RATIONALE: Mitochondrial [Ca(2+)] ([Ca(2+)](mito)) regulates mitochondrial energy production, provides transient Ca(2+) buffering under stress, and can be involved in cell death. Mitochondria are near the sarcoplasmic reticulum (SR) in cardiac myocytes, and evidence for crosstalk exists. However, quantitative measurements of [Ca(2+)](mito) are limited, and spatial [Ca(2+)](mito) gradients have not been directly measured. OBJECTIVE: To directly measure local [Ca(2+)](mito) during normal SR Ca release in intact myocytes, and evaluate potential subsarcomeric spatial [Ca(2+)](mito) gradients. METHODS AND RESULTS: Using the mitochondrially targeted inverse pericam indicator Mitycam, calibrated in situ, we directly measured [Ca(2+)](mito) during SR Ca(2+) release in intact rabbit ventricular myocytes by confocal microscopy. During steady state pacing, Δ[Ca(2+)](mito) amplitude was 29±3 nmol/L, rising rapidly (similar to cytosolic free [Ca(2+)]) but declining much more slowly. Taking advantage of the structural periodicity of cardiac sarcomeres, we found that [Ca(2+)](mito) near SR Ca(2+) release sites (Z-line) versus mid-sarcomere (M-line) reached a high peak amplitude (37±4 versus 26±4 nmol/L, respectively P<0.05) which occurred earlier in time. This difference was attributed to ends of mitochondria being physically closer to SR Ca(2+) release sites, because the mitochondrial Ca(2+) uniporter was homogeneously distributed, and elevated [Ca(2+)] applied laterally did not produce longitudinal [Ca(2+)](mito) gradients. CONCLUSIONS: We developed methods to measure spatiotemporal [Ca(2+)](mito) gradients quantitatively during excitation-contraction coupling. The amplitude and kinetics of [Ca(2+)](mito) transients differ significantly from those in the cytosol and are respectively higher and faster near the Z-line versus M-line. This approach will help clarify SR-mitochondrial Ca(2+) signaling.
RATIONALE: Mitochondrial [Ca(2+)] ([Ca(2+)](mito)) regulates mitochondrial energy production, provides transient Ca(2+) buffering under stress, and can be involved in cell death. Mitochondria are near the sarcoplasmic reticulum (SR) in cardiac myocytes, and evidence for crosstalk exists. However, quantitative measurements of [Ca(2+)](mito) are limited, and spatial [Ca(2+)](mito) gradients have not been directly measured. OBJECTIVE: To directly measure local [Ca(2+)](mito) during normal SR Ca release in intact myocytes, and evaluate potential subsarcomeric spatial [Ca(2+)](mito) gradients. METHODS AND RESULTS: Using the mitochondrially targeted inverse pericam indicator Mitycam, calibrated in situ, we directly measured [Ca(2+)](mito) during SR Ca(2+) release in intact rabbit ventricular myocytes by confocal microscopy. During steady state pacing, Δ[Ca(2+)](mito) amplitude was 29±3 nmol/L, rising rapidly (similar to cytosolic free [Ca(2+)]) but declining much more slowly. Taking advantage of the structural periodicity of cardiac sarcomeres, we found that [Ca(2+)](mito) near SR Ca(2+) release sites (Z-line) versus mid-sarcomere (M-line) reached a high peak amplitude (37±4 versus 26±4 nmol/L, respectively P<0.05) which occurred earlier in time. This difference was attributed to ends of mitochondria being physically closer to SR Ca(2+) release sites, because the mitochondrial Ca(2+) uniporter was homogeneously distributed, and elevated [Ca(2+)] applied laterally did not produce longitudinal [Ca(2+)](mito) gradients. CONCLUSIONS: We developed methods to measure spatiotemporal [Ca(2+)](mito) gradients quantitatively during excitation-contraction coupling. The amplitude and kinetics of [Ca(2+)](mito) transients differ significantly from those in the cytosol and are respectively higher and faster near the Z-line versus M-line. This approach will help clarify SR-mitochondrial Ca(2+) signaling.
Authors: Simona Boncompagni; Ann E Rossi; Massimo Micaroni; Galina V Beznoussenko; Roman S Polishchuk; Robert T Dirksen; Feliciano Protasi Journal: Mol Biol Cell Date: 2008-11-26 Impact factor: 4.138
Authors: Christoph Maack; Sonia Cortassa; Miguel A Aon; Anand N Ganesan; Ting Liu; Brian O'Rourke Journal: Circ Res Date: 2006-06-15 Impact factor: 17.367
Authors: Eckard Picht; Aleksey V Zima; Thomas R Shannon; Alexis M Duncan; Lothar A Blatter; Donald M Bers Journal: Circ Res Date: 2011-02-10 Impact factor: 17.367
Authors: Camila Lopez-Crisosto; Christian Pennanen; Cesar Vasquez-Trincado; Pablo E Morales; Roberto Bravo-Sagua; Andrew F G Quest; Mario Chiong; Sergio Lavandero Journal: Nat Rev Cardiol Date: 2017-03-09 Impact factor: 32.419