Renal glucose production and utilization: new aspects in humans

Stümvoll, Michael; Meyer, Christian; Mitrakou, Asimina; Nadkarni, Veena; Gerich, John E.

doi:10.1007/s001250050745

Cited by 229 publications

(132 citation statements)

References 78 publications

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“…We failed to observe any effect of acute insulin deficiency on renal glucose production in type 1 diabetic subjects, but as noted above it is possible that more severe hypoinsulinaemia could have promoted renal glucose production. In particular, it should be noticed that under the current conditions insulin withdrawal did not augment circulating epinephrine concentrations and that epinephrine has been reported to stimulate renal glucose production; and blood levels of epinephrine increase in severe diabetic derangement, such as ketoacidosis [4,6]. Table 5 Arterial plasma concentrations and whole-body appearance rates for palmitate and femoral and renal net palmitate balances, and palmitate release and uptake rates in five diabetic subjects with and without insulin and in six control subjects Enhanced lipolysis and uncontrolled ketogenesis following insulin deprivation can lead to diabetic ketoacidosis.…”

Section: Discussionmentioning

confidence: 69%

“…The renal contribution to endogenous glucose production has been a matter of much controversy [4][5][6][7][8][9][10][11][12]28]. Much of the confusion in all likelihood has arisen from the fact that measurements across the renal bed, because of the high renal blood flow of around 1 l/min, are highly susceptible to methodological imprecision as regards analysis of differences in arteriovenous glucose concentrations and dilution of tracers.…”

Section: Discussionmentioning

confidence: 99%

“…Until recently it was assumed that the primary tissues participating in these events were liver (increased glucose production and ketogenesis), adipose tissue (increased lipolysis) and muscle (increased proteolysis) [1][2][3]. Several reports have suggested that in addition the kidney may be an important component in the regulation of intermediary metabolism, in particular glucose metabolism [4]. This renewed interest in the metabolic role of the kidney was fuelled by a study by Cersosimo et al [5] who used arteriovenous balance and isotopic dilution techniques to report that in postabsorptive dogs renal glucose utilisation and production each accounted for close to 30% of total glucose turnover in the presence of net balances close to zero.…”

Section: Introductionmentioning

confidence: 99%

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Renal amino acid, fat and glucose metabolism in type 1 diabetic and non-diabetic humans: effects of acute insulin withdrawal

et al. 2006

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Aims/hypothesis: The aim of this study was to test the hypothesis that type 1 diabetes alters renal amino acid, glucose and fatty acid metabolism. Materials and methods: We studied five C-peptide-negative, type 1 diabetic subjects during insulin replacement (glucose 5.6 mmol/l) and insulin deprivation (glucose 15.5 mmol/l) and compared them with six non-diabetic subjects. Leucine, phenylalanine, tyrosine, glucose and palmitate tracers were infused after an overnight fast and samples were obtained from the renal vein, femoral vein and femoral artery. Results: Insulin deprivation significantly increased wholebody fluxes (20-25%) of phenylalanine, tyrosine and leucine, and leucine oxidation (50%). Kidney contributed 5-10% to the whole-body leucine and phenylalanine flux. A net uptake of phenylalanine, conversion of phenylalanine to tyrosine (5 μmol/min) and net release of tyrosine (∼5 μmol/min) occurred across the kidney. Whole-body (three-fold) and leg (two-fold) leucine transamination increased but amino acid metabolism in the kidney did not alter with diabetes or insulin deprivation. Insulin deprivation doubled endogenous glucose production, renal glucose production was unaltered by insulin deprivation and diabetes (ranging between 100 and 140 μmol/min).Renal palmitate exchange was unaltered by insulin deprivation. Conclusions/interpretation: In conclusion, kidney postabsorptively accounts for 5-10% of whole-body protein turnover, 15-20% of leucine transamination and 10-15% of endogenous glucose production, and actively converts phenylalanine to tyrosine. During insulin deprivation, leg becomes a major site for leucine transamination but insulin deprivation does not affect renal phenylalanine, leucine, palmitate or glucose metabolism. Despite its key metabolic role, insulin deprivation in type 1 diabetic patients does not alter many of these metabolic functions.

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Section: Discussionmentioning

confidence: 69%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Renal amino acid, fat and glucose metabolism in type 1 diabetic and non-diabetic humans: effects of acute insulin withdrawal

et al. 2006

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“…Interestingly moderate increase of insulin suppressed liver, but not kidney, PEPCK mRNA in both the PEPCK transgenic and control rats. As has been previously suggested [32], this implies that kidney PEPCK is not as insulin responsive as liver PEPCK and that increased renal glucose production can be a substantial contributor to glucose turnover [36,37]. It has been shown that in patients undergoing liver transplantation endogenous glucose production falls about 50% after removal of the liver, representing renal glucose production [38].…”

