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Query: UMLS:C0011849 (
diabetes
)
277,896
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Type I
diabetes
susceptibility genes have been identified within the major histocompatibility complex (MHC) on chromosome 6p21.3 and near the VNTR/insulin region on chromosome 11p15.5. We have used polymorphic dinucleotide repeat markers to search the human genome for additional susceptibility genes in 162 type I diabetic families with an affected sibling pair. We report that an additional susceptibility gene is located on chromosome 2q31 near HOXD8 (P < 10(-5), maximum logarithm of odds score = 4.8) in an analysis of affected sibling pairs having specific
human leukocyte antigen
(
HLA
) and hypervariable nucleotide tandem repeat (VNTR)/insulin gene haplotypes (absence of high-risk HLA-DR3/4 haplotypes and presence of homozygous high-risk class I VNTR alleles). These results suggest the interaction of a minimum of three genes in the pathogenesis of type I
diabetes
in humans.
Diabetes
1995 Jan
PMID:The HOXD8 locus (2q31) is linked to type I diabetes. Interaction with chromosome 6 and 11 disease susceptibility genes. 781 7
Type I
diabetes
is probably due to the immune-mediated destruction of islet insulin-secreting beta-cells. This chronic destructive process is associated with both cellular and humoral immune changes in the peripheral blood that can be detected months, even years, before the onset of clinical
diabetes
. Throughout this prediabetic period, metabolic changes, including altered glucose tolerance and reduced insulin secretion, deteriorate at variable rates toward full-blown
diabetes
. The ability to predict subsequent clinical
diabetes
in those nondiabetic individuals with immune and metabolic changes has led to attempts to prevent the disease onset by therapeutic intervention. A small fraction of individuals with immune changes develop clinical
diabetes
that does not require insulin treatment. The onset of
diabetes
in these cases is usually in adult life, and because their
diabetes
is, at least initially, not insulin-dependent, they appear clinically to have type II
diabetes
. Such patients probably have the same disease process as patients with type I
diabetes
in that they have similar
human leukocyte antigen
(
HLA
) genetic susceptibility as well as autoantibodies to islet antigens. It is proposed that non-insulin-dependent diabetic patients who have markers that characterize individuals at risk of type I
diabetes
may be suitable candidates for those same therapeutic strategies that seek to prevent progression to insulin-dependence or even to reestablish normal glucose tolerance.
Diabetes
Care 1994 Oct
PMID:Type I diabetes masquerading as type II diabetes. Possible implications for prevention and treatment. 782 Nov 48
Susceptibility to insulin-dependent
diabetes mellitus
(IDDM) is greatly influenced by polymorphisms in the genes of the class II region of the
human leukocyte antigen
(
HLA
) complex. The complexity of this genetic association and the lack of a direct proof of involvement of HLA class II genes in human IDDM have continued to support speculation on a possible role of genes encoded in the close vicinity of these loci in IDDM. Because the recently discovered transporter associated with antigen processing (TAP) and large multifunctional protease (LMP) genes are encoded in the HLA class II region and are implicated in the processing of antigenic proteins for presentation by HLA class I molecules, they are additional candidates for a role in IDDM pathogenesis. We have analyzed genomic and coding sequence polymorphisms in the LMP2, TAP1, and TAP2 genes of 77 Danish IDDM patients and 102 control subjects. Although patients and control subjects did not differ in TAP1 and LMP2 alleles, we found a striking absence of the TAP2 allele B (long form) in IDDM patients. An analysis of the TAP2 alleles in individual DR types, however, revealed that this phenomenon is likely to be caused by linkage disequilibrium between the two loci. Thus, polymorphisms in the TAP and LMP genes are unlikely to be associated with IDDM.
Diabetes
1994 Jan
PMID:Major histocompatibility complex-encoded antigen processing gene polymorphism in IDDM. 790 60
We established a T-cell line and 20 CD4+ T-cell clones from the peripheral blood lymphocytes of a type I diabetic patient using a membrane preparation of a rat insulinoma cell line (beta membrane antigen [BMA]) as a source of antigen. The T-cell line and three selected clones proliferated specifically to stimulation with BMA and to membranes prepared from human islets, rat pancreas, and NOD pancreas, but not to control antigens. Proliferation-inhibition studies using
human leukocyte antigen
(
HLA
)-specific monoclonal antibodies revealed
HLA
-DQw1-restricted recognition of BMA. An analysis of the T-cell receptor (TCR) repertoire of the T-cell line after 8 and 40 days of culture showed a prominent usage of the V alpha 1 and V alpha 12 gene families. Although sequencing of the TCR V alpha and V beta chains of the three clones demonstrated that each used different V alpha and V beta gene segments, structural similarities were found in complementary-determining region 3 (CDR3), the region that is postulated to interact with the peptide component of the TCR ligand. When we compared these TCR sequences with published sequences of disease-inducing T-cells of NOD mice, highly related TCR V beta families were detected. Furthermore, stretches of identical amino acids within the CDR3 region were found between two pairs of human and mouse T-cells. If one considers the species differences in TCR genes and sequence differences in the restriction elements for these cells (HLA-DQ vs. H-2 I-A nod), these sequence similarities are striking and may be useful for pinpointing T-cells of primary importance in the development of disease.
