Cardiac high-energy phosphates adapt faster than oxygen consumption to changes in heart rate.

Eijgelshoven, M. H. J.; Beek, Hans van; Mottet, Isabelle; Nederhoff, Marcel G.J.; Echteld, C.J.A. van; Westerhof, Nicolaas

doi:10.1161/01.res.75.4.751

Cited by 29 publications

(26 citation statements)

References 44 publications

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“…[P i ] in intact heart is essentially constant (or, at best, changes little) during low-tohigh work transition [42] and equals roughly 1-3 mM [77,78] (compare also discussion in [14]). [P i ] may be significantly different for different substrates and hormones present in the perfusion medium, but is in the millimolar range [77].…”

Section: Comparison Of Different Mechanisms Of Regulation Of Oxidativmentioning

confidence: 93%

“…It seems that the (almost) perfect stability of metabolite (free ADP, PCr, P i , NADH) concentrations (changes by less than 10 %) discussed above takes place in intact heart in vivo, but not in perfused heart, where some significant changes (by 10 -300 %) in metabolite concentrations during work transitions are usually observed [77,92,93,78]. Additionally, the extent of these changes depends on respiratory substrates and hormones present in the perfusion medium [77].…”

Section: Accepted M Manuscriptmentioning

confidence: 99%

“…Next, the simulated half-transition time for PCr equals several hundreds of seconds (Fig. 5 in [98]), whereas this time equals a few seconds in perfused heart [74,78]. Finally, the VO 2 estimated from the initial rate of [PCr] decrease during transition from 0.25 Hz to 2 Hz stimulation frequency (Fig.…”

Section: Other Theoretical Studiesmentioning

confidence: 99%

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Regulation of oxidative phosphorylation through parallel activation

Korzeniewski

2007

Biophysical Chemistry

119

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When the mechanical work intensity in muscle increases, the elevated ATP consumption rate must be matched by the rate of ATP production by oxidative phosphorylation in order to avoid a quick exhaustion of ATP. The traditional mechanism of the regulation of oxidative phosphorylation, namely the negative feedback involving [ADP] and [P i ] as regulatory signals, is not sufficient to account for various kinetic properties of the system in intact skeletal muscle and heart in vivo. Theoretical studies conducted using a dynamic computer model of oxidative phosphorylation developed previously strongly suggest the so-called each-step-activation (or parallel-activation) mechanism, due to which all oxidative phosphorylation complexes are directly activated by some cytosolic factor/mechanism related to muscle contraction in parallel with the activation of ATP usage and substrate dehydrogenation by calcium ions. The present polemic article reviews and discusses the growing evidence supporting this mechanism and compares it with alternative mechanisms proposed in the literature. It is concluded that only the each-step-activation mechanism is able to explain the rich set of various experimental results used as a reference for estimating the validity and applicability of particular mechanisms.

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Section: Comparison Of Different Mechanisms Of Regulation Of Oxidativmentioning

confidence: 93%

Section: Accepted M Manuscriptmentioning

confidence: 99%

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Regulation of oxidative phosphorylation through parallel activation

Korzeniewski

2007

Biophysical Chemistry

119

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“…Whereas anaerobic glycolysis may only produce as little as 3-7% of the total ATP under aerobic conditions in ex vivo preparations (8, 17), its contribution to cellular bioenergetics may increase significantly during ischemia and hypoxia (31). In addition, ATP from glycolysis may be used in the heart early during dynamic workload changes (7), as observed previously in skeletal muscle (24).We can measure the time course of oxygen consumption (V O 2 ) in response to pacing-induced workload steps, which reflects the transcytosolic energy signaling speeds between myofibrils and ion pumps and the mitochondria in isolated rabbit hearts to match ATP synthesis to hydrolysis (7,37,38). The mitochondrial delay time (t mito ) is sensitive to altered exogenous substrate (35) and ischemia (46).…”

mentioning

confidence: 94%

“…We can measure the time course of oxygen consumption (V O 2 ) in response to pacing-induced workload steps, which reflects the transcytosolic energy signaling speeds between myofibrils and ion pumps and the mitochondria in isolated rabbit hearts to match ATP synthesis to hydrolysis (7,37,38). The mitochondrial delay time (t mito ) is sensitive to altered exogenous substrate (35) and ischemia (46).…”

mentioning

confidence: 99%

Glycolytic buffering affects cardiac bioenergetic signaling and contractile reserve similar to creatine kinase

