Exercise and metformin counteract altered mitochondrial function in the insulin-resistant brain
Gregory N. Ruegsegger, Patrick M. Vanderboom, Surendra Dasari, Katherine A. Klaus, Parijat Kabiraj, Christina B. McCarthy, Claudia F. Lucchinetti, K. Sreekumaran Nair
Gregory N. Ruegsegger, Patrick M. Vanderboom, Surendra Dasari, Katherine A. Klaus, Parijat Kabiraj, Christina B. McCarthy, Claudia F. Lucchinetti, K. Sreekumaran Nair
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Research Article Endocrinology Metabolism

Exercise and metformin counteract altered mitochondrial function in the insulin-resistant brain

Abstract

Insulin resistance associates with increased risk for cognitive decline and dementia; however, the underpinning mechanisms for this increased risk remain to be fully defined. As insulin resistance impairs mitochondrial oxidative metabolism and increases ROS in skeletal muscle, we considered whether similar events occur in the brain, which — like muscle — is rich in insulin receptors and mitochondria. We show that high-fat diet–induced (HFD-induced) brain insulin resistance in mice decreased mitochondrial ATP production rate and oxidative enzyme activities in brain regions rich in insulin receptors. HFD increased ROS emission and reduced antioxidant enzyme activities, with the concurrent accumulation of oxidatively damaged mitochondrial proteins and increased mitochondrial fission. Improvement of insulin sensitivity by both aerobic exercise and metformin ameliorated HFD-induced abnormalities. Moreover, insulin-induced enhancement of ATP production in primary cortical neurons and astrocytes was counteracted by the insulin receptor antagonist S961, demonstrating a direct effect of insulin resistance on brain mitochondria. Further, intranasal S961 administration prevented exercise-induced improvements in ATP production and ROS emission during HFD, supporting that exercise enhances brain mitochondrial function by improving insulin action. These results support that insulin sensitizing by exercise and metformin restores brain mitochondrial function in insulin-resistant states.

Authors

Gregory N. Ruegsegger, Patrick M. Vanderboom, Surendra Dasari, Katherine A. Klaus, Parijat Kabiraj, Christina B. McCarthy, Claudia F. Lucchinetti, K. Sreekumaran Nair

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Figure 2

Aerobic exercise corrects impairments in mitochondrial function accompanying HFD.

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Aerobic exercise corrects impairments in mitochondrial function accompan...
(A and B) Citrate synthase (CS) (A) and cytochrome c oxidase (COX (B) activities were lower in the hypothalamus (Hypo), hippocampus (Hippo), and cortex in HFD-SED, which was corrected in HFD-EX. Further, chow-EX led to additional increases in CS and COX activities in the hippocampus (n = 10–11). (C) Mitochondrial ATP production rate (MAPR) in isolated cerebral mitochondria was lower in HFD-SED, which was corrected in HFD-EX (n = 9–10). (D) ROS emission in isolated cerebral mitochondria was greater in HFD-SED, which was corrected in HFD-EX (n = 10–11). (E and F) Activities of antioxidant enzymes SOD2 (E) and Catalase (CAT) (F) were lower in HFD-SED, which were normalized in HFD-EX (n = 7). (G and H) MAPR (G) and ROS emission (H) negatively and positively associated with HOMA-IR, respectively. (I) Mitochondrial DNA (mtDNA) copy number, as indicated by Nd1 and Nd4, was lower in the hippocampus of HFD-SED, which was corrected in HFD-EX. Further, chow-EX led to an additional increase in mtDNA copy number (n = 6). (J) Select mitochondrial- and nuclear-encoded mRNAs encoding mitochondrial proteins were lower in the hippocampus of HFD-SED, which was mostly attenuated in HFD-EX. Further, chow-EX increased mRNA expression of several genes encoding mitochondrial proteins (n = 6). Data represent means ± SEM and were analyzed with 2-way ANOVA followed by Tukey’s multiple comparisons post hoc test (AF, I, and J) or Pearson correlation test (G and H); *P < 0.05.