Mapping the metabolic reprogramming induced by sodium-glucose cotransporter 2 inhibition

Diabetes is associated with increased risk for kidney disease, heart failure, and mortality. Sodium-glucose cotransporter 2 inhibitors (SGLT2i) prevent these adverse outcomes; however, the mechanisms involved are not clear. We generated a roadmap of the metabolic alterations that occur in different organs in diabetes and in response to SGLT2i. In vivo metabolic labeling with 13C-glucose in normoglycemic and diabetic mice treated with or without dapagliflozin, followed by metabolomics and metabolic flux analyses, showed that, in diabetes, glycolysis and glucose oxidation are impaired in the kidney, liver, and heart. Treatment with dapagliflozin failed to rescue glycolysis. SGLT2 inhibition increased glucose oxidation in all organs; in the kidney, this was associated with modulation of the redox state. Diabetes was associated with altered methionine cycle metabolism, evident by decreased betaine and methionine levels, whereas treatment with SGLT2i increased hepatic betaine along with decreased homocysteine levels. mTORC1 activity was inhibited by SGLT2i along with stimulation of AMPK in both normoglycemic and diabetic animals, possibly explaining the protective effects against kidney, liver, and heart diseases. Collectively, our findings suggest that SGLT2i induces metabolic reprogramming orchestrated by AMPK-mTORC1 signaling with common and distinct effects in various tissues, with implications for diabetes and aging.

[1]  F. Ashcroft,et al.  Altered glycolysis triggers impaired mitochondrial metabolism and mTORC1 activation in diabetic β-cells , 2022, Nature Communications.

[2]  V. Rigalleau,et al.  Nutritional biomarkers and heart failure requiring hospitalization in patients with type 2 diabetes: the SURDIAGENE cohort , 2022, Cardiovascular Diabetology.

[3]  Hassan ul Hussain,et al.  Effect of novel glucose lowering agents on non-alcoholic fatty liver disease: A systematic review and meta-analysis. , 2022, Clinics and research in hepatology and gastroenterology.

[4]  D. Tang,et al.  Metabolomics study reveals the alteration of fatty acid oxidation in the hearts of diabetic mice by empagliflozin. , 2022, Molecular omics.

[5]  Yi Dang,et al.  Dapagliflozin Attenuates Myocardial Fibrosis by Inhibiting the TGF-β1/Smad Signaling Pathway in a Normoglycemic Rabbit Model of Chronic Heart Failure , 2022, Frontiers in Pharmacology.

[6]  C. Ecelbarger,et al.  Empagliflozin Treatment Attenuates Hepatic Steatosis by Promoting White Adipose Expansion in Obese TallyHo Mice , 2022, International journal of molecular sciences.

[7]  Kahealani Uehara,et al.  Inhibition of nonalcoholic fatty liver disease in mice by selective inhibition of mTORC1 , 2022, Science.

[8]  T. Szkudelski,et al.  The anti-diabetic potential of betaine. Mechanisms of action in rodent models of type 2 diabetes. , 2022, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.

[9]  Nektarios Tavernarakis,et al.  One-Carbon Metabolism: Pulling the Strings behind Aging and Neurodegeneration , 2022, Cells.

[10]  T. Matsha,et al.  Methylenetetrahydrofolate (MTHFR), the One-Carbon Cycle, and Cardiovascular Risks , 2021, Nutrients.

[11]  P. Ponikowski,et al.  Empagliflozin in Heart Failure with a Preserved Ejection Fraction. , 2021, The New England journal of medicine.

[12]  P. Lawler,et al.  Changes in plasma and urine metabolites associated with empagliflozin in patients with type 1 diabetes , 2021, Diabetes, obesity & metabolism.

[13]  L. Gluud,et al.  The Role of the Transsulfuration Pathway in Non-Alcoholic Fatty Liver Disease , 2021, Journal of clinical medicine.

[14]  D. Mikhailidis,et al.  Homocysteine and diabetes: Role in macrovascular and microvascular complications. , 2020, Journal of diabetes and its complications.

[15]  D. Allison,et al.  Canagliflozin extends life span in genetically heterogeneous male but not female mice , 2020, JCI insight.

[16]  J. McMurray,et al.  Dapagliflozin in Patients with Chronic Kidney Disease. , 2020, The New England journal of medicine.

[17]  B. Tirosh,et al.  Proximal Tubule mTORC1 Is a Central Player in the Pathophysiology of Diabetic Nephropathy and Its Correction by SGLT2 Inhibitors , 2020, Cell reports.

[18]  H. Maegawa,et al.  SGLT2 Inhibition Mediates Protection from Diabetic Kidney Disease by Promoting Ketone Body-Induced mTORC1 Inhibition. , 2020, Cell metabolism.

[19]  D. Sabatini,et al.  Dihydroxyacetone phosphate signals glucose availability to mTORC1 , 2020, Nature Metabolism.

