A pancreatic islet-specific glucose-6-phosphatase-related protein (IGRP) was cloned using a subtractive cDNA expression cloning procedure from mouse insulinoma tissue. Two alternatively spliced variants that differed by the presence or absence of a 118-bp exon (exon IV) were detected in normal balb/c mice, diabetic ob/ob mice, and insulinoma tissue. The longer, 1901-bp full-length cDNA encoded a 355-amino acid protein (molecular weight 40,684) structurally related (50% overall identity) to the liver glucose-6-phosphatase and exhibited similar predicted transmembrane topology, conservation of catalytically important residues, and the presence of an endoplasmic reticulum retention signal. The shorter transcript encoded two possible open reading frames (ORFs), neither of which possessed His174, a residue thought to be the phosphoryl acceptor (Pan CJ, Lei KJ, Annabi B, Hemrika W, Chou JY: Transmembrane topology of glucose-6-phosphatase. J Biol Chem 273:6144-6148, 1998). Northern blot and reverse transcription-polymerase chain reaction analysis showed that the mRNA was highly expressed in pancreatic islets and expressed more in beta-cell lines than in an alpha-cell line. It was notably absent in tissues and cell lines of non-islet neuroendocrine origin, and no other major tissue source of the mRNA was found. During development, it was expressed in parallel with insulin mRNA. The mRNA was efficiently translated and glycosylated in an in vitro translation/membrane translocation system and readily transcribed into COS 1, HIT, and CHO cells using cytomegalovirus or Rous sarcoma virus promoters. Whereas the liver glucose-6-phosphatase showed activity in these transfection systems, the IGRP failed to show glucose phosphotransferase or phosphatase activity with p-nitrophenol phosphate, inorganic pyrophosphate, or a range of sugar phosphates hydrolyzed by the liver enzyme. While the metabolic function of the enzyme is not resolved, its remarkable tissue-specific expression warrants further investigation, as does its transcriptional regulation in conditions where glucose responsiveness of the pancreatic islet is altered.
Glucose-6-phosphatase (G6Pase) catalyzes the final step in the gluconeogenic and glycogenolytic pathways, the hydrolysis of glucose-6-phosphate (G6P) to glucose and phosphate. This paper describes the identification and characterization of a human cDNA and gene encoding a ubiquitously expressed G6Pase catalytic subunit-related protein (UGRP). The ORF of this UGRP cDNA encodes a protein (346 amino acids (aa); M r 38 709) which shares 36% overall identity to the human G6Pase catalytic subunit (357 aa; M r 40 487). UGRP exhibits a similar predicted transmembrane topology and conservation of many of the catalytically important residues with the G6Pase catalytic subunit; however, unlike the G6Pase catalytic subunit, UGRP does not catalyze G6P hydrolysis. UGRP mRNA was detected by RNA blot analysis in every tissue examined with the highest expression in muscle. Database analysis showed that the human UGRP gene is composed of six exons, spans ∼5·4 kbp of genomic DNA and is located on chromosome 17q21 with the G6Pase catalytic subunit gene. The UGRP gene transcription start sites were mapped by primer extension analysis, and the activity of the UGRP gene promoter was analyzed using luciferase fusion gene constructs. In contrast to the G6Pase catalytic subunit gene promoter, the UGRP promoter was highly active in all cell lines examined.
Because overexpression of the glucose-6-phosphatase catalytic subunit (G-6-Pase) in both type 1 and type 2 diabetes may contribute to the characteristic increased rate of hepatic glucose production, we have investigated whether the insulin response unit (IRU) identified in the mouse G-6-Pase promoter is conserved in the human promoter. A series of human G-6-Pase-chloramphenicol acetyltransferase (CAT) fusion genes was transiently transfected into human HepG2 hepatoma cells, and the effect of insulin on basal CAT expression was analyzed. The results suggest that the IRU identified in the mouse promoter is conserved in the human promoter, but that an upstream multimerized insulin response sequence (IRS) motif that is only found in the human promoter appears to be functionally inactive. The G-6-Pase IRU comprises two distinct promoter regions, designated A and B. Region B contains an IRS, whereas region A acts as an accessory element to enhance the effect of insulin, mediated through region B, on basal G-6-Pase gene transcription. We have previously shown that the accessory factor binding region A is hepatocyte nuclear factor-1, and we show here that the forkhead protein FKHR is a candidate for the insulin-responsive transcription factor binding region B.
