Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01275 (glucagon)
 26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Glucose can modulate the transcription of many genes, particularly those encoding enzymes of liver metabolism. The transcriptional effect of glucose can be indirect, being mediated in vivo by hormonal variations, especially increase in insulin and decrease in glucagon secretion. Whereas the transcription of the glucokinase gene, for example, is stimulated by insulin without the aid of glucose, the transcriptional activation of most glycolytic and lipogenic genes in hepatocytes requires the presence of both glucose and insulin. The role of insulin in the activation of these genes seems mainly to stimulate glucokinase synthesis, and thus to permit glucose phosphorylation. In some cells in which hexokinase activity is constitutive, the glucose-dependent activation of the same genes does not require insulin and, in addition, can be produced by the nonmetabolisable analog, 2-deoxyglucose. In hepatocytes, the insulin effect on the glucose-dependent activation of the L-pyruvate kinase gene can be reproduced by fructose at low concentrations. Fructose probably acts through the fructose 1-phosphate dependent deinhibition of glucokinase activity. A glucose/carbohydrate element has been identified on the L-type pyruvate kinase and spot 14 gene promoters. It is able to bind, in vitro, transcriptional factors of the MLTF/USF family and could act in cooperation with tissue-specific contiguous elements, such as the HNF4 binding site in the L-type pyruvate kinase gene.
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PMID:Transcriptional control of metabolic regulation genes by carbohydrates. 829 88

The functional role of the different sites binding transcriptional factors on the tissue-specific, glucose-responsive promoter of the L type pyruvate kinase gene (L-PK) has been investigated in transgenic mice. These sites are able to bind, from 3' to 5', HNF1, NF1, HNF4, and MLTF/USF, respectively. We have compared the level of chloramphenicol acetyltransferase reporter transgene expression when driven by a L-PK promoter fragment of either -96 base pairs (bp) (containing only the HNF1 binding site) or -150 bp (lacking the MLTF/USF binding site) or driven by a -183-bp L-PK promoter fragment with or without the NF1 binding site. Our results demonstrate that: 1) HNF1 alone is not sufficient to promote an efficient L-PK gene transcription in vivo; 2) with only binding sites for HNF1, NF1, and HNF4, though the tissue-specific pattern of expression is respected, the level of the gene transcription is low and the hormonal control is lost; 3) the MLTF/USF binding site is the target of the hormonal control, required for both positive response to carbohydrates and negative response to glucagon; 4) the role of NF1 in the promoter activity could be to negatively modulate the L-PK gene expression in the different tissues, without interfering with the glucose and hormone responsiveness.
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PMID:Exploration of a liver-specific, glucose/insulin-responsive promoter in transgenic mice. 831 45

Nondiabetic subjects with the Q268X mutation in the hepatocyte nuclear factor (HNF)-4alpha/MODY1 gene have impaired glucose-induced insulin secretion. To ascertain the effects of the nonglucose secretagogue arginine on insulin and glucagon secretion in these subjects, we studied 18 members of the RW pedigree: 7 nondiabetic mutation negative (ND[-]), 7 nondiabetic mutation positive (ND[+]), and 4 diabetic mutation positive (D[+]). We gave arginine as a 5-g bolus, followed by a 25-min infusion at basal glucose concentrations, and after glucose infusion to clamp plasma glucose at approximately 200 mg/dl. The acute insulin response (AIR), the 10-60 min insulin area under the curve (AUC), and the insulin secretion rate (ISR) were compared, as were the acute glucagon response (AGR) and glucagon AUC. The ND[+] and D[+] groups had decreased insulin AUC and ISR and decreased glucose potentiation of AIR, insulin AUC, and ISR to arginine administration when compared with the ND[-] group. At basal glucose concentrations, glucagon AUC was greatest for the ND[-] group, intermediate for the ND[+] group, and lowest for the D[+] group. During the hyperglycemic clamp, there was decreased suppression of glucagon AUC for both ND[+] and D[+] groups compared with the ND[-] group. The decreased ISR to arginine in the ND[+] group compared with the ND[-] group, magnified by glucose potentiation, indicated that HNF-4alpha affects the signaling pathway for arginine-induced insulin secretion. The decrease in glucagon AUC and decreased suppression of glucagon AUC with hyperglycemia suggest that mutations in HNF-4alpha may lead to alpha-cell as well as beta-cell secretory defects or a reduction in pancreatic islet mass.
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PMID:Diminished insulin and glucagon secretory responses to arginine in nondiabetic subjects with a mutation in the hepatocyte nuclear factor-4alpha/MODY1 gene. 935 21

