Allelic T-cell receptor alpha complexes have little or no influence on susceptibility to type 1 diabetes

Gut microbiota: A double-edged sword in immune checkpoint blockade immunotherapy against tumors

Tumor cells can evade immune surveillance by expressing immune checkpoint molecule ligands, resulting in effective immune cell inactivation. Immune checkpoint blockades (ICBs) have dramatically improved survival of patients with multiple types of cancers. However, responses to ICB immunotherapy are heterogeneous with lower patient response rates. The advances have established that the gut microbiota can be as a promising target to overcome resistance to ICB immunotherapy. Furthermore, some bacterial species have shown to promote improved responses to ICBs. However, gut microbiota is critical in maintaining gut and systemic immune homeostasis. It not only promotes differentiation and function of immunosuppressive immune cells but also inhibits inflammatory cells via gut microbiota derived products such as short chain fatty acids (SCFAs), tryptophan (Trp) and bile acid (BA) metabolites, which play an important role in tumor immunity. Since the gut microbiota can either inhibit or enhance immune against tumor, it should be a double-edged sword in ICBs against tumor. In this review, we discuss the effects of gut microbiota on immune cells and also tumor cells, especially enhances of gut microbiota on ICB immunotherapy. These discussions can hopefully promote the development of ICB immunotherapy.

Association of TCR/CD3, PTPN22, CD28 and ZAP70 gene polymorphisms with type 1 diabetes risk in Tunisian population: family based association study

Type 1 diabetes (T1D) is caused by an immune-mediated destruction of the insulin-producing β-cells. Several studies support the involvement of T cell activation molecules in the pathogenesis of T1D. In order to underline the role of the genes involved in this activation pathway, we investigated, using the Sequenom MassARRAY platform, 45 single-nucleotide polymorphisms (SNPs) belonging to TCR/CD3, CD28, ZAP70, and PTPN22 genes in 59 T1D Tunisian families. In the current study, we identified an association with rs706 (Z score=2.782; p=0.005) of TCRβ gene. We also demonstrated that rs10918706 in the intron of the CD3z gene was associated with increased risk of T1D (Z score 2.137; p=0.032). In the same region, rs2949655 (Z score=2.101; p=0.035) and rs1214611 (Z score=4.036; p=0.00005) showed a genotype association with the risk of T1D. When haplotypes were constructed, GAA haplotype displayed significant association with T1D (Z score=2.135; p=0.032), while GGA haplotype (Z score=-1.988; p=0.046) was negatively associated with the disease. We also identified an association with rs3181096 (Z score=2.177; p=0.029), rs17695937 (Z score =2.111; p=0.034) and rs2488457 (Z score=2.219; p=0.026), respectively of CD28, ZAP70 and PTPN22 genes. In addition, our results suggest a significant effect on T1D susceptibility for AC (Z score=2.30; p=0.02) and CTGGC (Z score=2.309, p=0.02) haplotypes of ZAP70 and PTPN22 genes, respectively. While, the GTCT (Z score=-2.114, p=0.034) and CTAGG (Z score=-2.121, p=0.033) haplotypes of CD28 and PTPN22 genes, may confer protection against T1D. These findings confirm the role of PTPN22 and CD28 involved in the T cell activation pathway in the development of T1D in Tunisian families. Interestingly, ZAP70 and TCRβ/CD3z seem to contribute to the susceptibility to the disease in our population. However, this finding has to be confirmed in further studies.

Polymorphism Study of Tcr α and γ Genes in Insulin Dependent Diabetes Mellitus (Iddm) Multiplex Families

T-cell receptor (TCR) alpha and gamma genes polymorphisms were analysed by Restriction Fragment Length Polymorphism (RFLP) in 10 Insulin Dependent Diabetes Mellitus (IDDM) multiplex families. TCR alpha and gamma alleles distribution does not significantly differ between affected and non affected children. Furthermore there was no excess of C alpha or V gamma allele sharing in affected sib pairs. Therefore the T-cell receptor alpha and gamma chain alleles studied do not seem to affect IDDM susceptibility per se.

