Frontiers in Physiology (Mar 2020)

Diabetes Increases the Vulnerability of the Cardiac Mitochondrial Network to Criticality

  • Larissa Vetter,
  • Larissa Vetter,
  • Sonia Cortassa,
  • Brian O’Rourke,
  • Antonis A. Armoundas,
  • Antonis A. Armoundas,
  • Djahida Bedja,
  • Johann M. E. Jende,
  • Martin Bendszus,
  • Nazareno Paolocci,
  • Nazareno Paolocci,
  • Steven J. Sollot,
  • Miguel A. Aon,
  • Felix T. Kurz,
  • Felix T. Kurz

DOI
https://doi.org/10.3389/fphys.2020.00175
Journal volume & issue
Vol. 11

Abstract

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Mitochondrial criticality describes a state in which the mitochondrial cardiac network under intense oxidative stress becomes very sensitive to small perturbations, leading from local to cell-wide depolarization and synchronized oscillations that may escalate to the myocardial syncytium generating arrhythmias. Herein, we describe the occurrence of mitochondrial criticality in the chronic setting of a metabolic disorder, type 1 diabetes (T1DM), using a streptozotocin (STZ)-treated guinea pig (GP) animal model. Using wavelet analysis of mitochondrial networks from two-photon microscopy imaging of cardiac myocytes loaded with a fluorescent probe of the mitochondrial membrane potential, we show that cardiomyocytes from T1DM GPs are closer to criticality, making them more vulnerable to cell-wide mitochondrial oscillations as can be judged by the latency period to trigger oscillations after a laser flash perturbation, and their propensity to oscillate. Insulin treatment of T1DM GPs rescued cardiac myocytes to sham control levels of susceptibility, a protective condition that could also be attained with interventions leading to improvement of the cellular redox environment such as preincubation of diabetic cardiac myocytes with the lipid palmitate or a cell-permeable form of glutathione, in the presence of glucose.

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