Abstract 11029: Bioenergetic Independent Stress Signaling in the Heart Due to Mitochondrial Protein Import Stress

Mitochondrial diseases are some of the most common genetically inherited disorders, yet the prognosis for affected patients has not drastically improved in recent years. Most therapies are supportive as the underlying biochemical derangements in these diseases are incompletely understood. Mitochondrial functions rely on the import of nuclear-encoded proteins, and it has recently been appreciated that defective import of mitochondrial proteins can result in the cytosolic accumulation of these preproteins. The accumulation of these preproteins results in cellular toxicity independently of any changes to the mitochondrial bioenergetic function, raising the possibility that mitochondrial protein import stress may be a yet uncharacterized pathway that links mitochondrial dysfunction with pathology. Here, we model this cytosolic mitochondrial precursor overaccumulation stress (mPOS) in mice through overexpression of the inner mitochondrial membrane protein Adenine Nucleotide Translocase 1 (ANT1). The goal of this study is to determine whether ANT1 can induce mPOS and tissue remodeling prior to the onset of cardiac bioenergetic defects. Using isolated cardiac mitochondria from these mice, we detected a moderate decrease in the levels of Complex I, II ,and IV. By measuring oxygen consumption in these mitochondria from 2-month-old animals, we found only a mild reduction in complex II based state 3 and 4 respirations. No change in complex I-based state 3 and 4 respirations was observed. Using RNAseq and western blot analysis, we find the robust activation of the integrated stress response (ISR). Transcriptomic data further demonstrates a strong upregulation of transcripts involved with 1-carbon metabolism, the amino acid starvation response, and proteolysis. Using echocardiographic evaluation of heart function on anesthetized mice at 6 months old, we find no significant alteration in systolic function. Together these data support the idea that mPOS may be a potent trigger of the ISR in a bioenergetics-independent manner. Whether activation of the ISR can alter cardiac function later in life is being evaluated.