Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0011854 (type 1 diabetes)
20,749 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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

Insulin-dependent diabetes mellitus (IDDM) is characterized by autoimmune destruction of the insulin secreting beta-cells of the pancreas and subsequent disruption of glucose metabolism. The tendency of IDDM to cluster in families and the modest (36%) concordance rate in monozygotic twins indicates that both genetic and environmental factors contribute to IDDM susceptibility. Recent genome-wide searches using the affected sib-pair (ASP) approach have provided evidence for novel loci, in addition to HLA (IDDM1) and insulin (IDDM2), which show evidence of linkage to IDDM (P < 0.05). We have evaluated 35 microsatellite marker loci on human chromosome 7 for linkage to IDDM in 339 affected sib-pair families. Increased sharing of parental haplotypes in affected sib-pairs was detected for two microsatellite markers flanking glucokinase (GCK). Preferential transmission of alleles to affected offspring was observed at one of these marker loci, GCK3, indicating linkage disequilibrium between the marker and a disease susceptibility locus. This combination of linkage and disease association suggests that glucokinase, or a gene in the vicinity, plays an important part in IDDM susceptibility.
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PMID:Linkage and association between insulin-dependent diabetes mellitus (IDDM) susceptibility and markers near the glucokinase gene on chromosome 7. 766 23

Candidate genes for NIDDM have been screened in Japanese. Mutations in the glucokinase gene were found in apparent late-onset NIDDM patients as well as in MODY patients. Clinical characteristics in the subjects with glucokinase gene mutations are similar to those in Caucasian subjects; diabetes mellitus is generally mild and some patients actually remain as having impaired glucose tolerance. Of great interest is that all affected subjects show blunted insulin secretion response to the glucose challenge, which is most commonly observed in Japanese NIDDM patients. Thus, it is possible that impairment in the regulation of glucokinase gene expression or its enzyme activity is associated with at least some Japanese NIDDM patients, though the prevalence of the mutations in the coding region is relatively low. In contrast, a mitochondrial tRNA(Leu(UUR)) gene mutation at np 3243 appears to be much more common, and diabetes due to this mutation has a progressive nature. Insulin secretory capacity progressively decreases, eventually reaching an insulin-dependent state in most patients. A surprising result is that this gene mutation is often observed in ICA-positive IDDM patients who were initially non-insulin-dependent, so called slowly progressive IDDM patients. These results suggest that the mitochondrial gene mutation may cause beta cell loss in addition to defects in glucose-induced signaling in pancreatic beta cells, which explains that the mitochondrial gene mutation manifests a wide range of diabetic phenotypes, from NIDDM to IDDM.
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PMID:NIDDM--genetic marker; glucose transporter, glucokinase, and mitochondria gene. 785 92

Non insulin dependent diabetes mellitus (Type 2) is a multifactorial disease, with a polygenic inheritance and environmental factors contributing to its clinical expression. The search for the genetic determinants of Type 2 diabetes began when several genes involved in the mechanisms of insulin secretion or action were cloned, localized in the human genome, and when informative polymorphisms were described within or in the vicinity of these genes. It then became possible to compare, in groups of patients and normoglycaemic controls from various populations, the frequency of the different alleles of polymorphic markers of various candidate genes (e.g. insulin, insulin receptor, glucose transporters). The conflicting results observed in these studies can be ascribed to the small size of the population samples, to the genetic heterogeneity of Type 2 diabetes mellitus, but also to the methodology used therein. Indeed, these studies searched for a correlation between the frequency of certain alleles or genotypes and the phenotype of diabetes (studies of associations in affected populations compared to healthy controls). However in order to attribute to a gene the responsibility for a disease it is necessary to demonstrate the cotransmission in affected kindreds of a morbid allele of the gene along with the disease (familial or linkage analysis). The aim of this review is to summarize the results of family studies of Type 2 diabetes and Maturity Onset Diabetes of the Young (MODY), particularly with concern to the mutations described in candidate genes, and the implication of glucokinase in these disorders.
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PMID:Genetic determinants of type 2 diabetes mellitus: lessons learned from family studies. 850 79

