Abstract
The mitochondrial mutator mouse is a well-established model of premature aging. In addition to accelerated aging, these mice develop hypertrophic cardiomyopathy at ~13 months of age, presumably due to overt mitochondrial dysfunction. Despite evidence of bioenergetic disruption within heart mitochondria, there is little information about the underlying changes to the mitochondrial proteome that either directly underly or predict respiratory insufficiency in mutator mice. Herein, nLC-MS/MS was used to interrogate the mitochondria-enriched proteome of heart and skeletal muscle of aged mutator mice. The mitochondrial proteome from heart tissue was then correlated with respiratory conductance data to identify protein biomarkers of respiratory insufficiency. The majority of downregulated proteins in mutator mitochondria were subunits of respiratory complexes I and IV, including both nuclear and mitochondrial-encoded proteins. Interestingly, the mitochondrial-encoded complex V subunits, were unchanged or upregulated in mutator mitochondria, suggesting a robustness to mtDNA mutation. Finally, the proteins most strongly correlated with respiratory conductance were PPM1K, NDUFB11, and C15orf61. These results suggest that mitochondrial mutator mice undergo a specific loss of mitochondrial complexes I and IV that limit their respiratory function independent of an upregulation of complex V. Additionally, the role of PPM1K in responding to mitochondrial stress warrants further exploration.
Highlights
The mitochondrial mutator mouse is a well-established model of premature aging
To investigate the proteomic impact of chronic bioenergetic insufficiency caused by the accumulation of mitochondrial DNA (mtDNA) mutations, label-free quantitative nLC-MS/MS was performed on cardiac mitochondria from D257A+/+ mice and WT littermates
By correlating proteomic and respiratory conductance data from heart mitochondria isolated from the same cohort of mice, novel relationships between heart protein expression and respiratory insufficiency were identified that may represent biomarkers for bioenergetic stress
Summary
The mitochondrial mutator mouse is a well-established model of premature aging. In addition to accelerated aging, these mice develop hypertrophic cardiomyopathy at ~13 months of age, presumably due to overt mitochondrial dysfunction. The mitochondrial proteome from heart tissue was correlated with respiratory conductance data to identify protein biomarkers of respiratory insufficiency. The proteins most strongly correlated with respiratory conductance were PPM1K, NDUFB11, and C15orf[61] These results suggest that mitochondrial mutator mice undergo a specific loss of mitochondrial complexes I and IV that limit their respiratory function independent of an upregulation of complex V. Given that all mice were aged to ~13 months, we reasoned that mice with the most severe decreases in respiratory flux may present with the greatest decreases in respiratory complex expression That said, it is currently unknown which, if any, of the hundreds of subunits that comprise the respiratory system would be most predictive of overall biochemical conductance. Correlations between respiratory conductance and protein abundance were expected to indicate potential biomarkers of respiratory insufficiency related to compromised mtDNA fidelity
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