In situ islet cytokine gene expression during development of type I diabetes in the non-obese diabetic mouse.

Expression of cytokine genes in the islets of non-obese diabetic (NOD) female mice was examined. RNA samples were prepared from the islets and spleens of NOD mice at different time points at prediabetic stages during the natural disease process. Cytofluorometric analyses showed that the majority of lymphocyte infiltrates in the islets at 14 weeks of age consisted of T cells (68%). Of these, 80% of Thy1.2+ cells were CD4+ T cells. Less than 1% of in situ islet immune cells expressed a cell surface marker specific for the macrophage (Mac-1). Results of polymerase chain reaction using RNA (RT-PCR) prepared from spleens, and isolated and purified islets demonstrated that IFN-gamma message was detectable in the islets at 7 weeks of age (an early stage of insulitis). No message for this gene was detected in the spleen at any stage studied (7, 14 and 16 weeks of age). In contrast, TNF-alpha message was detected in both spleen and the islets at all stages, although the level of expression of TNF-alpha in the islets was much higher than that in the spleen. These results suggest that both cytokines are produced by in situ islet T cells, possibly activated T cells, which may be responsible for initiating or perpetuating autoimmune reactions in the islets.

Distinct associations of HLA class II genes with inflammatory bowel disease.

BACKGROUND: There are relatively few studies of HLA class II association either with Crohn's disease (CD) or ulcerative colitis (UC). The few available association studies have been carried out by serological techniques, and the results from these studies are inconclusive. METHODS: The association between HLA class II genes was studied using molecular genotyping in combination with allele-specific oligonucleotide hybridization by polymerase chain reactions. RESULTS: In UC (n = 74), we observed a positive association with the HLA DR2 allele (P = 0.008) and negative associations with the DR4 (P = 0.018) and DRw6 (P = 0.028) when compared with ethnically matched controls (n = 77). No associations were observed with any DQ alleles. In contrast, in CD (n = 95) we observed a positive association with the combination of DR1 and DQw5 alleles (P = 0.021). Furthermore, stratifying DR1 and DQw5 alleles indicated that neither allele was independently associated with CD, suggesting that the association was with the haplotype rather than either of the alleles individually. A suballele of DQw5, DQB1*0501, contributed this haplotypic association (P = 0.012). CONCLUSIONS: DR and DQ molecules firmly separate UC and CD on genetic grounds, suggesting that the contribution of the HLA class II genes to the disease susceptibility is quite different for the two disorders.

In situ islet T cell receptor variable region gene usage in the nonobese diabetic mouse.

Several features of the genetics and immunopathology of diabetes in the nonobese diabetic (NOD) mouse, which spontaneously develops type I diabetes, are shared with the human disease. Immunohistochemical studies support the concept that T lymphocytes are the major components of inflammatory cells in the pancreatic islets and these cells may play a critical role in the destruction of the beta cells leading to diabetes. Therefore, we examined whether particular TCR-beta variable region genes were utilized by in situ islet T cells at different stages (4 - 5, 7, 14 - 15 and 16 weeks of age) of the disease process. Dot-blot hybridization was performed using RNA prepared from isolated islets, thymus, spleen, peripheral blood leukocytes and axillary lymph nodes of 10 to 15 mice pooled for each data point. Ten different TCR V-beta probes were used for the analyses. Limited usage of islet V-beta genes was observed only at the early prediabetic stage (4 - 5 weeks old) of the disease. At later stages of the disease (7 - 16 weeks old), no preferential usage of TCR genes was observed in the islets compared to those of peripheral lymphoid organs. These data suggest that only certain types of T cells bearing particular TCR V-beta genes may be responsible for initiating and perpetuating infiltration of immune cells into the islets and these particular T cells are only identified at the very early stages of the autoimmune process.

Allele-specific methylation in the 5'-regulatory region of class II DQ beta genes in the human major histocompatibility complex (MHC): relationship to autoimmune disease susceptibility.

The DNA methylation state of the 5'-regulatory region of human HLA-DQ beta genes was examined. Two restriction enzymes were utilized to detect methylated (meCG) dinucleotides in the 5'-regulatory region of the DQ-beta genes: the restriction enzyme Msp I, which recognizes CCGG and CmeCGG, and Hpa II recognizes only the unmethylated CG sequence. DNA samples were prepared from 95 HLA-typed individuals including 40 B-lymphoblastoid cell lines and peripheral blood leukocytes of 55 individuals. Of these samples, 20 were from parents of individuals with insulin-dependent diabetes. Allele specific methylation was observed in particular DR-associated DQ-beta gene alleles. The DQw8 (DQw3.2) allele, most DQw7 (DQw3.1) alleles, and the DR3-associated DQw2 allele were all unmethylated. The parental methylation state was stably transmitted to offspring. Because these DQ alleles are highly associated with several autoimmune diseases, our results raise the possibility that the regulation of expression of these particular DQ-beta alleles might be different from that of other alleles, and that the 5'-regulatory DNA sequences of these particular DQ beta alleles may be responsible for, or contribute to, susceptibility to autoimmune diseases.

Restriction fragment length polymorphism (RFLP) heterogeneity of HLA-DQ beta genes associated with DNA fragment identical to the DR1-beta DNA structure.

Restriction fragment length polymorphism (RFLP) analyses of DR1 positive peripheral blood leukocytes DNA was carried out. The Taq I digested DNA was hybridized with cDNA probes for HLA-DR and -DQ beta genes. The DR probe detected fragments commonly observed in the DR1 specificity, whereas a new DQ-beta fragment was detected in some DR1 haplotypes when the DQ-beta probe was used. This fragment had an RFLP pattern identical to the DQ-beta fragment typically associated with most DR2 and some DRw6 specificities.