Stimulatory Effects of Calcium on Respiration and NAD(P)H Synthesis in Intact Rat Heart Mitochondria Utilizing Physiological Substrates Cannot Explain Respiratory Control in Vivo

Vinnakota, Kalyan C.; Dash, Ranjan K.; Beard, Daniel A.

doi:10.1074/jbc.m111.242529

Cited by 23 publications

(46 citation statements)

References 23 publications

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“…Excess [Ca 2ϩ ]m, however, opens the permeability transition pore (40, 54), a key factor in apoptosis during ischemiareperfusion injury (12)(13)(14)(15)(16)(17). These reports, together with our findings that LTHA enhances Ca 2ϩ stress-endurance and decreases Ca 2ϩ sensitivity in cardiomyocytes (52,67), lend further support to the hypothesis that the adaptive features of the mitochondria evolve with heat acclimation and are important for HACT by enhancing respiratory performance during stress.…”

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confidence: 72%

Mitochondrial performance in heat acclimation—a lesson from ischemia/reperfusion and calcium overload insults in the heart

Assayag

Saada

Gerstenblith

et al. 2012

American Journal of Physiology-Regulatory, Integrative and Comp

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Longterm heat acclimation (LTHA; 30 days, 34°C) causes phenotypic adaptations that render protection against ischemic/reperfusion insult (I/R, 30 min global ischemia and 40 min reperfusion) via heat acclimation-mediated cross-tolerance (HACT) mechanisms. Shortterm acclimation (STHA, 2 days, 34°C), in contrast, is characterized by cellular perturbations, leading to increased susceptibility to insults. Here, we tested the hypothesis that enhanced mitochondrial respiratory function is part of the acclimatory repertoire and that the 30-day regimen is required for protection via HACT. We subjected isolated hearts and mitochondria from controls (C), STHA, or LTHA rats to I/R, hypoxia/reoxygenation, or Ca 2ϩ overload insults. Mitochondrial function was assessed by measuring O2 consumption, membrane potential (⌬⌿m), mitochondrial Ca 2ϩ ([Ca 2ϩ ]m), ATP production, respiratory chain complex activities, and molecular markers of mitochondrial biogenesis. Our results, combining physiological and biochemical parameters, confirmed that mitochondria from LTHA rats subjected to insults, in contrast to C, preserve respiratory functions (e.g., upon I/R, C mitochondria fueled by glutamate-malate, demonstrated decreases of 81%, 13%, 25%, and 50% in O2/P ratio, ATP production, ⌬⌿m, and complex I activity, respectively, whereas the corresponding LTHA parameters remained unchanged). STHA mitochondria maintained ⌬⌿m but did not preserve ATP production. LTHA [Ca 2ϩ ]m was significantly higher than that of C and STHA and was not affected by the hypoxia/reoxygenation protocol compared with C. Enhanced mitochondrial biogenesis markers, switched-on during STHA coincidentally with enhanced membrane integrity (⌬⌿m), were insufficient to confer intact respiratory function upon insult. LTHA was required for respiratory complex I adaptation and HACT. Umschwief et al. (65) proved that the mitochondria, via heat acclimation-mediated cross-tolerance (HACT) mechanisms, in which heat acclimation confers protection against stressors of a different nature, attenuated apoptosis during ischemia/reperfusion (I/R) insult in the heart and following traumatic brain injury. Assayag et al. (3) also demonstrated that basal levels of cytochrome c, an essential electron carrier that transfers electrons from complex III to the COX complex, decreased in the cardiac mitochondria of heat-acclimated rats, whereas heat stress induced a marked elevation of this protein.The former fits with Seebacher's COX activity in warm acclimated reptiles (59). The mitochondrial Bcl XL protein was elevated under both basal-normothermic and heat-stress conditions, implying adaptive properties in the mitochondriaimporting complexes and synthesis systems (2) and marked the mitochondria as essential players in thermotolerance, as well as in HACT. Assayag et al. (3) demonstrated that the adaptive features of the outer mitochondrial membrane (such as an elevated Bcl XL /Bad ratio) are already found after 2 days of heat acclimation, namely short-term heat acclimation (STHA), whereas...

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confidence: 72%

Mitochondrial performance in heat acclimation—a lesson from ischemia/reperfusion and calcium overload insults in the heart

Assayag

Saada

Gerstenblith

et al. 2012

American Journal of Physiology-Regulatory, Integrative and Comp

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“…However, the importance of [Ca 2+ ] m on mitochondrial dehydrogenase activities is strongly dependent on the substrate used. For example, it was reported that pyruvate dehydrogenase is activated at almost 100%, regardless of the [Ca 2+ ] m , and that α-ketoglutarate dehydrogenase is a more physiologically relevant target of Ca 2+ regulation (Vinnakota et al 2011, Wan et al 1989). This means that the greatest effect of Ca 2+ on bioenergetics would be with α-ketoglutarate as the substrate.…”

Section: Discussionmentioning

confidence: 99%

Extra-matrix Mg2+ limits Ca2+ uptake and modulates Ca2+ uptake–independent respiration and redox state in cardiac isolated mitochondria