Protein synthesis in mammalian cells is regulated through alterations in the states of phosphorylation of initiation and elongation factors (eIF's and eEF's), and of other regulatory proteins. This modulates their activities or their abilities to interact with one another. Insulin activates a number of these proteins including the guanine nucleotide-exchange factor eIF2B; the eIF4F complex, which (through eIF4E) interacts with the cap of the mRNA; p70 S6 kinase and elongation factor eEF2, which mediates the translation step of elongation. Control of the last three of these is linked to mTOR. In CHO cells, regulation of all these proteins by insulin is modulated by the presence of amino acids and/or glucose in the medium. For example, p70 S6 kinase activity declines in the absence of amino acids and cannot be stimulated by insulin under this condition. Readdition of amino acids, especially leucine, restores activity and insulin-sensitivity. In the case of eIF2B and eEF2, both amino acids and glucose must be provided in order for insulin to regulate their activities. In contrast, insulin-stirnulation of the formation of eIF4F complexes requires glucose, but not amino acids. Glucose metabolism is required for this permissive effect.Provision of substrates to mammalian tissues requires constant adaptations of metabolism to the quality and quantity of nutrients. Although it is well known that insulin has an important role in hepatic adaptations at the gene level, the molecular mechanisms involved are poorly understood. Recent findings have pointed to SREBP-lc (Sterol Regulatory Element Binding Protein -1c) as the transcription factor involved in insulin action. We have shown that SREBP-lc expression and nuclear abundance is positively regulated by insulin through a mechanism involving PL-kinase, and negatively by glucagon. Adenovirus-mediated ovcrexprcssion of a transcriptionally active form of SREBP-I c in cultured rat hepatocytes mimicks the inductive effects of insulin on glycolytic and lipogenic gene expression. A dominant negative form of SREBP-lc has the opposite effects. SREBP-lc mimicks also the negative effect of insulin since it is able to down-regulate the expression and the promoter activity of phosphoenolpyruvate carboxykinase in cultured hepatocytes. Injection of an adenovirus containing the active form of SREBP-lc to diabetic mice induces a rapid decrease of their hyperglycaemia and the predicted changes in hepatic gene expression. These studies point out to SREBP-lc as an important actor in the long term regulation of glucose homeostasis. ~1 7Insulin-Regulated Gene Expression.
Glucose-6-phosphatase (G6Pase) catalyzes the final step in the gluconeogenic and glycogenolytic pathways, the hydrolysis of glucose-6-phosphate (G6P) to glucose and phosphate. This paper describes the identification and characterization of a cDNA and the gene encoding the mouse ubiquitously expressed G6Pase catalytic subunit-related protein (UGRP). The open reading frame of this UGRP cDNA encodes a protein (346 amino acids (aa); M r 38 755) that shares 36% overall identity (56% similarity) with the mouse G6Pase catalytic subunit (357 aa; M r 40 454). UGRP exhibits a similar predicted transmembrane topology and conservation of many of the catalytically important residues with the G6Pase catalytic subunit; however, unlike the G6Pase catalytic subunit, UGRP does not catalyze G6P hydrolysis and does not contain a carboxy-terminal di-lysine endoplasmic reticulum retention signal. UGRP mRNA was detected by RNA blot analysis in every mouse tissue examined with the highest expression in heart, brain, testis and kidney. Database analysis showed that the mouse UGRP gene is composed of six exons, spans ∼4·2 kbp of genomic DNA and is located on chromosome 11 along with the G6Pase catalytic subunit gene. The UGRP gene transcription start sites were mapped by primer extension analysis, and the activity of the mouse UGRP gene promoter was analyzed using luciferase fusion gene constructs. In contrast to the G6Pase catalytic subunit gene promoter, the UGRP promoter was highly active in all cell lines examined.
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