Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0011849 (diabetes)
277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Glucokinase from rat liver or transplantable, radiation-induced insulinomas was partially purified by ion exchange chromatography using DEAE-Cibacron Blue F3GA agarose. Phosphorylation of alpha,beta-D-mannose by glucokinase occurred with cooperative rate dependence on mannose concentration (nH: 1.50). Half-maximal phosphorylation rate occurred at 14 mM alpha,beta-D-mannose. The alpha- and beta-anomers of mannose were phosphorylated with sigmoidal kinetics (nH: 1.57 and 1.42, respectively). The affinity of glucokinase for alpha-D-mannose is higher than for beta-D-mannose (S0.5: 12 mM versus 19 mM). The maximum phosphorylation rate is slightly higher, about 10%, with beta-D-mannose than with alpha-D-mannose. Islet glucokinase has previously been shown to be chromatographically and kinetically identical to glucokinase from insulinoma and liver; therefore, evidence that glucokinase from these two tissues phosphorylates mannose with cooperative rate dependence and differentiates mannose anomers supports the glucokinase-glucose sensor hypothesis.
Diabetes 1983 Dec
PMID:Mannose phosphorylation by glucokinase from liver and transplantable insulinoma. Cooperativity and discrimination of anomers. 631

Control of blood sugar involves the complex interaction of the pancreatic glucose-sensing beta-cells with the liver, which serves as the primary site of glucose disposal after a meal. Glucokinase occupies an important role in controlling glucose phosphorylation and metabolism both in the liver and in pancreatic islets. In the beta-cells, glucokinase functions as pacemaker of glycolysis at physiological glucose levels. It determines the unique characteristics of islet hexose usage, that is, the rate, affinity, cooperativity, and anomeric discrimination of glucose metabolism. Because glycolysis controls hexose-induced insulin release, glucokinase is considered the best-qualified candidate for the elusive glucose sensor of beta-cells. A deficiency of glucokinase would disturb glucose homeostasis. Decreased islet glucokinase would diminish islet glycolysis and would result in a higher set point of beta-cells for glucose-induced insulin release. Decreased liver glucokinase would cause less efficient hepatic glucose disposal. Human maturity-onset diabetes (type II diabetes) has these characteristics. It is thus conceivable that certain forms of type II diabetes are due to a glucokinase deficiency.
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PMID:New perspectives on pancreatic islet glucokinase. 636 28

Glucokinase is the beta-cell glucose sensor, i.e., the site in glucose metabolism that determines the glucose set-point (sensitivity) for insulin secretion. Hexokinase is also present, but it normally contributes little to glucose metabolism because of end-product inhibition by glucose 6-phosphate. There is a lowered glucose set-point for insulin secretion in 90% pancreatectomized (Px) diabetic rats. We investigated the mechanism by measuring hexokinase and glucokinase activity in islet extracts. Glucokinase activity was minimally raised in Px islets (Vmax 125% of sham-operated control rats). In contrast, hexokinase Vmax was 250% of the control value, suggesting that the increased hexokinase activity caused the beta-cell glucose hypersensitivity. Additional evidence was obtained with a 40-h fast that was performed because of a previous observation that the inhibitory effect of fasting on insulin secretion was impaired in Px rats. Glucokinase activity fell normally in the Px rats (32 +/- 4% reduction in sham vs. 37 +/- 4% in Px rats) as opposed to hexokinase activity, which was unaffected in either group. In summary, a feature of hyperglycemia is upregulated islet hexokinase activity. The result is that hexokinase assumes partial control over the glucose set-point for insulin secretion. As such, regulatory effects on insulin secretion, such as fasting, that are mediated through glucokinase activity may be altered.
Diabetes 1995 Nov
PMID:Upregulated hexokinase activity in isolated islets from diabetic 90% pancreatectomized rats. 758 32

