Effects of Metformin on Lactate Uptake and Gluconeogenesis in the Perfused Rat Liver

Radziuk, J.; Zhang, Zi; Wiernsperger, Nicolas; Pye, Susan

doi:10.2337/diab.46.9.1406

Cited by 96 publications

(57 citation statements)

References 42 publications

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“…This strongly suggests that, in addition to its downstream inhibitory action on glucose production at the level of Glc6Pase, Met has an upstream suppressive effect on the lactate uptake by the liver. This corroborates recent data obtained from perfused rat livers (30).…”

Section: Discussionsupporting

confidence: 82%

“…The decreasing effect of Met on HGP has been previously ascribed to the inhibition of either gluconeogenesis (2,3,30) or glycogenolysis (5). We emphasize that the major effect of Met on Glc6Pase activity reported herein strongly suggests that both pathways may be affected as well, because Glc6Pase is a common step for both gluconeogenesis and glycogenolysis.…”

Section: Discussionmentioning

confidence: 76%

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Intrahepatic Mechanisms Underlying the Effect of Metformin in Decreasing Basal Glucose Production in Rats Fed a High-Fat Diet

Mithieux

Guignot

Bordet³

et al. 2002

Diabetes

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The aim of this study was to understand by which intrahepatic mechanism metformin (Met) may inhibit basal hepatic glucose production (HGP) in type 2 diabetes. We studied rats that were fed for 6 weeks a high-fat (HF) diet, supplemented (HF-Met) or not (HF) with Met (50 mg ⅐ kg ؊1 ⅐ day ؊1 ). Basal HGP, assessed by 3-[ 3 H]glucose tracer dilution, was lower by 20% in HFMet rats compared with HF-rats: 41.6 ؎ 0.7 vs. 52 ؎ 1.5 mol ⅐ kg ؊1 ⅐ min ؊1 (means ؎ SE, n ‫؍‬ 5; P < 0.01). Glucose-6 phosphatase (Glc6Pase) activity, assayed in a liver lobe freeze-clamped in situ, was lower by 25% in HF-Met rats compared with HF-rats (7.9 ؎ 0.4 vs. 10.3 ؎ 0.9 mol ⅐ min ؊1 ⅐ g ؊1 wet liver; P < 0.05). Glucose-6 phosphate and glycogen contents, e.g., 42 ؎ 5 nmol/g and 3.9 ؎ 2.4 mg/g, respectively, in HF-rats were dramatically increased by three to five times in HF-Met rats, e.g., 118 ؎ 12 nmol/g and 19.6 ؎ 4.6 mg/g (P < 0.05 and P < 0.01, respectively). Glucose-6 phosphate dehydrogenase activity was increased in HF-Met compared with HF rats (1.51 ؎ 0.1 vs. 1.06 ؎ 0.08 mol ⅐ min ؊1 ⅐ g ؊1 ; P < 0.01). Intrahepatic lactate concentration tended to be lower in the Met-group (؊30%; NS), whereas plasma lactate concentration was higher in HF-Met rats (1.59 ؎ 0.15 mmol/l) than in HF rats (1.06 ؎ 0.06 mmol/l; P < 0.05). We concluded that Met decreases HGP in insulin-resistant HF-fed rats mainly by an inhibition of hepatic Glc6Pase activity, promoting glycogen sparing. Additional mechanisms might involve the diversion of glucose-6 phosphate into the pentose phosphate pathway and an inhibition of hepatic lactate uptake. Diabetes 51:139 -143, 2002

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Section: Discussionsupporting

confidence: 82%

Section: Discussionmentioning

confidence: 76%

Intrahepatic Mechanisms Underlying the Effect of Metformin in Decreasing Basal Glucose Production in Rats Fed a High-Fat Diet

Mithieux

Guignot

Bordet³

et al. 2002

Diabetes

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“…Lactate, a substrate for HGP, was significantly increased in the high-dose Met group relative to both the lower Met dose and Veh. In isolated mitochondria or hepatocytes, Met has been shown to impair mitochondrial respiration by complex 1 inhibition, resulting in increased glycolysis and glucose uptake, decreased liver lactate uptake and decreased use of lactate as a substrate for glucose production (Radziuk et al 1997, Owen et al 2000, Otto et al 2003. However, Met is also known to activate lactate production in the intestine and muscle (Borst & Snellen 2001), which may hypothetically, in an in vivo system, lead to an excessive gluconeogenic substrate loading, overriding Met-related reductions in lactate usage.…”