The aim of this study is to understand better the genetic causes of type II diabetes and the phenotypic consequences of the genetic changes. We first investigated the relative prevalence of the different forms of diabetes in young adults and their clinical features. 51 non-obese patients were identified in whom diabetes had been diagnosed before age 40; cases of typical insulin-dependent type I diabetes were excluded. A search for mutations of the glucokinase and HNF-1 alpha genes and for mitochondrial DNA was made, anti-islet and anti-GAD antibodies were determined and HLA class II genotyping was performed. Patients were subdivided on clinical grounds into a MODY (maturity onset diabetes of the young) group (n = 19) and a non-MODY group (n = 32). MODY is a form of diabetes which has an autosomal dominant inheritance for which 3 genes have already been implicated (MODY1, HNF-4 gene; MODY2, glucokinase gene, and MODY3, HNF-1 alpha gene). In the MODY group we identified 3 patients with MODY2, 1 with MODY3, 1 with the 3243 mitochondrial mutation and a further patient with autoimmune diabetes. In the non-MODY group we found 5 patients with autoimmune diabetes and 1 with MODY2. No clinical parameter was helpful in classifying patients in one of these subclasses of diabetes; however, glucagon stimulated C-peptide was useful in discriminating between MODY2 patients and the others. Young and lean non-insulin-dependent diabetic patients thus constitute a very heterogeneous group, though presenting similar clinical features. In the second study we analyzed hepatic glucose metabolism in patients with a mutation of the glucokinase gene expressed in both liver and islet beta cells. We found that endogenous glucose production is inadequately inhibited by hyperglycemia, a fact which contributes to the pathogenesis of hyperglycemia in these patients.
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PMID:[Swiss journey through the clinical and genetic characteristics of diabetes in young patients]. 952 22

Glucose, that Claude Bernard has demonstrated in 1850 to be synthesized and secreted by the liver, is an important regulator of gene transcription in all types of organisms. In vertebrates, it especially regulates transcription of metabolic genes in the liver and fat tissue, activating genes encoding enzymes and regulators of the glycolytic and lipogenic pathways. Working with the L-type pyruvate kinase gene we have found that in hepatocytes glucose-dependent gene regulation requires: Presence of the GLUT2 glucose transporter, necessary to allow for an effective depletion in glucose 6-phosphate (G-6P) under gluconeogenic conditions. Phosphorylation of glucose to G-6P assured either by insulin-dependent glucokinase or by another hexokinase isoform. Most likely, entry of G-6P in the pentose phosphate pathway. Modulation of a kinase/phosphatase cascade, in particular inhibition of the 5'AMP-activated protein kinase. Signalling through a glucose response complex assembled onto a glucose-response element (GIRE) located in regulatory regions of glucose-responsive genes. The activators USF belong to the complex, and are required for a normal gene activation by glucose, as evidenced from the phenotype of knock-out mice deficient in USF. The study of USF-defective knock-out mice suggest that USF could be involved in nutritional activation of a whole class of genes regulated by glucose, and not by insulin itself. In particular, lipogenic genes and the ob gene, encoding the leptin satiety hormone, are abnormally responsive to diet in USF-/- mice. The transactivation potential of USF would be modulated by a glucose sensor system implying the COUP-TFII transcription inhibitor. The main role of insulin in the glucose response of genes like the L-PK gene is to induce the glucokinase gene. Glucagon, through cyclic AMP, inhibits L-PK gene transcription mainly through activation of PKA. The PKA catalytic subunit could act by phosphorylating member(s) of the glucose-response complex, or of contiguous transcription factor, e.g. HNF4. In conclusion, through a pluridisciplinary approach ranging from Claude Bernard-derived biology to modern molecular biology, important progress have been made during the last years on the mechanisms of the regulation of gene transcription by glucose in vertebrates.
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PMID:[From the glycogenic function of the liver to gene regulation by glucose]. 987 95

