Role of the creatine/phosphocreatine system in the regulation of mitochondrial respiration

Saks, Valdur; Kongas, Olav; Vendelin, Marko; Kay, Laurence

doi:10.1046/j.1365-201x.2000.00715.x

Cited by 80 publications

(74 citation statements)

References 22 publications

(13 reference statements)

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“…For example, the widely used model of Korzeniewski and Zoladz [4][5][6] invokes an empirical linear relationship between the difference in pH across the mitochondrial inner membrane (matrix pH minus cytosol pH) and the magnitude of inner membrane potential. While the Korzeniewski model has been validated and verified based on a number of studies and is widely applied [7][8][9], the central empirical relationship between electrostatic potential and pH difference is not expected to apply under all conditions. For example, in the extensive study of isolated cardiac mitochondria published by Bose et al [10], this relationship is not obeyed.…”

Section: Introductionmentioning

confidence: 99%

A Biophysical Model of the Mitochondrial Respiratory System and Oxidative Phosphorylation

Beard¹

2005

PLoS Comp Biol

106

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A computational model for the mitochondrial respiratory chain that appropriately balances mass, charge, and free energy transduction is introduced and analyzed based on a previously published set of data measured on isolated cardiac mitochondria. The basic components included in the model are the reactions at complexes I, III, and IV of the electron transport system, ATP synthesis at F 1 F 0 ATPase, substrate transporters including adenine nucleotide translocase and the phosphate-hydrogen co-transporter, and cation fluxes across the inner membrane including fluxes through the K þ /H þ antiporter and passive H þ and K þ permeation. Estimation of 16 adjustable parameter values is based on fitting model simulations to nine independent data curves. The identified model is further validated by comparison to additional datasets measured from mitochondria isolated from rat heart and liver and observed at low oxygen concentration. To obtain reasonable fits to the available data, it is necessary to incorporate inorganic-phosphatedependent activation of the dehydrogenase activity and the electron transport system. Specifically, it is shown that a model incorporating phosphate-dependent activation of complex III is able to reasonably reproduce the observed data. The resulting validated and verified model provides a foundation for building larger and more complex systems models and investigating complex physiological and pathophysiological interactions in cardiac energetics.

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Section: Introductionmentioning

confidence: 99%

A Biophysical Model of the Mitochondrial Respiratory System and Oxidative Phosphorylation

Beard¹

2005

PLoS Comp Biol

106

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“…This latter study also showed reduced activation-stimulated oxyhaemoglobin delivery to the activated area following creatine supplementation. This suggests that creatine supplementation is acting to smooth fluctuations in the blood oxygen level dependent response curve which results from brain activation (Gjedde et al 1999;Madsen et al 1999), possibly by altering rates of ATP synthesis in the mitochondrion through the mitochondrial creatine kinase-adenine nucleotide translocase-porin complex (Wallimann et al 1992;Saks et al 2000). Most recently, deletion of cytosolic brain-type creatine kinase in mice was shown to result in slower learning of a spatial task and diminished open-field habituation as well as increased intra-and infra-pyramidal hippocampal mossy fibre area suggesting that the creatine-creatine kinase network is also involved in brain plasticity in addition to metabolism ( Jost et al 2002).…”

Section: Discussionmentioning

confidence: 99%

Oral creatine monohydrate supplementation improves brain performance: a double–blind, placebo–controlled, cross–over trial

Rae

Digney

McEwan

et al. 2003

Proc. R. Soc. Lond. B

206

153

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Creatine supplementation is in widespread use to enhance sports-fitness performance, and has been trialled successfully in the treatment of neurological, neuromuscular and atherosclerotic disease. Creatine plays a pivotal role in brain energy homeostasis, being a temporal and spatial buffer for cytosolic and mitochondrial pools of the cellular energy currency, adenosine triphosphate and its regulator, adenosine diphosphate. In this work, we tested the hypothesis that oral creatine supplementation (5 g d 2 1 for six weeks) would enhance intelligence test scores and working memory performance in 45 young adult, vegetarian subjects in a double-blind, placebo-controlled, cross-over design. Creatine supplementation had a significant positive effect ( p , 0.0001) on both working memory (backward digit span) and intelligence (Raven's Advanced Progressive Matrices), both tasks that require speed of processing. These findings underline a dynamic and significant role of brain energy capacity in influencing brain performance.