Evidence for a novel type 1 diabetes susceptibility locus on chromosome 8

Type 1 diabetes results from a combination of genetic susceptibility and environmental exposures. Susceptibility loci other than HLA and the insulin gene remain to be identified to account for the degree of familial clustering observed in this disorder. Early genome-wide scans provided suggestive evidence of linkage on chromosome 8q, prompting detailed analysis of this region. A total of 20 microsatellite markers spanning an 88-cM region of 8q11-24 were genotyped in 24 type 1 diabetes pedigrees from Wisconsin that contained 39 affected sib-pairs. Multipoint linkage analyses provided close to suggestive evidence of linkage, with a multipoint logarithm of odds score (MLS) of 2.4 and Genehunter nonparametric logarithm of odds score (NPL) of 2.7 (P = 0.003). There is also evidence of linkage disequilibrium at peak marker D8S1823 for the 217bp allele (P = 0.037) using the pedigree disequilibrium test. Although our sample size was small, the multiple tests were consistent and our preliminary results suggested that 8q24 may harbor a novel population-specific type 1 diabetes susceptibility gene. Continued investigation of this region for a novel type 1 diabetes susceptibility gene appears justified.

Pathogenesis of insulin-dependent diabetes mellitus

Insulin-dependent diabetes mellitus is strongly associated with certain HLA types and the presence of islet cell-specific autoantibodies. The pathogenesis is a specific loss of pancreatic beta cells. The dissection of IDDM genes is complicated by the low recurrence rate of the disease among first-degree relatives. HLA-DQ2 and 8 are closest to IDDM with a marked synergistic effect of DQ2/8 heterozygotes. The associations with other HLA genes are often explained by linkage disequilibrium. Genetic factors on other chromosomes which influence the pathogenesis are still to be fully identified but candidates are on chromosomes 11 (insulin gene polymorphisms) and 7 (TCR gene polymorphisms). The autoreactivity against the GAD65 isoform is pronounced both before and at the clinical onset of IDDM. GAD65 autoantibodies show the highest predictive value and may represent an initiating autoantigen. Autoantibodies to numerous other beta cell autoantigens are detected at the clinical onset but may represent a secondary response and antigen spreading during a sustained autoimmune attack on the beta cells. The role of T cells in human IDDM is yet to be defined. GAD65 and other islet autoantibodies have a low positive predictive value for IDDM and further investigations are needed to clarify ways to predict IDDM in the general population.

Influence of deletion of T cell receptor V beta genes on the Theiler's virus model of multiple sclerosis

To determine the role of TCR V beta genes in a model of multiple sclerosis (MS), we studied Theiler's virus infection in congenic mice with deletion of TCR V beta chromosome. Congenic mice expressing the V beta a [50% deletion of TCR V beta] or V beta c 70% deletion of TCR V beta] haplotype were generated in mice resistant [B10 (H-2b)], intermediate [B10.K (H-2k), B10.RIII (H-2r)] or susceptible [B10.S (H-2s), and B10.Q (H-2q)] to Theiler's virus induced demyelination. Deletion of TCR V beta genes (V beta a or V beta c) did not convert B10 or B10.K congenic mice to susceptibility. In contrast, congenic B10.RIII-V beta c developed prominent demyelination and 10- to 100-fold increase in virus-antigen expression in spinal cord compared to B10.RIII mice. No effect on the extent of demyelination was observed in B10.S-V beta a, B10.S-V beta c or B10.Q-V beta c mice. These experiments illustrate the critical interactions between MHC, TCR, and background genes in susceptibility to immune-mediated disease.

