haplotype of the rat major histocompatibility complex. A single RT1u haplotype is permissive, although the relative risk of developing the disease is increased when the animal is homozygous. An immunoregulatory defect, which is characterized phenotypically by a severe T lymphocyte depletion, behaves as if it were regulated by a single autosomal recessive gene which segregates independently of the RT1. The third phenotype characteristic is the presence of lymphocytic infiltration of the pancreas. The genetics of this characteristic have not been delineated, although there is evidence that it behaves as a dominant. In addition to the requirement for several genes, environmental events are important for full expression of the syndrome.

Genetic control of autoimmunity in type 1 diabetes

DNA sequence analysis of major histocompatibility complex (MHC) class II genes from humans and rodents with type 1 (insulin-dependent) diabetes indicates that a portion of MHC-linked genetic susceptibility in humans is determined by the HLA-DQA1 and -DQB1 loci. In this article John Todd summarizes recent advances in these studies. The conformation of DQ molecules and their levels of expression may influence the efficiency of autoantigen presentation and the degree of pancreatic beta cells destruction during disease development. Certain DAQ1 and DQB1 alleles correlate with decreased susceptibility to disease. The penetrance of class II alleles that are correlated with positive susceptibility may be influenced by environmental factors such as bacterial and viral infections.