The glycolytic enzyme, L-pyruvate kinase (L-PK), plays an important role in hepatic glucose metabolism. Insulin and glucose induce L-PK gene expression, while glucagon and polyunsaturated fatty acids (PUFA) inhibit L-PK gene expression. We have been interested in defining the PUFA regulation of L-PK. The cis-regulatory target for PUFA action includes an imperfect direct repeat (DR1) that binds HNF-4. HNF4 plays an ancillary role in the insulin/glucose-mediated transactivation of the L-PK gene. Because the fatty acid-activated nuclear receptor, peroxisome proliferator-activated receptor (PPARalpha), binds DR1-like elements and has been reported to interfere with HNF4 action, we examined the role PPARalpha plays in the regulation of L-PK gene transcription. Feeding rats either fish oil or the potent PPARalpha activator, WY14,643, suppressed rat hepatic L-PK mRNA and gene transcription. The PPARalpha-null mouse was used to evaluate the role of the PPARalpha in hepatic transcriptional control of L-PK. While WY14,643 control of L-PK gene expression required the PPARalpha, PUFA regulation of L-PK gene expression was independent of the PPARalpha. Transfection studies in cultured primary hepatocytes localized the cis-regulatory target for WY14,643/PPARalpha action to the L-PK HNF4 binding site. However, PPARalpha/RXRalpha heterodimers did not bind this region. Although both WY14,643 and PUFA suppress L-PK gene transcription through the same element, PUFA regulation of L-PK does not require the PPARalpha and PPARalpha/RXRalpha does not bind the L-PK promoter. These studies suggest that other intermediary factors are involved in both the PUFA and PPARalpha regulation of L-PK gene transcription.
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PMID:Evidence against the peroxisome proliferator-activated receptor alpha (PPARalpha) as the mediator for polyunsaturated fatty acid suppression of hepatic L-pyruvate kinase gene transcription. 1078 35

Subjects with the Q268X mutation in the hepatocyte nuclear factor (HNF)-4alpha gene (RW pedigree/maturity-onset diabetes of the young [MODY]-1) have diminished insulin and glucagon secretory responses to arginine. To determine if pancreatic polypeptide (PP) secretion is likewise involved, we studied PP responses to insulin-induced hypoglycemia in 17 RW pedigree members: 6 nondiabetic mutation-negative [ND(-)], 4 nondiabetic mutation-positive [ND(+)], and 7 diabetic mutation-positive [D(+)]. Subjects received 0.08 U/kg body wt human regular insulin as an intravenous bolus to produce moderate self-limited hypoglycemia. PP areas under the curve (PP-AUCs) were compared among groups. With hypoglycemia, the PP-AUC was lower in the D(+) group (14,907 +/- 6,444 pg/ml, P = 0.03) and the ND(+) group (14,622 +/- 6,015 pg/ml, P = 0.04) compared with the ND(-) group (21,120 +/- 4,158 pg/ml). In addition, to determine if the beta-cell secretory defect in response to arginine involves amylin in addition to insulin secretion, we analyzed samples from 17 previously studied RW pedigree subjects. We compared the AUCs during arginine infusions for the 3 groups both at euglycemia and hyperglycemia as well as their C-peptide-to-amylin ratios. The D(+) and ND(+) groups had decreased amylin AUCs during both arginine infusions compared with the ND(-) group, but had similar C-peptide-to-amylin ratios. These results suggest that the HNF-4alpha mutation in the RW/MODY1 pedigree confers a generalized defect in islet cell function involving PP cells in addition to beta- and alpha-cells, and beta-cell impairment involving proportional deficits in insulin and amylin secretion.
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PMID:Reduced pancreatic polypeptide response to hypoglycemia and amylin response to arginine in subjects with a mutation in the HNF-4alpha/MODY1 gene. 1086 48