T-cell receptor alpha, delta, and gamma chain genes in insulin-dependent diabetes mellitus

We have studied the genotypic, haplotypic, and allelic distribution of germline Restriction Fragment Length Polymorphism (RFLP) of T-cell receptor (Tcr) alpha, gamma, and delta loci in 75 insulin-dependent diabetes mellitus (IDDM) patients and 84 healthy blood donors as control population. The restriction endonuclease PvuII produces three allelic fragments of Tcr C gamma (TcrCG) gene segment of 16, 13, and 11.3 Kb respectively. Our observations revealed that PvuII/TcrCG RFLP allelic distributions were not significantly different in the IDDM and the control group. However, 85% of IDDM patients carried HLA DR3 and/or DR4 haplotypes, and when comparing these patients with a second group of HLA DR3+ and/or DR4+ healthy individuals, the 11.3 Kb/PvuII fragment of TcrCG gene was found to be associated with IDDM patients (chi 2 = 11.4, P = 0.003). 54.9% of IDDM patients carried at least one 11.3 Kb allele vs. 21% in controls (chi 2 = 10.77, P = 0.004). No significant association was found between RFLP in Tcr, C alpha, C delta, V gamma 9 loci and IDDM.

Silent allelic variants of a T-cell receptor V beta 12 gene are present in diverse human populations

Amino acid substitutions in variable regions of the T-cell receptor (TCR) can alter T-cell reactivity; however, relatively little is known about the extent of allelic variation in human TCR coding sequences. In the present studies, coding region variation in the human TCR V beta 12.2 gene was examined in detail. Virtually the entire V beta 12.2 coding region was screened for nucleotide substitutions by single-stranded conformational polymorphism analysis. Four alleles were identified in a sample population of 90 unrelated people from diverse genetic backgrounds. Three of the alleles were common, with estimated frequencies of 0.32, 0.47, and 0.20. Sequence analyses revealed that variation between the alleles was confined to three single-base differences in codons 24, 31, and 45; none of these changes altered the amino acid sequence. No evidence for other coding region differences in this gene were found. This analysis suggests that coding region variation in V beta 12.2 is limited, and amino acid sequence is highly conserved.

Association of rheumatoid arthritis with a dominant DR1/Dw4/Dw14 sequence motif, but not with T cell receptor beta chain gene alleles or haplotypes

HLA-DR, HLA-DQ, and T cell receptor beta (TCR beta) chain gene polymorphisms were investigated in 43 patients with rheumatoid arthritis (RA), in 10 patients with Felty's syndrome (FS), and in 5 RA multicase families. RA was found to be strongly associated with a DRB1 gene sequence motif present in DR1, DR4-Dw4, and DR4-Dw14 alleles. Ninety-three percent of RA patients were positive for at least 1 of these alleles, providing strong support for the "shared epitope hypothesis." The frequency distribution of this sequence motif suggests a dominant mode of inheritance. All 10 FS patients were DR4-Dw4 positive. Different DR-DQ associations among DR4 positive RA and FS patients indicate heterogeneity in the genetic susceptibility to these 2 disease entities. Furthermore, analyses of TCR V beta 8, V beta 11, and C beta gene polymorphisms did not support the notion of an influence of TCR beta germline allotypes on RA susceptibility.