Section: Discussionmentioning

confidence: 91%

Peripheral insulin resistance develops in transgenic rats overexpressing phosphoenolpyruvate carboxykinase in the kidney

et al. 2003

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Aims/hypothesis. To study the secondary consequences of impaired suppression of endogenous glucose production (EGP) we have created a transgenic rat overexpressing the gluconeogenic enzyme phosphoenolpyruvate carboxykinase (PEPCK) in the kidney. The aim of this study was to determine whether peripheral insulin resistance develops in these transgenic rats. Methods. Whole body rate of glucose disappearance (R d ) and endogenous glucose production were measured basally and during a euglycaemic/hyperinsulinaemic clamp in phosphoenolpyruvate carboxykinase transgenic and control rats using [6-3 H]-glucose. Glucose uptake into individual tissues was measured in vivo using 2-[1-14 C]-deoxyglucose. Results. Phosphoenolpyruvate carboxykinase transgenic rats were heavier and had increased gonadal and infrarenal fat pad weights. Under basal conditions, endogenous glucose production was similar in phosphoenolpyruvate carboxykinase transgenic and control rats (37.4±1.1 vs 34.6±2.6 µmol/kg/min). Moderate hyperinsulinaemia (810 pmol/l) completely suppressed EGP in control rats (−0.6±5.5 µmol/kg/min, p<0.05) while there was no suppression in phosphoenolpyruvate carboxykinase rats (45.2±7.9 µmol/kg/min). Basal R d was comparable between PEPCK transgenic and control rats (37.4±1.1 vs 34.6±2.6 µmol/kg/min) but under insulin-stimulated conditions the increase in R d was greater in control compared to phosphoenolpyruvate carboxykinase transgenic rats indicative of insulin resistance (73.4±11.2 vs 112.0±8.0 µmol/kg/min, p<0.05). Basal glucose uptake was reduced in white and brown adipose tissue, heart and soleus while insulin-stimulated transport was reduced in white and brown adipose tissue, white quadriceps, white gastrocnemius and soleus in phosphoenolpyruvate carboxykinase transgenic compared to control rats. The impairment in both white and brown adipose tissue glucose uptake in phosphoenolpyruvate carboxykinase transgenic rats was associated with a decrease in GLUT4 protein content. In contrast, muscle GLUT4 protein, triglyceride and long-chain acylCoA levels were comparable between PEPCK transgenic and control rats. Conclusions/interpretation. A primary defect in suppression of EGP caused adipose tissue and muscle insulin resistance. [Diabetologia (2003[Diabetologia ( ) 46:1338[Diabetologia ( -1347

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“…Accumulation of cadmium in both liver and kidney is a cause for concern as these two organs contribute to the maintenance of blood glucose levels (Gerich 2010;DeFronzo et al 2012). In the post absorptive state, kidney and liver supply an equal amount of glucose into blood circulation (Stumvoll et al 1997;Gerich 2010;DeFronzo et al 2012). Further, cadmium accumulation in kidney and RPE could contribute to early onset of diabetic nephropathy and retinopathy as seen in the Torres Strait (Australia) population who had elevated dietary cadmium exposures (Satarug et al 2000b;HaswellElkins et al 2007a,b;Haswell-Elkins et al 2008).…”

Section: Salient Features Of Cadmiummentioning

confidence: 99%

Emerging Roles of Cadmium and Heme Oxygenase in Type-2 Diabetes and Cancer Susceptibility

Satarug

2012

Tohoku J. Exp. Med.

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Many decades after an outbreak of severe cadmium poisoning, known as Itai-itai disease, cadmium continues to pose a significant threat to human health worldwide. This review provides an update on the effects of this environmental toxicant cadmium, observed in numerous populations despite modest exposure levels. In addition, it describes the current knowledge on the link between heme catabolism and glycolysis. It examines novel functions of heme oxygenase-2 (HO-2) that protect against type 2-diabetes and obesity, which have emerged from diabetic/obese phenotypes of the HO-2 knockout mouse model. Increased cancer susceptibility in type-2 diabetes has been noted in several large cohorts. This is a cause for concern, given the high prevalence of type-2 diabetes worldwide. A lifetime exposure to cadmium is associated with pre-diabetes, diabetes, and overall cancer mortality with sex-related differences in specific types of cancer. Liver and kidney are target organs for the toxic effects of cadmium. These two organs are central to the maintenance of blood glucose levels. Further, inhibition of gluconeogenesis is a known effect of heme, while cadmium has the propensity to alter heme catabolism. This raises the possibility that cadmium may mimic certain HO-2 deficiency conditions, resulting in diabetic symptoms. Intriguingly, evidence has emerged from a recent study to suggest the potential interaction and co-regulation of HO-2 with the key regulator of glycolysis: 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase 4 (PFKFB4). HO-2 could thus be critical to a metabolic switch to cancer-prone cells because the enzyme PFKFB and glycolysis are metabolic requirements for cell proliferation and resistance to apoptosis.

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Renal glucose production and utilization: new aspects in humans

Cited by 229 publications

References 78 publications

Renal amino acid, fat and glucose metabolism in type 1 diabetic and non-diabetic humans: effects of acute insulin withdrawal

Renal amino acid, fat and glucose metabolism in type 1 diabetic and non-diabetic humans: effects of acute insulin withdrawal

Peripheral insulin resistance develops in transgenic rats overexpressing phosphoenolpyruvate carboxykinase in the kidney

Emerging Roles of Cadmium and Heme Oxygenase in Type-2 Diabetes and Cancer Susceptibility

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