[20]  A. Vazquez,et al.  Metabolite AutoPlotter - an application to process and visualise metabolite data in the web browser , 2020, Cancer & Metabolism.

[21]  W. Ju,et al.  A metabolomics‐based molecular pathway analysis of how the sodium‐glucose co‐transporter‐2 inhibitor dapagliflozin may slow kidney function decline in patients with diabetes , 2020, Diabetes, obesity & metabolism.

[22]  D. Sabatini,et al.  mTOR at the nexus of nutrition, growth, ageing and disease , 2020, Nature Reviews Molecular Cell Biology.

[23]  Akshay S. Desai,et al.  Dapagliflozin in Patients with Heart Failure and Reduced Ejection Fraction. , 2019, The New England journal of medicine.

[24]  Deepak L. Bhatt,et al.  Effects of dapagliflozin on development and progression of kidney disease in patients with type 2 diabetes: an analysis from the DECLARE-TIMI 58 randomised trial. , 2019, The lancet. Diabetes & endocrinology.

[25]  G. Laverman,et al.  Effects of dapagliflozin on urinary metabolites in people with type 2 diabetes , 2019, Diabetes, obesity & metabolism.

[26]  B. Zinman,et al.  Canagliflozin and Renal Outcomes in Type 2 Diabetes and Nephropathy. , 2019, The New England journal of medicine.

[27]  M. Patti,et al.  SGLT2 inhibition reprograms systemic metabolism via FGF21-dependent and -independent mechanisms. , 2019, JCI insight.

[28]  S. Verma,et al.  Empagliflozin Increases Cardiac Energy Production in Diabetes , 2018, JACC. Basic to translational science.

[29]  I. Shimomura,et al.  Metabolomic and microarray analyses of adipose tissue of dapagliflozin-treated mice, and effects of 3-hydroxybutyrate on induction of adiponectin in adipocytes , 2018, Scientific Reports.

[30]  David S. Wishart,et al.  MetaboAnalyst 4.0: towards more transparent and integrative metabolomics analysis , 2018, Nucleic Acids Res..

[31]  T. Weichhart mTOR as Regulator of Lifespan, Aging, and Cellular Senescence: A Mini-Review , 2017, Gerontology.

[32]  Dudley Lamming,et al.  Regulation of metabolic health and aging by nutrient-sensitive signaling pathways , 2017, Molecular and Cellular Endocrinology.

[33]  E. Ferrannini Sodium-Glucose Co-transporters and Their Inhibition: Clinical Physiology. , 2017, Cell metabolism.

[34]  William J. Israelsen,et al.  Pyruvate kinase M2 activation may protect against the progression of diabetic glomerular pathology and mitochondrial dysfunction , 2017, Nature Medicine.

[35]  R. Gilbert Proximal Tubulopathy: Prime Mover and Key Therapeutic Target in Diabetic Kidney Disease , 2017, Diabetes.

[36]  R. DeFronzo,et al.  Renal, metabolic and cardiovascular considerations of SGLT2 inhibition , 2017, Nature Reviews Nephrology.

[37]  John M Lachin,et al.  Empagliflozin and Progression of Kidney Disease in Type 2 Diabetes. , 2016, The New England journal of medicine.

[38]  M. Fischereder,et al.  Empagliflozin, Cardiovascular Outcomes, and Mortality in Type 2 Diabetes. , 2016, The New England journal of medicine.

[39]  T. Pieber,et al.  Shift to Fatty Substrate Utilization in Response to Sodium–Glucose Cotransporter 2 Inhibition in Subjects Without Diabetes and Patients With Type 2 Diabetes , 2016, Diabetes.

[40]  Emma L. Baar,et al.  Sex‐ and tissue‐specific changes in mTOR signaling with age in C57BL/6J mice , 2015, Aging cell.

[41]  Dritan Liko,et al.  mTOR in health and in sickness , 2015, Journal of Molecular Medicine.

[42]  E. Gottlieb,et al.  Analysis of Cell Metabolism Using LC-MS and Isotope Tracers. , 2015, Methods in enzymology.

[43]  R. Bamezai,et al.  Pyruvate kinase M2 and cancer: an updated assessment , 2014, FEBS letters.

[44]  R. DeFronzo,et al.  Dapagliflozin improves muscle insulin sensitivity but enhances endogenous glucose production. , 2014, The Journal of clinical investigation.

[45]  T. Heise,et al.  Metabolic response to sodium-glucose cotransporter 2 inhibition in type 2 diabetic patients. , 2014, The Journal of clinical investigation.

[46]  C. Baines,et al.  Cardiac‐specific Hexokinase 2 Overexpression Attenuates Hypertrophy by Increasing Pentose Phosphate Pathway Flux , 2013, Journal of the American Heart Association.

[47]  Verena Albert,et al.  mTOR in aging, metabolism, and cancer. , 2013, Current opinion in genetics & development.