Insulin Induces a Shift in Lipid and Primary Carbon Metabolites in a Model of Fasting-induced Insulin Resistance

Overview

Journal Metabolomics

Publisher Springer

Specialty Endocrinology

Date 2017 Aug 1

PMID 28757815

Citations 2

Authors

Keedrian I Olmstead

Michael R La Frano

Johannes Fahrmann

Dmitry Grapov

Jose A Viscarra

John W Newman

Oliver Fiehn

Daniel E Crocker

Fabian V Filipp

Rudy M Ortiz

Affiliations

Soon will be listed here.

Abstract

Introduction: Prolonged fasting in northern elephant seals (NES) is characterized by a reliance on lipid metabolism, conservation of protein, and reduced plasma insulin. During early fasting, glucose infusion previously reduced plasma free fatty acids (FFA); however, during late-fasting, it induced an atypical elevation in FFA despite comparable increases in insulin during both periods suggestive of a dynamic shift in tissue responsiveness to glucose-stimulated insulin secretion.

Objective: To better assess the contribution of insulin to this fasting-associated shift in substrate metabolism.

Methods: We compared the responses of plasma metabolites (amino acids (AA), FFA, endocannabinoids (EC), and primary carbon metabolites (PCM)) to an insulin infusion (65 mU/kg) in early- and late-fasted NES pups (n = 5/group). Plasma samples were collected prior to infusion (T0) and at 10, 30, 60, and 120 min post-infusion, and underwent untargeted and targeted metabolomics analyses utilizing a variety of GC-MS and LC-MS technologies.

Results: In early fasting, the majority (72%) of metabolite trajectories return to baseline levels within 2 h, but not in late fasting indicative of an increase in tissue sensitivity to insulin. In late-fasting, increases in FFA and ketone pools, coupled with decreases in AA and PCM, indicate a shift toward lipolysis, beta-oxidation, ketone metabolism, and decreased protein catabolism. Conversely, insulin increased PCM AUC in late fasting suggesting that gluconeogenic pathways are activated. Insulin also decreased FFA AUC between early and late fasting suggesting that insulin suppresses triglyceride hydrolysis.

Conclusion: Naturally adapted tolerance to prolonged fasting in these mammals is likely accomplished by suppressing insulin levels and activity, providing novel insight on the evolution of insulin during a condition of temporary, reversible insulin resistance.

Citing Articles

Oxylipin responses to fasting and insulin infusion in a large mammalian model of fasting-induced insulin resistance, the northern elephant seal.

Wright D, Katundu K, Viscarra J, Crocker D, Newman J, La Frano M Am J Physiol Regul Integr Comp Physiol. 2021; 321(4):R537-R546.

PMID: 34346724 PMC: 8560368. DOI: 10.1152/ajpregu.00016.2021.

Exogenous GLP-1 stimulates TCA cycle and suppresses gluconeogenesis and ketogenesis in late-fasted northern elephant seals pups.

Dhillon J, Viscarra J, Newman J, Fiehn O, Crocker D, Ortiz R Am J Physiol Regul Integr Comp Physiol. 2021; 320(4):R393-R403.

PMID: 33407018 PMC: 8238143. DOI: 10.1152/ajpregu.00211.2020.

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