Diabetes
1994 Nov
PMID:HLA-DQ-restricted, islet-specific T-cell clones of a type I diabetic patient. T-cell receptor sequence similarities to insulitis-inducing T-cells of nonobese diabetic mice. 792 6
Genetic susceptibility to type I
diabetes
is partly determined by genes located in the
human leukocyte antigen
(
HLA
) region on chromosome 6. It has been claimed that the transmission of
HLA
-encoded susceptibility is influenced by parental sex. Fathers are reported to transmit HLA-DR4 haplotypes more frequently to their diabetic offspring than mothers. More recently, it has been suggested that the presence of HLA-DR4 in a mother may influence susceptibility in her offspring, even when it is not inherited. We have analyzed 172 multiplex diabetic pedigrees from the U.K. and find no evidence to support an important effect of parental sex on the inheritance of
HLA
-encoded susceptibility. Examination of a further 110 pedigrees from the U.S. supports this finding. These results have important implications for strategies involving genetic screening for type I
diabetes
.
Diabetes
1994 Dec
PMID:Parental origin of diabetes-associated HLA types in sibling pairs with type I diabetes. 795
Several lines of compelling epidemiologic evidence indicate that susceptibility to psorasis is inherited, albeit not in a simple monogenic fashion. Psoriasis is one of a number of diseases with a presumed autoimmune pathogenesis that display significant
human leukocyte antigen
(
HLA
) associations. However, only a small fraction of those who carry the implicated
HLA
susceptibility alleles develop disease. Taken together with the epidemiologic data indicative of high heritability, this observations suggests that one or more loci in addition to
HLA
are necessary for the development of psoriasis. As the identity of these other genes is unknown, genetic linkage analysis offers an attractive strategy for their identification. To this end, we have initiated a large linkage study of multiplex psoriasis kindreds, and PCR-based genotyping of CA repeat polymorphisms has been performed for several markers in the
HLA
region (6p21.3). As expected given the hypothesis of oligogenic inheritance, these analyses have thus far failed to reveal tight linkage of psoriasis to the 6p21 region. Nevertheless, the substantial homogeneity of the psoriatric phenotype and the clear evidence for increased
HLA
association and heritability in juvenile onset disease (40 years) indicate that, like insulin-dependent
diabetes mellitus
, psoriasis is an
HLA
-associated, genetically complex disease whose etiology is potentially amenable to elucidation through linkage analysis.
...
PMID:Epidemiology and the genetics of psoriasis. 800 29
Because of anatomical limitations, molecular characterization of islet-inflammatory T-cells in human insulin-dependent
diabetes mellitus
(IDDM) has remained elusive. We have isolated isletitis T-cells from pancreas graft biopsies of two patients (syngeneic and allogeneic, respectively) shortly after onset of recurrent IDDM and have characterized their repertoire by sequencing T-cell receptor (TcR)-specific cDNAs. Histopathological analysis of the grafts revealed selective beta-cell loss and isletitis characteristic of recurrent disease with no evidence of chronic inflammation or rejection. Most of the in vivo-activated isletitis T-cells were CD8+TcR alpha beta+ and CD4-CD8-TcR gamma delta+ in both patients. Comparison of the different TcR alpha,beta,gamma, and delta sequences revealed V(D)J junctional heterogeneity but skewed TcR usage within patients. Eighth of 13 different isletitis TcR beta sequences (19 of 26 cDNAs) from the syngeneic graft of patient 1 were V beta 3+, as opposed to only 1 of 31 peripheral TcR beta sequences (1 of 31 cDNAs) (61.5 vs. 3.2%, P < 0.0001). Of the 19 different isletitis TcR alpha clonotypes of this patient (24 of 42 cDNAs), 5 were V alpha 14+. The isletitis TcR beta clonotypes of the
human leukocyte antigen
-identical allogeneic graft of patient 2 showed selective J beta, but not V beta, gene usage. Two of three predominant isletitis clonotypes of patient 2 were V alpha 22+ (19 of 28 cDNAs) and the other (5 of 28 cDNAs) was also V alpha 14+.(ABSTRACT TRUNCATED AT 250 WORDS)
Diabetes
1994 Apr
PMID:Skewed T-cell receptor usage and junctional heterogeneity among isletitis alpha beta and gamma delta T-cells in human IDDM [corrected]. 802 53
The transporter associated with antigen processing (TAP) encoded in the major histocompatibility complex (MHC) class II region is a molecule required for endogenous antigen processing. We have typed TAP polymorphism in 95 Japanese patients with insulin-dependent
diabetes mellitus
(DDM) and 75 normal controls. Amino acid substitutions at positions 333 and 637 of TAP1 and at positions 379, 665, and 687 of TAP2 were typed by the polymerase chain reaction (PCR)-sequence-specific oligonucleotide method. In addition, DNA typing of
human leukocyte antigen
(
HLA
)-DQA1 and -DQB1 loci was performed by the PCR-restriction fragment length polymorphism method. There was no significant difference between IDDM patients and normal controls in the frequencies of TAP1 and TAP2 alleles. On the contrary, the HLA-DQ locus showed a strong association with IDDM in the same series of subjects. The frequencies of
HLA
-DQA1*0301 and -DQB1*0401 were increased significantly and those of
HLA
-DQA1*0103, -DQB1*0501, -DQB1*0601 and -DQB1*0602 were decreased significantly in Japanese IDDM patients compared with normal controls. Positive linkage disequilibrium was observed between
HLA
-DQB1*0303 and TAP2C and between
HLA
-DQB1*0401 and TAP2B. Negative linkage disequilibrium was observed between
HLA
-DQA1*0103 and TAP2A. Even when subjects with
HLA
-DQA1*0103, -DQA1*0301, -DQB1*0302, -DQB1*0303, and -DQB1*0401 were considered separately, no significant differences was found in the distribution of TAP1 and TAP2 alleles between IDDM patients and normal controls. We conclude that it is not TAP but HLA-DQ that exhibits a primary association with Japanese IDDM.