Harrison

Wijhe²,

Groot³

et al. 2003

American Journal of Physiology-Heart and Circulatory Physiology

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buffering affects cardiac bioenergetic signaling and contractile reserve similar to creatine kinase. Am J Physiol Heart Circ Physiol 285: H883-H890, 2003. First published April 24, 2003 10.1152/ajpheart.00725.2002 and glycolysis represent important energy-buffering processes in the cardiac myocyte. Although the role of compartmentalized CK in energy transfer has been investigated intensely, similar duties for intracellular glycolysis have not been demonstrated. By measuring the response time of mitochondrial oxygen consumption to dynamic workload jumps (t mito) in isolated rabbit hearts, we studied the effect of inhibiting energetic systems (CK and/or glycolysis) on transcytosolic signal transduction that couples cytosolic ATP hydrolysis to activation of oxidative phosphorylation. Tyrode-perfused hearts were exposed to 15 min of the following: 1) 0.4 mM iodoacetamide (IA; n ϭ 6) to block CK (CK activity Ͻ3% vs. control), 2) 0.3 mM iodoacetic acid (IAA; n ϭ 5) to inhibit glycolysis (GAPDH activity Ͻ3% vs. control), or 3) vehicle (control, n ϭ 7) at 37°C. Pretreatment t mito was similar across groups at 4.3 Ϯ 0.3 s (means Ϯ SE). No change in tmito was observed in control hearts; however, in IAA-and IA-treated hearts, t mito decreased by 15 Ϯ 3% and 40 Ϯ 5%, respectively (P Ͻ 0.05 vs. control), indicating quicker energy supply-demand signaling in the absence of ADP/ATP buffering by CK or glycolysis. The faster response times in IAA and IA groups were independent of the size of the workload jump, and the increase in myocardial oxygen consumption during workload steps was unaffected by CK or glycolysis blockade. Contractile function was compromised by IAA and IA treatment versus control, with contractile reserve (defined as increase in rate-pressure product during a standard heart rate jump) reduced to 80 Ϯ 8% and 80 Ϯ 10% of baseline, respectively (P Ͻ 0.05 vs. control), and significant elevations in end-diastolic pressure, suggesting raised ADP concentration. These results demonstrate that buffering of phosphate metabolites by glycolysis in the cytosol contributes appreciably to slower mitochondrial activation and may enhance contractile efficiency during increased cardiac workloads. Glycolysis may therefore play a role similar to CK in heart muscle. glycolysis; energy transduction; mitochondria; regulation of oxidative phosphorylation THE RELATIONSHIP BETWEEN CONTRACTILE function of the myocardium and myocyte bioenergetics is centered on the generation of ATP by oxidative phosphorylation, anaerobic glycolysis, and the conversion of phosphocreatine by creatine kinase (CK). The role of CK as an energy reserve and transfer system in the heart has been intensively studied (1,27,28,30,40), focusing on the functional significance of the compartmentation of CK isozymes to the mitochondria and myofibrils (39,44) and the regulators of CK flux during conditions of altered ATP synthesis or hydrolysis (22). Moreover, changes have been observed in CK activity and levels of its substrates and products in human patients sufferi...

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Metabolic Response Times: A Generalization of Indicator Dilution Theory Applied to Cardiac O2 Consumption Transients

Beek¹

1998

Whole Organ Approaches to Cellular Metabolism

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Cardiac high-energy phosphates adapt faster than oxygen consumption to changes in heart rate.

Cited by 29 publications

References 44 publications

Regulation of oxidative phosphorylation through parallel activation

Regulation of oxidative phosphorylation through parallel activation

Glycolytic buffering affects cardiac bioenergetic signaling and contractile reserve similar to creatine kinase

Metabolic Response Times: A Generalization of Indicator Dilution Theory Applied to Cardiac O2 Consumption Transients

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