Abstract 331: Impact of Acetylated Cyclophilin D on the Mitochondrial Permeability Transition Pore
- Resource Type
- Authors
- Jacob Perkins; Ronak A Sardari; George A. Porter; Gisela Beutner
- Source
- Circulation Research. 127
- Subject
- Mitochondrial permeability transition pore
Physiology
Chemistry
Acetylation
Biophysics
Cardiology and Cardiovascular Medicine
Cyclophilin D
- Language
- ISSN
- 1524-4571
0009-7330
Background: The mitochondrial matrix protein cyclophilin D (CypD) is a key regulator of mitochondrial function. CypD controls electron transport chain activity and ATP synthesis by regulating the permeability transition pore (PTP). The activity of CypD is regulated by several post-translational modifications including acetylation of lysine 166 in the mouse. Objective: To investigate how acetylation at lysine 166 of CypD specifically in the heart modifies its ability to regulate the PTP and the ATP synthase. Results: We generated a conditional cardiac knock-in mouse model where lysine 166 has been mutated into glutamine (CypD K166Q ) to mimic permanent acetylation of CypD. The mice were either +/+, +/- or -/- for the expression of native CypD. Results show that mitochondrial oxygen consumption was not affected by the expression of CypD K166Q . The calcium retention capacity (CRC) was measured with Arsenazo III and decreased significantly when CypD K166Q was expressed. The CypD inhibitor cyclosporine A significantly increased the CRC in WT mice. However, cyclosporine A was did not inhibit CypD in the hearts of mice expressing only CypD K166Q or in addition to wild-type CypD. The ability of the ATP synthase to create dimers or oligomers was assessed by western blotting and the hydrolysis of ATP in in-gel assays and shows that expression of CypD K166Q decreased the assembly of the ATP synthase into dimers or oligomers. Conclusions: Our data show that the expression of CypD K166Q increases the sensitivity of PTP opening to calcium and limits the assembly of ATP synthase into oligomers.