Ablation of ARNT/HIF1β in Liver Alters Gluconeogenesis, Lipogenic Gene Expression, and Serum Ketones

Wang, Xiaohui L.; Suzuki, Ritsuro; Lee, Kevin; Tran, Thien; Gunton, Jenny E.; Saha, Asish K.; Patti, Mary‐Elizabeth; Goldfine, Allison B.; Ruderman, Neil B.; Gonzalez, Frank J.; Kahn, C. Ronald

doi:10.1016/j.cmet.2009.05.002

Cited by 15 publications

(16 citation statements)

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“…These data are corroborated in mice where it was demonstrated that ARNT suppression severely impairs the insulin release in response to glucose, as well as other features resembling those observed in diabetic humans (Gunton et al, 2005;Wang et al, 2009). Is ARNT deficiency a cause or a consequence of the pathological changes of diabetes?…”

Section: Arnt As a Modulator Of Er Activitysupporting

confidence: 80%

AhR and ARNT modulate ER signaling

2010

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Section: Arnt As a Modulator Of Er Activitysupporting

confidence: 80%

AhR and ARNT modulate ER signaling

2010

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“…A key question is whether this is related to regulation of HIF function, or to altered activity of other putative FIH targets. Loss of VHL in hepatocytes results in a severe HIF-dependent steatosis, and deletion of HIF-1β in liver results in increased hepatic gluconeogenesis and lipogenic gene expression but reduced hepatic lipid storage (Rankin et al, 2009; Wang et al, 2009). These data indicate that HIF activation increases steatosis in the liver.…”

Section: Discussionmentioning

confidence: 99%

The Asparaginyl Hydroxylase Factor Inhibiting HIF-1α Is an Essential Regulator of Metabolism

et al. 2010

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SUMMARY Factor Inhibiting HIF-1α (FIH) is an asparaginal hydroxylase. Hydroxylation of HIF-α proteins by FIH blocks association of HIFs with the transcriptional co-activators CBP/p300, thus inhibiting transcriptional activation. We have created mice with a null mutation in the FIH gene, and found that it has little or no discernable role in mice in altering classical aspects of HIF function, e.g., angiogenesis, erythropoiesis, or development. Rather, it is an essential regulator of metabolism: mice lacking FIH exhibit reduced body weight, elevated metabolic rate, hyperventilation, improved glucose and lipid homeostasis, and are resistant to high fat diet-induced weight gain and hepatic steatosis. Neuron-specific loss of FIH phenocopied some of the major metabolic phenotypes of the global null animals: those mice have reduced body weight, increased metabolic rate, enhanced insulin sensitivity, and are also protected against high fat diet-induced weight gain. These results demonstrate that FIH acts to a significant degree through the nervous system to regulate metabolism.

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“…Further, HIFs regulate major metabolic liver functions, and in particular studies in which either ARNT or the two HIFα subunits were deleted supported this. Liver-specific ablation of the common beta HIF subunit (ARNT) in mice increased fed insulin levels, gluconeogenesis, lipogenesis, and decreased ketone bodies [45]. Deletion of HIF-1α was shown to impair gluconeogenesis during liver regeneration [46] whereas HIF-2α was crucial for hepatic insulin signaling [47] and accordingly its constitutive activation in mouse liver resulted in development of severe hepatic steatosis associated with impaired fatty acid beta-oxidation, decreased lipogenic gene expression, and increased lipid storage capacity [48].…”

Section: Hypoxia-inducible Transcription Factors (Hifs)mentioning

confidence: 99%

Metabolic zonation of the liver: The oxygen gradient revisited

2017

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The liver has a multitude of functions which are necessary to maintain whole body homeostasis. This requires that various metabolic pathways can run in parallel in the most efficient manner and that futile cycles are kept to a minimum. To a large extent this is achieved due to a functional specialization of the liver parenchyma known as metabolic zonation which is often lost in liver diseases. Although this phenomenon is known for about 40 years, the underlying regulatory pathways are not yet fully elucidated. The physiologically occurring oxygen gradient was considered to be crucial for the appearance of zonation; however, a number of reports during the last decade indicating that β-catenin signaling, and the hedgehog (Hh) pathway contribute to metabolic zonation may have shifted this view. In the current review we connect these new observations with the concept that the oxygen gradient within the liver acinus is a regulator of zonation. This is underlined by a number of facts showing that the β-catenin and the Hh pathway can be modulated by the hypoxia signaling system and the hypoxia-inducible transcription factors (HIFs). Altogether, we provide a view by which the dynamic interplay between all these pathways can drive liver zonation and thus contribute to its physiological function.

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Ablation of ARNT/HIF1β in Liver Alters Gluconeogenesis, Lipogenic Gene Expression, and Serum Ketones

Cited by 15 publications

References 0 publications

AhR and ARNT modulate ER signaling

AhR and ARNT modulate ER signaling

The Asparaginyl Hydroxylase Factor Inhibiting HIF-1α Is an Essential Regulator of Metabolism

Metabolic zonation of the liver: The oxygen gradient revisited

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