Non-HLA region genes in insulin dependent diabetes mellitus

The focus of this chapter is on the contribution of genes outside the HLA region to insulin dependent diabetes mellitus (IDDM) susceptibility. We review laboratory evidence for such genes from published studies and also present unpublished data from our recent research. The existence of genes predisposing to IDDM in the region of the insulin (INS) gene now appears established. Association analysis has demonstrated an increased frequency of class 1 alleles of the 5' INS polymorphism in diabetics compared with controls, and a new method of analysis (AFBAC) has shown that this association is not an artefact of population stratification. Interestingly, the effect of INS region susceptibility on IDDM cannot be detected by linkage analysis, suggesting that if a genetic marker locus is close to a disease susceptibility locus, association analysis may be a more sensitive method than linkage analysis for detecting the susceptibility locus. There is no convincing evidence that genes in the T cell receptor beta chain (TCRB) or alpha chain (TCRA) regions influence predisposition to IDDM, either directly, or indirectly through interaction with HLA region genes. However, we present new evidence for interaction between TCRB and immunoglobulin heavy chain (Gm) region genes in IDDM: diabetics who are positive for the IgG2 allotype G2m(23) have significantly different frequencies of a TCRB restriction fragment length polymorphism (RFLP) than those who are negative for the allotype. Gm region genes also appear to have indirect effects on IDDM susceptibility through interaction with HLA and INS region genes: DR3/4 and non-DR3/4 diabetics have significantly different frequencies of G2m(23), and INS1/1 and non-INS1/1 diabetics also have significantly different frequencies of this allotype. To our knowledge, there are no other studies of Gm-TCRB or Gm-INS interaction in IDDM susceptibility. Evidence for Gm-HLA interaction in IDDM has been published by several other groups of investigators, however the specific phenotypic interaction effects reported have differed. Nevertheless, pooled data from three studies of Gm/HLA haplotype segregation in affected sib pairs shows significantly increased sharing of Gm haplotypes in affected pairs who share both HLA haplotypes. The biological mechanisms underlying the direct (HLA, INS) and indirect (Gm-TCRB, Gm-HLA, Gm-INS) effects of these genetic regions on IDDM susceptibility remain to be elucidated.

T cell defined HLA epitopes and T cell receptor polymorphism in insulin dependent diabetes mellitus

T cell defined epitopes on class II HLA molecules (epitopes distinguishable by T cells but not by antibodies) seem to be important determinants of IDDM susceptibility/resistance. Although HLA-DR4 is associated with IDDM in many populations, DR4-positive HLA haplotypes vary greatly (relative risk from greater than 10 to less than 1). This variation seems to depend on both the DQ allele and T cell defined subtypes of the DR4 allele. These IDDM associated alleles at the two loci (DQB1 and DRB1) are not correlated with each other in the healthy population, so they clearly are independent risk factors. HLA-DR2 has universally been associated with lack of IDDM, and seems to be protective. However, not all DR2 haplotypes protect, and the protection or lack of protection correlates with T cell defined subtypes of DR2. In this case, however, the DR2 subtypes do correlate with DQ alleles, so it is unclear which locus (loci) is (are) actually affecting the disease process. It may be significant that, for both DR2 and DR4, only the more protective subtypes have arginine at amino acid position 71. Other portions of the DR beta chain are clearly important, however. Although TCR alpha and beta seemed to be promising candidates for additional IDDM susceptibility genes, in fact the various TCR alpha and beta haplotypes are equal, or nearly equal, with regard to IDDM susceptibility. The importance of HLA alleles in IDDM susceptibility, and the lack of importance of TCR alpha and beta alleles, may be due to the different means by which the HLA and TCR molecules achieve antigen binding diversity: HLA molecules by multiple loci and allelic diversity, and TCR molecules by the tremendous diversity that can be generated from a single TCR allele during T cell maturation.

Germline repertoire of T-cell receptor beta-chain genes in patients with insulin-dependent diabetes mellitus

We have investigated the genotype and allelic distribution of germline restriction fragment length polymorphisms of the T-cell receptor beta chain, segment C beta, and two variable segments which are in linkage disequilibrium, V beta 8 and V beta 11, in 42 insulin-dependent diabetes mellitus (IDDM) patients and in 51 healthy blood donors used as controls. Recently, several works have reported contradictory results showing or not showing an association between polymorphic alleles of the C beta gene and diabetes type I. We found no significant differences in the allele, genotype, and haplotype distribution of the gene segments studied, between IDDM patients and control populations.

Autoimmune diseases: the failure of self tolerance

The ability to discriminate between self and nonself antigens is vital to the functioning of the immune system as a specific defense against invading microorganisms. Failure of the immune system to "tolerate" self tissues can result in pathological autoimmune states leading to debilitating illness and sometimes death. The induction of autoimmunity involves genetic and environmental factors that have focused the attention of researchers on the trimolecular complex formed by major histocompatibility complex molecules, antigen, and T cell receptors. Detailed molecular characterization of these components points to potential strategies for disease intervention.