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Query: UMLS:C0011860 (type 2 diabetes)
57,723 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In searching for a genetic marker of type 2 diabetes we estimated the frequency of alleles of the Bgl II restriction fragment length polymorphism (RFLP) of the insulin receptor gene in a group of type II diabetic patients (n = 50), characterized by OGTT (glucose, insulin, C-peptide) and insulin receptor binding parameters. Leucocyte DNA was incubated with restriction endonuclease Bgl II and specific fragments were determined by Southern blot technique, using radioactive plasmid pINSR 13.1 as insulin receptor gene probe for hybridization. Insulin receptor numbers and receptor affinity were estimated by 125I-(Tyr-A-14)- insulin binding to red blood cells. Among control subjects the 20 kb fragment (allele Bgl II+) had a frequency of 0.21. In our group of diabetic patients this allele had a frequency of 0.10 (n.s., p greater than 0.05). In our study the insulin receptor genotype had no influence on body mass index, insulin and C-peptide during OGTT as well as insulin receptor binding data. So far, etiopathogenetic linkage between diabetes and insulin receptor variants (mutants) could unambiguously be proved in patients with extreme insulin resistance only. In our opinion, the estimation of the role of the gene as the reason underlying the disease inevitably requires the investigation of large families with multiple occurrence of type 2 diabetes.
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PMID:Restriction fragment length polymorphism of the insulin receptor gene, type 2 diabetes and insulin binding. 168 Jul 59

There are two approaches to identify diabetes-susceptibility genes. One approach is to isolate and characterize genes expressed in the beta-cell and in insulin target tissues whose mutation or altered expression may contribute to the development of diabetes mellitus. Another approach is to clone a diabetes-susceptibility gene by a reverse genetic strategy. The first step for this strategy is to identify a DNA polymorphism that is linked to the disease locus. Using the strategy of the first approach, several candidate genes were examined. Among these genes, the mutation of insulin genes and insulin receptor genes was found in the patient with diabetes. By cDNA cloning or PCR-direct sequencing methods, we identified several mutations in the insulin receptor genes of four insulin-resistant diabetic patients. At least two mutants of insulin receptor genes were expressed in Chinese hamster ovary cells and these mutated receptors showed impaired ability to transduce insulin action in these cultured cells. The expression of these mutant genes in animals such as transgenic mice will be indispensable to establish the relationship between the gene mutation and the abnormality found in the patient. Using the strategy of the second approach, Bell et al. recently reported that the gene responsible for MODY (maturity-onset diabetes of the young) is tightly linked to the adenosine deaminase gene on chromosome 20q. However, this strategy will not be applicable for identification of diabetes-susceptibility genes of NIDDM, since this disorder is likely to be genetically heterogenous, with mutations in several different genes able to cause hyperglycemia, and this heterogeneity could confound the linkage analysis.
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PMID:[Diabetes mellitus and molecular biology]. 177 65

Sulfonylureas are widely used drugs in the treatment of NIDDM when diet treatment is unsuccessful. In addition to their pancreatic effects sulfonylureas have been reported to have insulin-like and insulin-potentiating actions in vitro with respect both to glucose transport and glycogen synthase activation in isolated adipocytes and hepatocytes from rats. Glycogen synthesis in muscle accounts for the major part of non-oxidative glucose metabolism during insulin stimulation. Treatment with gliclazide of patients with NIDDM has been shown to be associated with a potentiation of both insulin-mediated glucose disposal and insulin-stimulated glycogen synthase activity in skeletal muscle. Muscle insulin receptor binding or insulin receptor kinase activity was shown not to be affected by gliclazide treatment. Whether the improved insulin sensitivity and improved insulin action on skeletal muscle glycogen synthase during gliclazide treatment is due to a direct or an indirect action of the drug is discussed.
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PMID:Gliclazide and insulin action in human muscle. 179 67

Family studies suggest a strong genetic component in the aetiology of non-insulin dependent diabetes (NIDDM), with evidence for a major gene of co-dominant or dominant effect. A gene-dosage effect, whereby diabetes develops earlier in people with two susceptibility genes than in those with one susceptibility gene is likely. The search for the diabetes gene has led to the cloning and characterization of many genes involved in controlling glucose homeostasis. These include the insulin, insulin receptor, glucose transporter, amylin and glucokinase genes. Molecular techniques have permitted rapid screening of these genes in NIDDM patients and controls. There is now a rather contradictory genetic literature for NIDDM, with weak disease associations reported and refuted for most candidate genes. However, pedigree analyses and DNA sequencing of available candidate genes and their regulatory regions have failed to implicate any of these in the common form of diabetes, NIDDM. Methodical application of random clones in well-defined NIDDM families may be the strategy of choice in finding the NIDDM genes, given the wide range of genes potentially involved in the glucose and lipoprotein metabolic disturbances seen in NIDDM.
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PMID:Genetics of non-insulin dependent diabetes mellitus in 1990. 189 73