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“…The mechanism of control of oxidative phosphorylation is through feedback of substrates for ATP synthesis. No additional regulatory mechanisms, such as feed-forward control of certain enzymes via cytosolic calcium levels (9) or functional coupling between mitochondrial creatine kinase and ANT (23,26,27), are necessary to explain the majority of the observed data. In addition, the impact of specific protein deficiencies on the relationship between oxidative phosphorylation and cytoplasmic ADP and P i is successfully explained by making the appropriate modifications to the mitochondrial enzymes altered in the diseases.…”

mentioning

confidence: 99%

“…Although the central component of the model-mitochondrial oxidative phosphorylation-is based on a mitochondrial model previously developed to match data on isolated mitochondria from rat heart, the integrated model matches a rich set of data on in vivo phosphate compounds from human skeletal muscle in healthy and complex I deficient individuals. The model also produces reasonable predictions for the ANT deficient subject, although the data available for comparison are sparse.The analysis predicts that the rate of oxidative phosphorylation is primarily regulated through concentrations of the substrates for ATP synthesis (ADP and P i ), since no additional control mechanisms, such as feed-forward control of certain enzymes via cytosolic calcium levels (9) and functional coupling between mitochondrial creatine kinase and ANT (23,26,27) that have been proposed to operate in the heart, were incorporated into the model. The current analysis does not rule out the possibility that ancillary control mechanisms are active in skeletal muscle (16,28); however, it shows that major contributions of such mechanisms to the overall regulation of the mitochondrial ATP synthetic pathway are not necessary to explain the thrust of the observed data.…”

mentioning

confidence: 99%

Oxidative ATP synthesis in skeletal muscle is controlled by substrate feedback

Wu¹,

Jeneson²,

Beard³

2007

American Journal of Physiology-Cell Physiology

108

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Data from 31 P-nuclear magnetic resonance spectroscopy of human forearm flexor muscle were analyzed based on a previously developed model of mitochondrial oxidative phosphorylation (PLoS Comp Bio 1: e36, 2005) to test the hypothesis that substrate level (concentrations of ADP and inorganic phosphate) represents the primary signal governing the rate of mitochondrial ATP synthesis and maintaining the cellular ATP hydrolysis potential in skeletal muscle. Model-based predictions of cytoplasmic concentrations of phosphate metabolites (ATP, ADP, and Pi) matched data obtained from 20 healthy volunteers and indicated that as work rate is varied from rest to submaximal exercise commensurate increases in the rate of mitochondrial ATP synthesis are effected by changes in concentrations of available ADP and Pi. Additional data from patients with a defect of complex I of the respiratory chain and a patient with a deficiency in the mitochondrial adenine nucleotide translocase were also predicted the by the model by making the appropriate adjustments to the activities of the affected proteins associates with the defects, providing both further validation of the biophysical model of the control of oxidative phosphorylation and insight into the impact of these diseases on the ability of the cell to maintain its energetic state. computational model; mitochondria; cellular energetics; oxidative phosphorylation; 31 P-NMR spectroscopy MITOCHONDRIAL OXIDATIVE ADP phosphorylation is the primary source of ATP in skeletal muscle during aerobic exercise. Thus, to maintain the free energy state of the cytoplasmic phosphoenergetic compounds ATP, ADP, and P i , oxidative phosphorylation is modulated to match the rate of ATP utilization during exercise. It has recently been shown through computational model-based analysis of data obtained from 31 P-NMR spectroscopy of working in vivo dog hearts that the primary control mechanism operating in cardiomyocytes is feedback of substrate concentrations for ATP synthesis (5). In other words, changes in the concentrations of the products generated by the utilization of ATP in the cell, ADP and P i , effect changes in the rate at which mitochondria utilize those products to resynthesize ATP (5).Here the question of whether this same mechanism can explain the observed data on the control of oxidative metabolism in skeletal muscle is investigated. Previous analyses of 31 P-NMR spectroscopy ( 31 P-MRS) data on energy balance in exercising skeletal muscle have mainly focused on testing ADP feedback control of mitochondrial ATP synthesis using black box descriptions of the mitochondrial ATP synthetic pathway (8, 14 -16, 28), P i acceptor control (7), and thermodynamic control involving quasi-linear relations between cytoplasmic Gibbs free energy of ATP hydrolysis and mitochondrial ATP synthesis flux (13,18, 31). Yet, to date, these 31 P-MRS data have not been adequately explained based on a detailed mechanistic model of oxidative phosphorylation and cellular energetics.To analyze and interpret data from s...

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Role of the creatine/phosphocreatine system in the regulation of mitochondrial respiration

Cited by 80 publications

References 22 publications

A Biophysical Model of the Mitochondrial Respiratory System and Oxidative Phosphorylation

A Biophysical Model of the Mitochondrial Respiratory System and Oxidative Phosphorylation

Oral creatine monohydrate supplementation improves brain performance: a double–blind, placebo–controlled, cross–over trial

Oxidative ATP synthesis in skeletal muscle is controlled by substrate feedback

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