The aim of our study was to investigate the relative prevalence of the different forms of diabetes in young adults and their respective clinical characteristics. Included were 51 nonobese patients (BMI < 27 kg/m2) with diabetes diagnosed before age 40, excluding typical IDDM. Each patient was subjected to screening for glucokinase gene (MODY2) and mitochondrial DNA (at nucleotide 3243) mutations, to HLA class II genotyping, and screening for the presence of islet cell antibodies (ICAs) and anti-GAD antibodies. Informative families were analyzed for linkage of diabetes to chromosome 12q (MODY3). Based on clinical criteria, patients were subdivided into MODY (n = 19) and non-MODY (n = 32). In the MODY group, we identified three patients with MODY2, one with the 3243 mitochondrial mutation, and another with autoimmune diabetes. One of the five MODY families available for linkage study was shown to have MODY3. In the non-MODY group, we found five patients with autoimmune diabetes and one with MODY2. No clinical parameter was helpful to classify patients in one of these subclasses of diabetes; however, the glucagon-stimulated C-peptide was useful to discriminate between MODY2 patients and the others. In conclusion, young and lean non-insulin-dependent diabetic patients constitute a very heterogeneous group, although they present similar clinical characteristics. The clinical distinction of MODY and non-MODY patients allows correct classification in, at most, 75% of the patients and thus is not sufficient to predict clinical course. However, immunological and genetic parameters allowed us to classify only 25% of the patients in specific diagnostic classes.
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PMID:Diagnostic heterogeneity of diabetes in lean young adults: classification based on immunological and genetic parameters. 907 2

Insulin gene was induced into differentiated hepatic cell line. These cells released immunoreactive insulin (IRI) of which molecular weight was greater than mature insulin. The secretion of IRI was responsive to glucose concentration and inhibited by glucose metabolism antagonist, 2-deoxy glucose (2-DOG). The mRNA of GLUT2 and glucokinase (GK) were not detected in these cells by Northern blotting. The glucose metabolism process is supposed to play an important role in the glucose responsive IRI release. It is assumed that hepatic cells have metabolic "glucose sensor", and insulin gene transduction to hepatic cells can be a physiological way of gene therapy for IDDM.
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PMID:The IRI release from insulin gene-transduced hepatic cells responds to ambient glucose concentration. 914 60

Glucokinase plays an important role in the regulation of insulin secretion and is therefore an attractive candidate gene for both insulin dependent (IDDM) and non-insulin-dependent (NIDDM) diabetes mellitus. A single G-A nucleotide polymorphism at the -30 position of the beta-cell specific promoter region of the glucokinase gene was previously associated with reduced beta-cell function. In the present study we analysed 268 consecutive newly diagnosed Swedish patients classified with either IDDM (n = 205), NIDDM (n = 31) or unclassifiable (n = 32) diabetes between the ages of 15 and 35 years along with a group of 158 age- and sex-matched control subjects. The beta-cell promoter region was amplified by the polymerase chain reaction and the G-A variant identified by single strand conformational polymorphism. There was no significant difference in allele frequencies of G and A between any of the subject groups and likewise, no significant difference in the frequencies of the G/G, G/A, or A/A genotypes. Eight subjects were homozygous for the less common A allele, five had IDDM and three were control subjects. Our results suggest that the -30 beta-cell glucokinase promoter variant is not associated with IDDM.
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PMID:The beta cell glucokinase promoter variant is an unlikely risk factor for diabetes mellitus. Diabetes Incidence Study in Sweden (DISS). 926 92