In vivo studies indicate that patients with NIDDM have defects in both insulin secretion and insulin action. The decrease in insulin action is due to both hepatic and extrahepatic insulin resistance. The impairment in glucose uptake is associated with alterations in both oxidative and nonoxidative disposal. Defective glucose transport may limit both of these processes. NIDDM also is associated with increased concentrations and rates of oxidation of plasma free fatty acids. Insulin resistance appears to be familial and in at least some individuals antedates glucose intolerance. In vitro studies indicate that insulin resistance can involve a variety of insulin sensitive tissues including adipocytes, muscle and liver. While most studies note that insulin binding and insulin receptor kinase activity are decreased in insulin sensitive tissues in obese patients with NIDDM, further delineation of the contribution of obesity and diabetes is required. Alterations in glucose transporter number and function likely account at least in part for impaired glucose transport. The cause of the alterations in other insulin responsive pathways and the role of an abnormal metabolic milieu versus intrinsic cellular defects remain to be established.
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PMID:Insulin resistance in type II diabetes mellitus. 216 26

The insulin receptor binding ability was studied in 26 persons with above normal body mass (15 women and 11 men), mean age 44.15 +/- 10.1 years without family history of diabetes mellitus. According to the degree of obesity they were classified into 3 groups. In the persons with I-II degree of obesity parallel with the strongly reduced number of insulin receptors (total and the high affinity) an increase of the receptors affinity appears as a compensatory mechanism which ensures appropriate insulin receptor binding. In the persons with III-IV degree of obesity the number of insulin receptors is strongly reduced but the receptor affinity does not differ from that of the controls with normal body mass. The receptor changes in the persons with excessive obesity are similar to those found by the authors in patients with newly discovered non-insulin dependent diabetes mellitus. This allows the suggestion that these persons are in a potential risk of developing diabetes mellitus.
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PMID:[Insulin receptor function in subjects with above-normal body weight]. 228 6

Obesity is associated with insulin resistance and type II diabetes mellitus. In the present study, we have characterized hepatic insulin receptor function in two animal models of obesity: the Zucker fatty rat (ZFR), a model of genetic obesity with severe hyperinsulinemia, and the Sprague-Dawley rat with dietary obesity, a model of acquired obesity. Zucker fatty rats were also treated with streptozotocin (STZ) in an effort to examine the effects of relative insulin deficiency and hyperglycemia in the setting of obesity. Using wheat germ agglutinin-purified insulin receptor extracted from liver, no significant difference in insulin binding was identified in either model of obesity. beta-Subunit autophosphorylation was significantly decreased in both obese models relative to that in controls (72% in the obese ZFR and 49% in the overfed Sprague-Dawley model). Kinase activity, as measured by phosphorylation of the 1142-1153 synthetic peptide, was also decreased in both models of obesity by 22% and 64%, respectively. In the Zucker rat, STZ treatment led to an 80% increase in receptor concentration and a further 70% increase in beta-subunit autophosphorylation per receptor, whereas tyrosine kinase activity toward substrate was not altered. Since kinase activity is closely linked to autophosphorylation, we determined the fraction of autophosphorylated (activated) receptors vs. non-phosphorylated (inactive) receptors by using antiphosphotyrosine antibody to precipitate receptors bound with [125I]insulin. There was no significant difference in the percentage of activated insulin receptors in the dietary obese, ZFR, or STZ-treated Zucker rat vs. that in the controls. In all models, the percentage of activated receptors ranged from 32-46% of the total receptor pool. These data suggest that in genetic and acquired obesity, autophosphorylation of the beta-subunit is reduced and is a limiting factor in insulin receptor activation. A similar fraction of all receptors appears to undergo some level of autophosphorylation; however, full autophosphorylation and, thus, activation of the receptor do not occur, and this results in a decrease in kinase activity. This block in autophosphorylation may account for significant reductions in insulin receptor kinase function in obesity.
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PMID:Alterations in the hepatic insulin receptor kinase in genetic and acquired obesity in rats. 255 53