A 400-bp intronic enhancer fragment in conjunction with the proximal promoter of the aldolase B gene provided correct tissue-specific expression in transgenic mice together with hormonal regulation in the liver. We investigated in vivo and in cultured cells the contribution of the intronic regulatory sequences and their interaction with the promoter elements in controlling aldolase B gene expression. Transgene activity was completely abolished by disruption of the two hepatocyte nuclear factor 1 (HNF1) binding sites in the enhancer, whereas mutation of one HNF1 site had no effect in the liver but strongly decreased activity in the kidney. Our data show that the HNF1 binding site(s) in the enhancer were key regulators of aldolase B transgene expression both in the liver and kidney. Deletion of the CCAAT/enhancer-binding protein site in the promoter completely abolished the enhancer function in HepG2 cells. These results suggest that expression of the aldolase B gene in the liver requires cooperative interactions between CCAAT/enhancer-binding protein and HNF1. Deletion of the HNF4 binding site in the enhancer suppressed expression in both liver and kidney in half of the transgenic lines, suggesting that this element might play a role in chromatin opening at the insertion site. We firmly establish that the endogenous aldolase B gene's first response to glucagon or cyclic AMP exposure was a transient increase in the expression in the liver, followed by a secondary decline in the transcription, as previously reported. This response was reproduced by all transgenes studied, indicating that neither HNF1 nor HNF4 binding sites in the enhancer were involved in this biphasic cyclic AMP response.
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PMID:In vivo functional characterization of the aldolase B gene enhancer. 1203 48

Liver carnitine palmitoyltransferase I catalyzes the transfer of long-chain fatty acids into mitochondria. L-CPT I is considered the rate-controlling enzyme in fatty acid oxidation. Expression of the L-CPT I gene is induced by starvation in response to glucagon secretion from the pancreas, an effect mediated by cAMP. Here, the molecular mechanisms underlying the induction of L-CPT I gene expression by cAMP were characterized. We demonstrate that the cAMP response unit of the L-CPT I gene is composed of a cAMP-response element motif and a DR1 sequence located 3 kb upstream of the transcription start site. Our data strongly suggest that the coactivator PGC-1 is involved in the regulation of this gene expression by cAMP in combination with HNF4 alpha and cAMP-response element-binding protein (CREB). Indeed, (i) cotransfection of CREB or HNF4 alpha dominant negative mutants completely abolishes the effect of cAMP on the L-CPT I promoter, and (ii) the cAMP-responsive unit binds HNF4 alpha and CREB through the DR1 and the cAMP-response element sequences, respectively. Moreover, cotransfection of PGC-1 strongly activates the L-CPT I promoter through HNF4 alpha bound at the DR1 element. Finally, we show that the transcriptional induction of the PGC-1 gene by glucagon through cAMP in hepatocytes precedes that of L-CPT-1. In addition to the key role that PGC-1 plays in glucose homeostasis, it may also be critical for lipid homeostasis. Taken together these observations suggest that PGC-1 acts to coordinate the process of metabolic adaptation in the liver.
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PMID:The coactivator PGC-1 is involved in the regulation of the liver carnitine palmitoyltransferase I gene expression by cAMP in combination with HNF4 alpha and cAMP-response element-binding protein (CREB). 1210 81

Small hepatocytes (SHs), which are known to be hepatic progenitor cells, were isolated from an adult rat liver. SHs in a colony sometimes change their shape from small to large and from flat to rising/piled-up. The aim of the present study is to clarify whether the alteration of cell shape is correlated with the maturation of SHs and whether extracellular matrix (ECM) can induce the morphological changes of SHs. We used liver-enriched transcription factors (LETFs) such as hepatocyte nuclear factor (HNF) 4 alpha, HNF6, CCAAT/enhancer binding proteins (C/EBP) alpha, and C/EBP beta, tryptophan 2,3-dioxygenase (TO), and serine dehydratase (SDH) as markers of hepatic maturation. To enrich the number of SH colonies, the colonies were isolated from dishes and replated. Replated colonies proliferated and the average number of cells per colony was about five times larger at day 9 than at day 1. When the cells were treated with laminin, type IV collagen, a mixture of laminin and type IV collagen, Matrigel or collagen gel (CG), only the cells treated with Matrigel dramatically changed their shape within several days and had reduced growth activity, whereas the cells treated with other ECM did not. HNF4 alpha, HNF6, C/EBP alpha, C/EBP beta, and TO were well expressed in the cells treated with Matrigel. Furthermore, addition of both glucagon and dexamethasone dramatically induced the expression of SDH mRNA and protein in the cells treated with Matrigel. In conclusion, morphological changes of SHs may be correlated with hepatic maturation and basement membrane (BM)-like structure may induce the morphological changes of SHs.
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PMID:Morphological changes induced by extracellular matrix are correlated with maturation of rat small hepatocytes. 1221 Jul 18


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