Diabetes, known since antiquity, has been defined by glycosuria. In 1886, when Minkowski demonstrated that pancreatectomized dogs developed diabetes, the islets of Langerhans became a focus of the search for an active principle culminating in the discovery and the isolation of insulin in 1921 by Banting, Best and Collip. In 1959, the radioimmunoassay of Yalow and Berson solidified the concept of insulin resistance in non-insulin dependent diabetes (NIDDM). In 1971, the insulin receptor was defined as a cell surface protein that initiated the insulin signal transduction cascade. Today, we know that NIDDM accounts for at least 90% of all diabetes worldwide and involves approximately 100 million people. The microvascular complications of NIDDM are the same as for insulin dependent diabetes (IDDM) and are related to the intensity and duration of hyperglycaemia. Further, it is clear from the Diabetes Control and Complications Trial (DCCT) that all microvascular complications can be reduced with intensive control of the blood glucose. Macrovascular disease is also accelerated in NIDDM, including both hypertension and dyslipidemia. The major risk factor for NIDDM are age, obesity, physical inactivity, and genetic background. The earliest features seen in individuals destined to develop NIDDM is insulin resistance, but for hyperglycaemia to ensure there must be a defect in insulin secretion. Thus, insulin resistance defines the prehyperglycaemic phase of NIDDM, but varying degrees of insulin secretory deficiency define the hyperglycaemic phase. Macrovascular risk occurs throughout the lifetime of the individual, whereas microvascular risk ensues with the inception of hyperglycaemia. Tomorrow, we will understand more clearly whether lifestyle changes, such as diet and exercise, or new classes of drugs, can delay or prevent NIDDM. Clinical trials are now beginning to test whether impaired glucose tolerance (IGT) can be delayed or prevented from moving to overt NIDDM. The genetics of NIDDM are under intense study. Mutations in the insulin receptor lead to NIDDM in a small number of patients, and mutations in the glucokinase gene lead to maturity onset diabetes of the young (MODY). Work is now underway to study other candidate genes as well as work on positional cloning techniques to identify diabetes genetic loci. The hormone Leptin has just been discovered and is a major regulator of body weight. In summary, the most important new emphasis on the treatment of NIDDM is the recognition of the importance of hyperglycaemia and our ability to both treat and possibly prevent this metabolic perturbation. This joins the longer-term emphasis on cardiovascular risk reduction from both treatment and prevention of hypertension and dyslipidemia.
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PMID:Non-insulin dependent diabetes--the past, present and future. 928 27

One form of maturity-onset diabetes of the young, MODY3, is characterized by a severe insulin secretory defect, compared with MODY2, a glucokinase-deficient diabetes. It has recently been shown that mutations of the gene encoding the transcription factor hepatocyte nuclear factor (HNF)-1 alpha cause MODY3. Because of the rapid progress to overt diabetes and the high prevalence of required insulin treatment in patients with MODY3, we screened the HNF-1 alpha gene for mutations in Japanese subjects with IDDM. Ten exons and flanking introns of the HNF-1 alpha gene in these subjects were amplified by polymerase chain reaction and direct sequencing of the products. Mutations were identified in three (5.5%) of the 55 unrelated subjects with IDDM. A missense mutation of R272H (replacement of Arg by His in codon 272) in the DNA binding domain of HNF-1 alpha was found in a subject who developed IDDM 1 year after diagnosis of NIDDM at 8 years of age. A frameshift mutation of P291 fsinsC (insertion of a C in a polyC tract around codon 291 for Pro), which would generate a mutant truncated protein of 340 amino acids, was found in a subject who started insulin treatment when hyperglycemia and ketonuria were noticed at 13 years of age. A missense mutation of R583G (replacement of Arg by Gly in codon 583) in the transactivation domain of HNF-1 alpha was found in a subject with sudden-onset IDDM at 20 years of age. None of these mutations were present in 100 nondiabetic subjects (200 normal chromosomes). These results indicate that the HNF-1 alpha gene defects could lead to the development of not only early-onset NIDDM but also IDDM, implicating the importance of subclassification of HNF-1 alpha-deficient IDDM from a classical type of autoimmune-based IDDM in Japanese.
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PMID:Identification of mutations in the hepatocyte nuclear factor (HNF)-1 alpha gene in Japanese subjects with IDDM. 931 63

Well-characterized defects in insulin secretion, most notably a loss of glucose-induced insulin secretion, are found in virtually all forms of NIDDM, as well as in early IDDM. Similar abnormalities have been found in all animal models of diabetes in which they have been studied. A novel hypothesis is being proposed to explain the mechanisms responsible for these alterations. Many abnormalities in the various steps of glucose-induced insulin secretion have been identified in rodent models of diabetes, but none by itself seems sufficient to explain the defects. These include a loss of GLUT2, glycogen accumulation, glucose recycling, abnormal glucokinase or hexokinase, altered mitochondrial glycerol phosphate dehydrogenase (mGPDH) activity, abnormal ion channel function and beta cell degranulation. We propose that optimal secretory function is dependent upon the unique differentiation of beta cells that is maintained by a set of transcription factors and that this control is disrupted by the diabetic state. Therefore, we propose that key transcription factors are affected even when beta cells are stressed by insulin resistance in very earliest stages of diabetes and that the abnormality becomes more severe as full-blown diabetes develops, which leads to loss of beta cell differentiation and a resultant derangement of insulin secretion.
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PMID:Transcription factor abnormalities as a cause of beta cell dysfunction in diabetes: a hypothesis. 940 38


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