Gestational diabetes mellitus (GDM) is defined as glucose intolerance with onset or first recognition during pregnancy. We have examined restriction fragment length polymorphisms (RFLPs) near "candidate diabetogenic genes" as one approach to identify molecular markers for GDM genes. Genotypes for insulin hypervariable region (HVR), insulin-like growth factor II (IGF2), insulin receptor (INSR), and glucose transporter (GLUT1) RFLPs were studied in 96 GDM and 164 control subjects, matched to GDM for race, age, and gravidity. Logistic regression analysis was used to explore the relationship between genotypes at these candidate gene loci and GDM, while adjusting for the effects of potential confounding variables. Among black subjects, the INSR allele 1 (P = 0.001) and interactions between INSR allele 1 with body mass index (BMI) (P = 0.002) and history of DM in subject's mother (P = 0.004) contributed significantly to GDM risk. Among Caucasian subjects, a similar relationship between the INSR allele 1 (P = 0.007) and INSR allele 1-BMI interactions (P = 0.011) on GDM risk were observed. In Caucasians, an additional significant risk factor was determined by an INSR allele 1-IGF2 allele 2 interaction (P = 0.018). No risk factors were identified in Hispanic subjects. These data continue to support the hypothesis that GDM is a heterogeneous disorder with respect to phenotypic and genotypic features. Furthermore, our data suggest that risk for GDM in black and Caucasian subjects is not due to obesity perse but to interactions between obesity and INSR alleles. In Caucasian women, INSR and IGF2 alleles interact to confer additional risk for GDM. Thus genes underlying susceptibility to GDM in some women may be similar to genes conferring risk to NIDDM, while in others novel genes may contribute to GDM risk.
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PMID:Increased risk for gestational diabetes mellitus associated with insulin receptor and insulin-like growth factor II restriction fragment length polymorphisms. 257 27

This review summarized aspects of the widening scope, phenotypic expression, natural history, recognition, pathogeneses, and heterogenous nature of maturity-onset diabetes of the young (MODY), an autosomal dominant inherited subtype of NIDDM, which can be recognized at a young age. There are differences in metabolic, hormonal, and vascular abnormalities in different ethnic groups and even among Caucasian pedigrees. In MODY patients with low insulin responses, there is a delayed and decreased insulin and C-peptide secretory response to glucose from childhood or adolescence, even before glucose intolerance appears; it may represent the basic genetic defect. The nondiabetic siblings have had normal insulin responses for decades. The fasting hyperglycemia of some MODY has been treated successfully with sulfonylureas for more than 30 years. In a few, after years or decades of diabetes, the insulin and C-peptide responses to glucose are so low that they may resemble those of early Type I diabetes. The rate of progression of the insulin secretory defect over time does distinguish between these two types of diabetes. In contrast are patients from families who have very high insulin responses to glucose despite glucose intolerance and fasting hyperglycemia similar to those seen in patients with low insulin responses. In many of these patients, there is in vivo and in vitro evidence of insulin resistance. Whatever its mechanism, the compensatory insulin responses to nutrients must be insufficient to maintain normal carbohydrate tolerance. This suggests that diabetes occurs only in those patients who have an additional islet cell defect, i.e., insufficient beta cell reserve and secretory capacity. In a few MODY pedigrees with high insulin responses to glucose and lack of evidence of insulin resistance, an insulin is secreted which is a structurally abnormal, mutant insulin molecule that is biologically ineffective. No associations have been found between specific HLA antigens and MODY in Caucasian, black, and Asian pedigrees. Linkage studies of the insulin gene, the insulin receptor gene, the erythrocyte/Hep G2 glucose transporter locus, and the apolipoprotein B locus have shown no association with MODY. Vascular disease may be as prevalent as in conventional NIDDM. Because of autosomal dominant transmission and penetrance at a young age, MODY is a good model for further investigations of etiologic and pathogenetic factors in NIDDM, including the use of genetic linkage strategies to identify diabetogenic genes.
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PMID:Maturity-onset diabetes of the young (MODY). 268 21

Diabetes mellitus is a clinically heterogeneous disorder which is characterized by hyperglycaemia due to an absolute or relative deficiency of insulin. Both genetic and non-genetic factors contribute to its development and, as such, it represents a multifactorial disorder. In addition, it may also be, in some instances, a polygenic disorder resulting from the cumulative effects of several genes with or without environmental factors. Serological and/or DNA markers for genes that confer susceptibility to the insulin-dependent form of the disorder (IDDM; type 1) have been identified in the HLA-D region of chromosome 6 and near the insulin gene on chromosome 11. Patients with non-insulin-dependent diabetes mellitus (NIDDM; type 2) make up a more heterogeneous group than those with IDDM and it is likely that in these patients similar clinical phenotypes may be produced by different genetic defects. The synthesis of either an abnormal insulin/proinsulin molecule or an abnormal insulin receptor can confer susceptibility to NIDDM. The genes encoding insulin and the insulin receptor are on chromosomes 11 and 19, respectively. In addition, studies of restriction fragment length polymorphism and disease associations suggest that two other genes may contribute to the development of NIDDM on chromosome 11, one near the insulin gene on the short arm of this chromosome and the other near the apolipoprotein A-I gene on the long arm. None of the susceptibility genes that have been identified to date causes diabetes in the absence of other genetic or non-genetic contributing factors, which is consistent with a multifactorial or polygenic origin for this disorder.
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PMID:The molecular genetics of diabetes mellitus. 289 28

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