Insulin Regulation of PEPCK Gene Expression: A Model for Rapid and Reversible Modulation

Quinn, Patrick G.; Yeagley, David

doi:10.2174/156800805774912962

Cited by 104 publications

(77 citation statements)

References 170 publications

(337 reference statements)

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“…We found that hepatic FOXQ1 is regulated by fasting and pathophysiological status (insulin resistance and diabetes). In the fasted state insulin levels drop while secretion of glucagon and glucocorticoids increase, resulting in increased hepatic gluconeogenesis [3,36]. Our data indicates that glucocorticoids, rather than glucagon or insulin, regulate the expression of FOXQ1.…”

Section: Discussionmentioning

confidence: 73%

The hepatic FOXQ1 transcription factor regulates glucose metabolism in mice

et al. 2016

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Aim/hypothesis Hepatic forkhead box q1 (FOXQ1) expression levels are regulated by nutritional and pathophysiological status. In this study we investigated the role of FOXQ1 in the regulation of hepatic gluconeogenesis. Methods We used multiple mouse and cell models to study the role of FOXQ1 in regulating expression of gluconeogenic genes, and cellular and hepatic glucose production. Results Expression of hepatic FOXQ1 was regulated by fasting in normal mice and was dysregulated in diabetic mice. Overexpression of FOXQ1 in primary hepatocytes inhibited expression of gluconeogenic genes and decreased cellular glucose output. Hepatic FOXQ1 rescue in db/db and high-fat diet-induced obese mice markedly decreased blood glucose level and improved glucose intolerance. In contrast, wildtype C57 mice with hepatic FOXQ1 deficiency displayed increased blood glucose levels and impaired glucose tolerance. Interestingly, studies into molecular mechanisms indicated that FOXQ1 interacts with FOXO1, thereby blocking FOXO1 activity on hepatic gluconeogenesis, preventing it from directly binding to insulin response elements mapped in the promoter region of gluconeogenic genes. Conclusions/interpretation FOXQ1 is a novel factor involved in regulating hepatic gluconeogenesis, and the decreased FOXQ1 expression in liver may contribute to the development of type 2 diabetes.

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Section: Discussionmentioning

confidence: 73%

The hepatic FOXQ1 transcription factor regulates glucose metabolism in mice

et al. 2016

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“…Indeed, after glucose injection, no insulin production could be detected in blood serum. Notably, these reduced circulatory insulin levels will also contribute to the increased expression of gluconeogenic enzymes, as the negative influence of insulin normally dominates over the positive effects of cyclic AMP and GCs (78). This indicates that SPRET/Ei mice display impaired glucose-stimulated insulin synthesis and/or secretion.…”

Section: Discussionmentioning

confidence: 99%

Increased Glucocorticoid Receptor Expression and Activity Mediate the LPS Resistance of SPRET/EI Mice