Section: Discussionmentioning

confidence: 99%

Metformin attenuates olanzapine-induced hepatic, but not peripheral insulin resistance

Remington

Teo

Wilson

et al. 2015

Journal of Endocrinology

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Antipsychotics (APs) are linked to diabetes, even without weight gain. Whether anti-diabetic drugs are efficacious in reversing the direct effects of APs on glucose pathways is largely undetermined. We tested two metformin (Met) doses to prevent impairments seen following a dose of olanzapine (Ola) (3 mg/kg); glucokinetics were measured using the hyperinsulinemic-euglycemic clamp (HIEC). Met (150 mg/kg; nZ13, or 400 mg/kg; nZ11) or vehicle (Veh) (nZ11) was administered through gavage preceding an overnight fast, followed by a second dose prior to the HIEC. Eleven additional animals were gavaged with Veh and received a Veh injection during the HIEC (Veh/Veh); all others received Ola. Basal glucose was similar across treatment groups. The Met 400 group had significantly greater glucose appearance (R a ) in the basal period (i.e., before Ola, or hyperinsulinemia) vs other groups. During hyperinsulinemia, glucose infusion rate (GINF) to maintain euglycemia (reflective of whole-body insulin sensitivity) was higher in Veh/Veh vs other groups. Met 150/Ola animals demonstrated increased GINF relative to Veh/Ola during early time points of the HIEC. Glucose utilization during hyperinsulinemia, relative to basal conditions, was significantly higher in Veh/Veh vs other groups. The change in hepatic glucose production (HGP) from basal to hyperinsulinemia demonstrated significantly greater decreases in Veh/Veh and Met 150/Ola groups vs Veh/Ola. Given the increase in basal R a with Met 400, we measured serum lactate (substrate for HGP), finding increased levels in Met 400 vs Veh and Met 150. In conclusion, Met attenuates hepatic insulin resistance observed with acute Ola administration, but fails to improve peripheral insulin resistance. Use of supra-therapeutic doses of Met may mask metabolic benefits by increasing lactate.

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“…The multiplicity of effects of metformin also includes the reduction in gluconeogenesis in liver cells due to the decreased uptake of gluconeogenic substrates such as L-alanine (Komori et al 1993) and lactate (Radziuk et al 1997) and the direct inhibition of the redox shuttle enzyme glycerophosphate dehydrogenase (Madiraju et al 2014). Metformin also reduces glucose output through the decrease in cAMP, protein kinase A activity and phosphorylation of protein kinase A substrates induced by glucagon .…”

Section: Metformin and Glucose Cell Metabolismmentioning

confidence: 99%

Metformin, cancer and glucose metabolism

Salani¹,

Río²,

Marini³

et al. 2014

Endocrine-Related Cancer

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Metformin is the first-line treatment for type 2 diabetes. Results from several clinical studies have indicated that type 2 diabetic patients treated with metformin might have a lower cancer risk. One of the primary metabolic changes observed in malignant cell transformation is an increased catabolic glucose metabolism. In this context, once it has entered the cell through organic cation transporters, metformin decreases mitochondrial respiration chain activity and ATP production that, in turn, activates AMP-activated protein kinase, which regulates energy homeostasis. In addition, metformin reduces cellular energy availability and glucose entrapment by inhibiting hexokinase-II, which catalyses the glucose phosphorylation reaction. In this review, we discuss recent findings on molecular mechanisms that sustain the anticancer effect of metformin through regulation of glucose metabolism. In particular, we have focused on the emerging action of metformin on glycolysis in normal and cancer cells, with a drug discovery perspective.

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Effects of Metformin on Lactate Uptake and Gluconeogenesis in the Perfused Rat Liver

Cited by 96 publications

References 42 publications

Intrahepatic Mechanisms Underlying the Effect of Metformin in Decreasing Basal Glucose Production in Rats Fed a High-Fat Diet

Intrahepatic Mechanisms Underlying the Effect of Metformin in Decreasing Basal Glucose Production in Rats Fed a High-Fat Diet

Metformin attenuates olanzapine-induced hepatic, but not peripheral insulin resistance

Metformin, cancer and glucose metabolism

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