Paul M. Titchenell scite author profile

SUMMARY Impaired insulin-mediated suppression of hepatic glucose production (HGP) plays a major role in the pathogenesis of type 2 diabetes (T2D), yet the molecular mechanism by which this occurs remains unknown. Using a novel in vivo metabolomics approach, we show that the major mechanism by which insulin suppresses HGP is through reductions in hepatic acetyl CoA by suppression of lipolysis in white adipose tissue (WAT) leading to reductions in pyruvate carboxylase flux. This mechanism was confirmed in mice and rats with genetic ablation of insulin signaling and mice lacking adipose triglyceride lipase. Insulin’s ability to suppress hepatic acetyl CoA, PC activity, and lipolysis was lost in high-fat-fed rats, a phenomenon reversible by IL-6 neutralization and inducible by IL-6 infusion. Taken together, these data identify WAT-derived hepatic acetyl CoA as the main regulator of HGP by insulin and link it to inflammation-induced hepatic insulin resistance associated with obesity and T2D.

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Unraveling the Regulation of Hepatic Metabolism by Insulin

Titchenell

Lazar

Birnbaum

2017

Trends in Endocrinology & Metabolism

334

257

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During insulin-resistant states such as type 2 diabetes mellitus (T2DM), insulin fails to suppress hepatic glucose production yet promotes lipid synthesis leading to hyperglycemia and hypertriglyceridemia. Defining the downstream signaling pathways underlying the control of hepatic metabolism by insulin is necessary for understanding both normal physiology and the pathogenesis of metabolic disease. Here, we summarize recent literature highlighting the importance of both hepatic and extra-hepatic mechanisms in insulin’s regulation of liver glucose and lipid metabolism. We posit that a failure of insulin to inappropriately regulate liver metabolism during T2DM is not exclusively from an inherent defect in canonical liver insulin signaling but, rather, due to a combination of hyperinsulinemia, altered substrate supply, and the input of several extra-hepatic signals.

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Dietary fructose feeds hepatic lipogenesis via microbiota-derived acetate

Zhao

Jang

Liu

et al. 2020

Nature

383

250

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Fructose consumption has risen dramatically in recent decades due to use of sucrose and high fructose corn syrup in beverages and processed foods 1 , contributing to rising rates of obesity and non-alcoholic fatty liver disease (NAFLD) 2 – 4 . Fructose intake triggers hepatic de novo lipogenesis (DNL) 4 – 6 , which is initiated from acetyl-CoA. ATP-citrate lyase (ACLY) cleaves cytosolic citrate to generate acetyl-CoA and is upregulated upon carbohydrate consumption 7 . Ongoing clinical trials are pursuing ACLY inhibition for treatment of metabolic diseases 8 . Nevertheless, the route from dietary fructose to hepatic acetyl-CoA and lipids remains unproven. Here we show, using in vivo isotope tracing, that liver-specific deletion of Acly fails to suppress fructose-induced DNL in mice. Dietary fructose is converted by the gut microbiome into acetate 9 , which supplies lipogenic acetyl-CoA independently of ACLY 10 . Depletion of the microbiome or silencing of hepatic ACSS2, which generates acetyl-CoA from acetate, potently suppresses conversion of a fructose bolus into hepatic acetyl-CoA and fatty acids, bypassing ACLY. When fructose is consumed more gradually to facilitate its absorption in the small intestine, both citrate cleavage and microbial acetate contribute to lipogenesis. The DNL transcriptional program, on the other hand, is activated in response to fructose in a manner independent of acetyl-CoA metabolism. These data reveal a two-pronged mechanism regulating hepatic DNL, in which fructolysis within hepatocytes provides a signal to promote DNL gene expression, while microbial acetate generation feeds lipogenic acetyl-CoA pools.

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Direct Hepatocyte Insulin Signaling Is Required for Lipogenesis but Is Dispensable for the Suppression of Glucose Production

et al. 2016

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Summary Insulin-resistant syndromes such as type II diabetes mellitus (T2DM) involve disrupted temporal coordination of hepatic metabolism such that synthesis and secretion of lipid and glucose are inappropriately engaged concurrently. Here we test the hypothesis that a combination of direct and indirect actions of insulin on liver can lead to the metabolic phenotype exhibited in T2DM without a defect in proximal hepatic insulin signaling. First, we show that the insulin-dependent inhibition of Foxo1 and activation of mTorc1 by Akt is both necessary and sufficient for the induction of lipogenesis and the lipogenic gene program. In marked contrast, insulin, acting in vivo independent of hepatocyte insulin signaling can suppress glucose production by reducing serum free fatty acids. These studies support the hypothesis that under conditions of obesity and diabetes, intact hepatic insulin signaling can maintain lipogenesis while excess circulating FFAs become a dominant positive regulator of HGP.

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The LKB1-salt-inducible kinase pathway functions as a key gluconeogenic suppressor in the liver

et al. 2014

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LKB1 is a master kinase that regulates metabolism and growth through adenosine monophosphate-activated protein kinase (AMPK) and 12 other closely related kinases. Liver-specific ablation of LKB1 causes increased glucose production in hepatocytes in vitro and hyperglycaemia in fasting mice in vivo. Here we report that the salt-inducible kinases (SIK1, 2 and 3), members of the AMPK-related kinase family, play a key role as gluconeogenic suppressors downstream of LKB1 in the liver. The selective SIK inhibitor HG-9-91-01 promotes dephosphorylation of transcriptional co-activators CRTC2/3 resulting in enhanced gluconeogenic gene expression and glucose production in hepatocytes, an effect that is abolished when an HG-9-91-01-insensitive mutant SIK is introduced or LKB1 is ablated. Although SIK2 was proposed as a key regulator of insulin-mediated suppression of gluconeogenesis, we provide genetic evidence that liver-specific ablation of SIK2 alone has no effect on gluconeogenesis and insulin does not modulate SIK2 phosphorylation or activity. Collectively, we demonstrate that the LKB1–SIK pathway functions as a key gluconeogenic gatekeeper in the liver.

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