To develop a model somatic gene therapy system for diabetes, a human hepatoma cell line (HEP G2) was transfected with a mammalian expression vector carrying the full-length human insulin cDNA. More proinsulin than insulin was released daily by the stably transformed cell line (HEP G2ins). However, on acute stimulation with 5mM 8-Br-cAMP and 10mM theophylline the HEP G2ins cells released predominantly insulin into the medium. The cells did not secrete insulin in response to glucose. Examination of acid-ethanol extracts confirmed insulin was preferentially being stored. Immunohistochemical analysis of the cells also showed (pro)insulin was being stored. Electron microscopy revealed large membrane-bound vacuoles, containing electron-dense material, which were not seen in control cells. Glucokinase activity and albumin secretion of the transfectants were unaltered from the controls. Five-minute pulse-chase labelling of the HEP G2ins cells with 3H-leucine confirmed insulin synthesis in the presence of 20mM glucose and 5mM 8-Br-cAMP. A dose-response curve for insulin synthesis was also generated to increasing concentrations of glucose with a half Vmax of 4.9mM. Our results show that the introduction of insulin cDNA into a human hepatoma cell line results in synthesis, storage and acute regulated insulin release and lend credence to the possibility of engineering a liver cell to secrete insulin acutely in response to physiological stimuli.
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PMID:Functional expression of the human insulin gene in a human hepatoma cell line (HEP G2). 761 54

Hormonal and non-hormonal regulation of glucokinase gene expression was investigsted in cultured rat islet cells. To measure glucokinase mRNA in pancreatic islet cells, the competitive PCR method was adopted. With this method, GKmRNA levels can be measured using only 0.1-1.0 microgram of total RNA isolated from cultured rat islet cells. Following 24 h preculture with 5.5 mM glucose, islet cells were cultured for 24 or 8 h with hormonal or non-hormonal factors. Glucokinase mRNA levels tended to increase, but not significantly, at 16.7 mM glucose compared to those at 5.5 mM glucose. Treatment with either 1 microM T3 or 1 microM glucagon resulted in a decrease in the glucokinase mRNA level with 16.7 mM glucose, whereas 1 microM insulin had no effect on glucokinase mRNA. Five mM dibutyryl cyclic AMP decreased the glucokinase mRNA level with 16.7 mM glucose, but cycloheximide did not block this inhibitory effect, suggesting that the effect of glucagon may be mediated by cyclic AMP and that protein synthesis is not involved in the response. Furthermore, the islet glucokinase mRNA level increased in response to 1 microM glibenclamide with 5.5 mM glucose and the response was abolished by cycloheximide, which indicates the involvement of protein synthesis in the glibenclamide-induced mRNA change. An 8-bromo-cyclic GMP (1 microM) and vanadate (1 microM) did not affect the islet GKmRNA level. These findings suggested that thyroid hormone and glucagon-cyclic AMP suppress, and glibenclamide increases the GKmRNA level in cultured rat islet cells, and that insulin, cyclic GMP and vanadate differentially affect glucokinase gene expression in pancreatic islet cells and in the liver.
Diabetes Res 1994
PMID:Regulation of glucokinase gene expression in cultured rat islet cells: the inhibitory effects of T3 and glucagon, and the stimulatory effect of glibenclamide. 766 33

Glucokinase catalyzes a rate-limiting step in glucose metabolism in hepatocytes and pancreatic beta cells and is considered the "glucose sensor" for regulation of insulin secretion. Patients with maturity-onset diabetes of the young (MODY) have heterozygous point mutations in the glucokinase gene that result in reduced enzymatic activity and decreased insulin secretion. However, it remains unclear whether abnormal liver glucose metabolism contributes to the MODY disease. Here we show that disruption of the glucokinase gene results in a phenotype similar to MODY in heterozygous mice. Reduced islet glucokinase activity causes mildly elevated fasting blood glucose levels. Hyperglycemic clamp studies reveal decreased glucose tolerance and abnormal liver glucose metabolism. These findings demonstrate a key role for glucokinase in glucose homeostasis and implicate both islets and liver in the MODY disease.
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PMID:Animal model for maturity-onset diabetes of the young generated by disruption of the mouse glucokinase gene. 766 57

Mutations of the glucokinase gene (chromosome 7p) have been shown to cause some cases of familial maturity onset diabetes of youth (MODY) but few, if any, cases of late onset familial Type 2 diabetes. A further single large pedigree with MODY has shown linkage to a marker for the adenosine deaminase gene (ADA, chromosome 20q), although the diabetes susceptibility gene at this locus has not been identified. We have studied members of 19 families with familial Type 2 diabetes (including 10 European families, 6 families from the Indian subcontinent, and 3 families of Afro-Caribbean origin), 2 of which were of MODY type (and both European), with a glucokinase marker and a marker linked to ADA, to examine whether glucokinase, or the unknown defect on chromosome 20, are implicated in diabetes in our pedigrees. Several models were constructed for standard two-point linkage analysis. Glucokinase is not the cause of diabetes in all of these families but was excluded in only one MODY family. It was possible to exclude both loci in the second MODY pedigree. No evidence was found of linkage to either marker in this multi-ethnic population under the models used. At least one further locus is involved in determining susceptibility to MODY.
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PMID:Genetic analysis of glucokinase and the chromosome 20 diabetes susceptibility locus in families with type 2 diabetes. 770 22