Dejager

Pinheiro

Puimège

et al. 2010

Journal of Biological Chemistry

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SPRET/Ei mice are extremely resistant to acute LPS-induced lethal inflammation when compared with C57BL/6. We found that in vivo SPRET/Ei mice exhibit strongly reduced expression levels of cytokines and chemokines. To investigate the role of the potent anti-inflammatory glucocorticoid receptor (GR) in the SPRET/Ei phenotype, mice were treated with the GR antagonist RU486 or bilateral adrenalectomy. Under such conditions, both C57BL/6 and SPRET/Ei mice were strongly sensitized to LPS, and the differences in LPS response between SPRET/Ei and C57BL/6 mice were completely gone. These results underscore the central role of GR in the LPS hyporesponsiveness of SPRET/Ei mice. Compared with C57BL/ 6, SPRET/Ei mice were found to express higher GR levels, which were reflected in increased GR transactivation. Using a backcross mapping strategy, we demonstrate that the high GR transcription levels are linked to the Nr3c1 (GR) locus on chromosome 18 itself. Unexpectedly, SPRET/Ei mice exhibit a basal overactivation of the hypothalamic-pituitary-adrenal axis, namely strongly increased corticosterone levels, ACTH levels, and adrenocortical size. As a consequence of the excess of circulating glucocorticoids (GCs), levels of hepatic gluconeogenic enzymes are increased, and insulin secretion from pancreatic ␤-cells is impaired, both of which result in hyperglycemia and glucose intolerance in SPRET/Ei mice. We conclude that SPRET/Ei mice are unique as they display an unusual combination of elevated GR expression and increased endogenous GC levels. Hence, these mice provide a new and powerful tool for the study of GR-and GC-mediated mechanisms, including immune repressive functions, neuroendocrine regulation, insulin secretion, and carbohydrate metabolism.The Mus spretus species has been used to establish several inbred strains, including SPRET/Ei, SEG/Pas, and STF/Pas. M. spretus or Algerian mice and the Mus musculus or house mice diverged about 1.5 million years ago, which results in a great amount of genetic polymorphisms present in the genome of these wild-derived inbred strains compared with the common laboratory M. musculus strains. The ability to produce interspecific crosses and backcrosses between M. spretus and M. musculus, despite their evolutionary divergence (1) and the high degree of sequence variation between them, allows accurate genetic mapping of complex traits (2). Furthermore, due to their high sequence variation, M. spretus strains provide a great amount of additional phenotypic variation (3). As an example, when compared with the standard laboratory mouse strain C57BL/6, SPRET/Ei mice exhibit a strong and dominant resistance against the lethal effects of several inflammatory mediators, such as lipopolysaccharide (LPS) and TNF (4, 5). Both can induce an exaggerated inflammatory response mediated partly by the activation of potent transcription factors such as NFB and AP1. The LPS-induced response is called endotoxemia, which is a commonly used model for studying sepsis.

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“…PEPCK is a rate-limiting enzyme of gluconeogenesis in the liver. Its gene expression is controlled at the transcriptional level and is induced by glucagon and glucocorticoids and inhibited by insulin (37)(38)(39). Earlier studies led to the assumption that gluconeogenesis is an essential metabolic pathway in the rabbit blastocyst (15).…”

Section: Fig 7 Ir and Igf-ir Expression In Rabbit Blastocysts Cultumentioning

confidence: 99%

Maternal Diabetes Impairs Gastrulation and Insulin and IGF-I Receptor Expression in Rabbit Blastocysts

et al. 2010

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Women with type 1 diabetes are subfertile. Diabetes negatively affects pregnancy by causing early miscarriage and poor prenatal outcomes. In this study we examine consequences of maternal type 1 diabetes on early embryo development, metabolic gene expression, and the pattern of insulin receptor (IR) and IGF-I receptor (IGF-IR) distribution in rabbit blastocysts. In female rabbits, type 1 diabetes was induced by alloxan treatment. Six-day-old blastocysts were recovered and assessed for receptor distribution and metabolic gene expression. In vitro culture of blastocysts was performed in medium containing 1 mM, 10 mM, or 25 mM glucose, simulating normo-and hyperglycemic developmental condition in vitro. The fertility rate of the diabetic rabbits clearly mirrored subfertility with a drop in blastocyst numbers by 40% (13.3 blastocysts in diabetic vs. 21.9 in control females). In blastocysts onset and progression of gastrulation was delayed and expression of IR and IGF-IR and their metabolic target genes (hexokinase, phosphoenolpyruvate carboxykinase), both in vivo and in vitro, was down-regulated. The amount of apoptotic cells in the embryonic disc was increased, correlating closely with the reduced transcription of the bcl-x(L) gene. Blastocyst development is clearly impaired by type 1 diabetes during early pregnancy. Insulin-stimulated metabolic genes and IR and IGF-IR are down-regulated, resulting in reduced insulin and IGF sensitivity and a delay in development. Dysregulation of the IGF system and embryonic glucose metabolism are potential reasons for diabetogenous subfertility and embryopathies and start as soon as during the first days of life. (Endocrinology 151: 4158 -4167, 2010)

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Insulin Regulation of PEPCK Gene Expression: A Model for Rapid and Reversible Modulation

Cited by 104 publications

References 170 publications

The hepatic FOXQ1 transcription factor regulates glucose metabolism in mice

The hepatic FOXQ1 transcription factor regulates glucose metabolism in mice

Increased Glucocorticoid Receptor Expression and Activity Mediate the LPS Resistance of SPRET/EI Mice

Maternal Diabetes Impairs Gastrulation and Insulin and IGF-I Receptor Expression in Rabbit Blastocysts

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