Boelens

Pradhan

Blomeyer

et al. 2013

J Bioenerg Biomembr

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Cardiac mitochondrial matrix (m) free Ca2+ ([Ca2+]m) increases primarily by Ca2+ uptake through the Ca2+ uniporter (CU). Ca2+ uptake via the CU is attenuated by extra-matrix (e) Mg2+ ([Mg2+]e). How [Ca2+]m is dynamically modulated by interacting physiological levels of [Ca2+]e and [Mg2+]e and how this interaction alters bioenergetics is not well understood. We postulated that as [Mg2+]e modulates Ca2+ uptake via the CU, it also alters bioenergetics in a matrix Ca2+–induced and matrix Ca2+–independent manner. To test this, we measured changes in [Ca2+]e, [Ca2+]m, [Mg2+]e and [Mg2+]m spectrofluorometrically in guinea pig cardiac mitochondria in response to added CaCl2 (0–0.6 mM; 1 mM EGTA buffer) with/without added MgCl2 (0–2 mM). In parallel, we assessed effects of added CaCl2 and MgCl2 on NADH, membrane potential (ΔΨm), and respiration. We found that ≥0.125 mM MgCl2 significantly attenuated CU-mediated Ca2+ uptake and [Ca2+]m. Incremental [Mg2+]e did not reduce initial Ca2+uptake but attenuated the subsequent slower Ca2+ uptake, so that [Ca2+]m remained unaltered over time. Adding CaCl2 without MgCl2 to attain a [Ca2+]m from 46 to 221 nM enhanced state 3 NADH oxidation and increased respiration by 15%; up to 868 nM [Ca2+]m did not additionally enhance NADH oxidation or respiration. Adding MgCl2 did not increase [Mg2+]m but it altered bioenergetics by its direct effect to decrease Ca2+ uptake. However, at a given [Ca2+]m, state 3 respiration was incrementally attenuated, and state 4 respiration enhanced, by higher [Mg2+]e. Thus, [Mg2+]e without a change in [Mg2+]m can modulate bioenergetics independently of CU-mediated Ca2+ transport.

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“…First, 10 mM of substrate (NaPM or KPM) to energize mitochondria may saturate the ADP-independent TCA cycle flux. In a recent study [54], it was reported that to observe an effect of increased Ca 2+ to stimulate state 3 NADH production and respiration, a low substrate concentration is necessary. Second, the substrate glutamate +malate provides a greater NADH response to increasing extra-matrix [Ca 2+ ].…”

Section: Discussionmentioning

confidence: 99%

Enhanced charge-independent mitochondrial free Ca2+ and attenuated ADP-induced NADH oxidation by isoflurane: Implications for cardioprotection

Agarwal

Camara

Stowe

et al. 2012

Biochimica et Biophysica Acta (BBA) - Bioenergetics

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Modulation of mitochondrial free Ca2+ ([Ca2+]m) is implicated as one of the possible upstream factors that initiates anesthetic-mediated cardioprotection against ischemia-reperfusion (IR) injury. To unravel possible mechanisms by which volatile anesthetics modulate [Ca2+]m and mitochondrial bioenergetics, with implications for cardioprotection, experiments were conducted to spectrofluorometrically measure concentration-dependent effects of isoflurane (0.5, 1, 1.5, 2 mM) on the magnitudes and time-courses of [Ca2+]m and mitochondrial redox state (NADH), membrane potential (ΔΨm), respiration, and matrix volume. Isolated mitochondria from rat hearts were energized with 10 mM Na+- or K+-pyruvate/malate (NaPM or KPM) or Na+-succinate (NaSuc) followed by additions of isoflurane, 0.5 mM CaCl2 (≈200 nM free Ca2+ with 1 mM EGTA buffer), and 250 mM ADP. Isoflurane stepwise: (a) increased [Ca2+]m in state 2 with NaPM, but not with KPM substrate, despite an isoflurane-induced slight fall in ΔΨm and a mild matrix expansion, and (b) decreased NADH oxidation, respiration, ΔΨm, and matrix volume in state 3, while prolonging the duration of state 3 NADH oxidation, respiration, ΔΨm, and matrix contraction with PM substrates. These findings suggest that isoflurane's effects are mediated in part at the mitochondrial level: (1) to enhance the net rate of state 2 Ca2+ uptake by inhibiting the Na+/Ca2+ exchanger (NCE), independent of changes in ΔΨm and matrix volume, and (2) to decrease the rates of state 3 electron transfer and ADP phosphorylation by inhibiting complex I. These direct effects of isoflurane to increase [Ca2+]m, while depressing NCE activity and oxidative phosphorylation, could underlie the mechanisms by which isoflurane provides cardioprotection against IR injury at the mitochondrial level.

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Stimulatory Effects of Calcium on Respiration and NAD(P)H Synthesis in Intact Rat Heart Mitochondria Utilizing Physiological Substrates Cannot Explain Respiratory Control in Vivo

Cited by 23 publications

References 23 publications

Mitochondrial performance in heat acclimation—a lesson from ischemia/reperfusion and calcium overload insults in the heart

Mitochondrial performance in heat acclimation—a lesson from ischemia/reperfusion and calcium overload insults in the heart

Extra-matrix Mg2+ limits Ca2+ uptake and modulates Ca2+ uptake–independent respiration and redox state in cardiac isolated mitochondria

Enhanced charge-independent mitochondrial free Ca2+ and attenuated ADP-induced NADH oxidation by isoflurane: Implications for cardioprotection

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