Because of the demonstration of a genetic linkage between glucokinase and Type II diabetes, and the central role of glucokinase on glucose metabolism, we studied glucokinase activity in the liver of patients with and without Type II diabetes. Glucokinase activity was decreased by about 50% in obese subjects with diabetes (n = 12) compared with (p < 0.01) lean controls (n = 9) and (p < 0.05) obese controls (n = 10). There was no difference between lean and obese controls. Fifty percent of subjects with diabetes had lower liver glucokinase activity than the lowest value of the controls. These data further support the important role that glucokinase plays in the pathogenesis of Type II diabetes.
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PMID:Liver glucokinase: decreased activity in patients with type II diabetes. 772 87

Pancreatic insulin secretion rates can be accurately derived by mathematical deconvolution of peripheral C-peptide concentrations either by using individual C-peptide kinetic parameters obtained by analysis of the decay curve of biosynthetic human C-peptide or by using published group parameters with appropriate adjustments for age and degree of obesity. Since the cross-reactivity of proinsulin and related peptides is low (< 10%) in many C-peptide assays, this experimental approach avoids the spurious increase in insulin immunoreactivity resulting from cross-reactivity with proinsulin and related peptides in the insulin assay. Application of this technique has demonstrated that the phenotypic expression of beta-cell dysfunction differs in subjects with different genetic mechanisms of non-insulin-dependent diabetes mellitus (NIDDM). Subjects who have maturity-onset diabetes of the young (MODY) due to mutations in the glucokinase gene demonstrate different patterns of altered insulin secretion when compared with subjects who have mutations in the MODY1 gene on chromosome 20. Glucokinase mutations affect the ability of the beta-cell to detect and respond to small increases in glucose above the basal level. However, compensatory mechanisms operative in vivo, which include a priming effect of glucose on insulin secretion, limit the severity of the observed insulin secretory defect, resulting in a generally mild clinical course in these subjects. In contrast, mutations in the MODY1 gene are associated with an inability to increase insulin secretion as the plasma glucose concentration increases above 7-8 mmol/l and the normal priming effect of glucose on insulin secretion is lost. These characteristics of the dose-response relationships between glucose and insulin secretion result in a more severe degree of hyperglycemia than observed in subjects with glucokinase mutations, and these subjects more frequently need insulin treatment. These alterations are evident in prediabetic subjects with normal glucose levels who carry the MODY1 mutation, suggesting that defective beta-cell function is the primary pathogenetic defect in the diabetic syndrome in these subjects. Studies performed in the classic form of NIDDM demonstrate that subjects with mild glucose intolerance and normal fasting glucose concentrations and glycosylated hemoglobin levels consistently demonstrate defective beta-cell function. These results are consistent with studies in the Zucker diabetic fatty rat, an animal model of NIDDM in which prediabetic animals demonstrate extensive alterations in expression of multiple genes involved in the regulation of insulin secretion. It thus appears that abnormal beta-cell function is present at a relatively early stage in the evolution of NIDDM, even before the onset of overt hyperglycemia.
Diabetes 1995 Jun
PMID:Lilly Lecture 1994. The beta-cell in diabetes: from molecular genetics to clinical research. 778 37

Maturity-onset diabetes of the young (MODY) is an autosomal dominant-subtype of noninsulin-dependent diabetes mellitus, characterized by an early age of onset. MODY is considered a model for genetic studies of noninsulin-dependent diabetes mellitus because of the availability of large multigenerational families, which make linkage analyses possible. So far, two MODY susceptibility loci have been reported, one unknown gene on chromosome 20q, and glucokinase on chromosome 7q. Glucokinase mutations appear to be the most common cause of MODY in the European population, being found in 60% of the families investigated. This form of diabetes results from a primary defect in insulin secretion due to the reduced enzymatic activity of the mutant glucokinase. The search for a third MODY gene will provide a better understanding of diabetes in childhood.
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PMID:Maturity-onset diabetes of the young. 795 73


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