...
PMID:Lack of association of the transporter associated with antigen processing with Japanese insulin-dependent diabetes mellitus. 805 40
Glucagon-like polypeptides, GLP-1-(7-36)-amide and GLP-1-(7-37), are important regulators of insulin synthesis and secretion by islet beta-cells. The hypothesis to be tested in this study was that defects in the islet beta-cell GLP-1 receptor gene contribute to the impaired glucose-regulated insulin secretion of non-insulin-dependent
diabetes mellitus
(NIDDM). Human islet GLP-1 receptor genomic clones were isolated, and two highly polymorphic simple sequence repeat regions (GLP-1R-CA1 and GLP-1R-CA3) were identified. Polymerase chain reaction assays were developed to define alleles. For GLP-1R-CA1, 14 alleles were observed in African-Americans (heterozygosity [het] = 0.78) and 6 alleles in Caucasians (het = 0.67). For GLP-1R-CA3, 16 alleles were observed in African Americans (het = 0.89) and 8 alleles in Caucasians (het = 0.83). By genotyping all members of the 40 reference Centre d'Etude du Polymorphisme Humain pedigrees at GLP-1R-CA3, the human GLP-1 receptor gene was uniquely placed on chromosome 6p between GLO1 and D6S19, 20.4 cM from
human leukocyte antigen
. To assess the possible role of the GLP-1 receptor gene in determining the genetic susceptibility to NIDDM, allelic frequencies of GLP-1R-CA1 and GLP-1R-CA3 were compared between African-American NIDDM patients (n = 95) and control subjects (n = 93). The frequencies did not differ between the two groups at either GLP-1R-CA1 or GLP-1R-CA3. The GLP-1 receptor gene simple-sequence repeat polymorphisms were used for linkage analysis in Utah Mormon pedigrees (n = 16) with NIDDM.(ABSTRACT TRUNCATED AT 250 WORDS)
Diabetes
1994 Jun
PMID:Human glucagon-like peptide-1 receptor gene in NIDDM. Identification and use of simple sequence repeat polymorphisms in genetic analysis. 819 59
A combination of immune, genetic, and metabolic markers potentially implicated in the development of insulin-dependent
diabetes mellitus
(IDDM) was studied in the general population. We screened 3,992 healthy schoolchildren, 12-18 years of age with no family history of IDDM, for islet cell antibodies (ICAs). Of the children, 69 (1.7%) were found to be ICA positive (ICA+), of whom 7 (0.17%) also were positive for insulin autoantibodies (IAAs). ICA+ children (group 1) were
human leukocyte antigen
(
HLA
) typed at the DQ locus along with 123 matched (group 2) and 235 random (group 3) control subjects (from the original cohort of 3,992). Of the ICA+ children, 28 underwent beta-cell function (beta-CF) studies. High-risk DQ types were surprisingly prevalent in all groups with 35.8% of random control subjects carrying DQB1*0302 and 8.9% carrying the highest risk
HLA
type for IDDM, DQB1*0302/*0201. Those individuals with higher ICA titer (> 19 Juvenile Diabetes Foundation units [JDF U]) had a significantly higher prevalence of DQB1*0302 than those with lower titer ICA or normal control subjects. Six of 7 individual positive for both ICA and IAA and typed at the DQ locus were DQB1*0302/*0201 heterozygotes or DQB1*0302 or DQB1*0201 homozygotes, representing three of the highest risk genotypes for IDDM. No correlation was observed between ICA titer or DQ type and beta-CF except that all those with beta-CF below the 5th percentile carried either DQB1*0302 or DQB1*0201. Prospective follow-up is underway to determine if any combination of DQ type and immune markers predicts decline in beta-CF and the development of IDDM.
Diabetes
1994 Jan
PMID:High genetic risk for IDDM in the Pacific Northwest. First report from the Washington State Diabetes Prediction Study. 826 22
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