Quantification of skeletal muscle mitochondrial function by <sup>31</sup><scp>P</scp> magnetic resonance spectroscopy techniques: a quantitative review

Kemp, Graham J.; Ahmad, Rukhsar; Nicolay, Klaas; Prompers, Jeanine J.

doi:10.1111/apha.12307

Cited by 127 publications

(220 citation statements)

References 299 publications

(383 reference statements)

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“…This last assumption is critical because this approach ignores changes in cellular pH, which can inhibit oxidative phosphorylation[27], during PCr recovery by focusing on the direct measurement of [PCr] from the 31 P NMR spectra. An advantage of this strategy is that it is based on the empirical relationship between the fall in PCr and resynthesis rate[27, 28] and is not dependent on a theoretical model for control of respiration. Other models for estimating ATPmax from PCr recovery data are based on either control of mitochondrial respiration by cytoplasmic [ADP][29, 30] or the free energy of ATP hydrolysis[31].…”

Section: In Vivo Approaches For Measuring Mitochondrial Phosphorylmentioning

confidence: 99%

“…Other models for estimating ATPmax from PCr recovery data are based on either control of mitochondrial respiration by cytoplasmic [ADP][29, 30] or the free energy of ATP hydrolysis[31]. A recent review by Kemp et al[28] provides a more detailed comparison of these models for determining mitochondrial capacity from PCr recovery. In contrast to the linear model discussed above, which relies on direct measurement of [PCr] concentration from the NMR spectra, these other models require calculation of [ADP] and pH as well as knowledge of the K M for ADP, which may change under different conditions[32].…”

Section: In Vivo Approaches For Measuring Mitochondrial Phosphorylmentioning

confidence: 99%

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Evaluation of in vivo mitochondrial bioenergetics in skeletal muscle using NMR and optical methods

Campbell

Marcinek

2016

Biochimica et Biophysica Acta (BBA) - Molecular Basis of Diseas

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It is now clear that mitochondria are involved as either a cause or consequence of many chronic diseases. This central role of mitochondria is due to their position in the cell as important integrators of cellular energetics and signaling. Mitochondrial function affects many aspects of the cellular environment such as redox homeostasis and calcium signaling, which then also exert control over mitochondrial function. This complex dynamic between mitochondrial function and the cellular environment highlights the value of examining mitochondria in vivo in the intact physiological environment. This review discusses NMR and optical approaches used to measure mitochondria ATP and oxygen fluxes that provide in vivo measures of mitochondrial capacity and quality in animal and human models. Combining these in vivo measurements with more traditional ex vivo analyses can lead to new insights into the importance of the cellular environment in controlling mitochondrial dysfunction under pathological conditions. Interpretation and underlying assumptions for each technique are discussed with the goal of providing an overview of some of the most common approaches used to measure in vivo mitochondrial function encountered in the literature.

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Section: In Vivo Approaches For Measuring Mitochondrial Phosphorylmentioning

confidence: 99%

Section: In Vivo Approaches For Measuring Mitochondrial Phosphorylmentioning

confidence: 99%

Evaluation of in vivo mitochondrial bioenergetics in skeletal muscle using NMR and optical methods

Campbell

Marcinek

2016

Biochimica et Biophysica Acta (BBA) - Molecular Basis of Diseas

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“…However, one should keep in mind that the absolute initial rate of PCr resynthesis reflects the actual oxidative ATP synthesis contribution at that point, whereas the rate constant is standardly interpreted as a measure of effective mito chondrial capacity (24) for a given end-of-exercise condition (7,42). A lower rate constant might be linked to a reduced number/activity of mitochondria, an impaired vascular sup ply of 0 2 and its diffusion across the capillary wall and through the myocyte to the mitochondria (23,24). Therefore, the concomitant decrease in ATPox, l/Trecov, and Frecov PCr likely illustrates an impaired mitochondrial function as pre viously described (25).…”

Section: Discussionmentioning

confidence: 84%

Impaired Mitochondrial Function and Reduced Energy Cost as a Result of Muscle Damage

Fouré

Wegrzyk

Fur

et al. 2015

Medicine &Amp; Science in Sports &Amp; Exercise

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“…We found actually that sActRIIB-Fc treatment dramatically reduced the maximal rate of oxidative ATP synthesis (Ϫ42%), which is considered a robust and highly reproducible in vivo index of oxidative mitochondrial capacity and has been widely used in research and clinical applications (4,7,26,32). Our findings are in agreement with previous in vitro experiments conducted in wild-type mice showing that sActRIIB-Fc delivery reduces the expression of genes involved in mitochondrial oxidative phosphorylation (50,60) and decreases the level of porin, a mitochondrial membrane protein involved in the transport of ATP between mitochondrial matrix and cytosol (52).…”

Section: Discussionmentioning

confidence: 91%

Mitochondrial impairment induced by postnatal ActRIIB blockade does not alter function and energy status in exercising mouse glycolytic muscle in vivo

Béchir

Pecchi

Relizani

et al. 2016

American Journal of Physiology-Endocrinology and Metabolism

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-Because it leads to a rapid and massive muscle hypertrophy, postnatal blockade of the activin type IIB receptor (ActRIIB) is a promising therapeutic strategy for counteracting muscle wasting. However, the functional consequences remain very poorly documented in vivo. Here, we have investigated the impact of 8-wk ActRIIB blockade with soluble receptor (sActRIIB-Fc) on gastrocnemius muscle anatomy, energy metabolism, and force-generating capacity in wild-type mice, using totally noninvasive magnetic resonance imaging (MRI) and dynamic 31 P-MRS. Compared with vehicle (PBS) control, sActRIIB-Fc treatment resulted in a dramatic increase in body weight (ϩ29%) and muscle volume (ϩ58%) calculated from hindlimb MR imaging, but did not alter fiber type distribution determined via myosin heavy chain isoform analysis. In resting muscle, sActRIIB-Fc treatment induced acidosis and PCr depletion, thereby suggesting reduced tissue oxygenation. During an in vivo fatiguing exercise (6-min repeated maximal isometric contraction electrically induced at 1.7 Hz), maximal and total absolute forces were larger in sActRIIB-Fc treated animals (ϩ26 and ϩ12%, respectively), whereas specific force and fatigue resistance were lower (Ϫ30 and Ϫ37%, respectively). Treatment with sActRIIB-Fc further decreased the maximal rate of oxidative ATP synthesis (Ϫ42%) and the oxidative capacity (Ϫ34%), but did not alter the bioenergetics status in contracting muscle. Our findings demonstrate in vivo that sActRIIB-Fc treatment increases absolute force-generating capacity and reduces mitochondrial function in glycolytic gastrocnemius muscle, but this reduction does not compromise energy status during sustained activity. Overall, these data support the clinical interest of postnatal ActRIIB blockade. skeletal muscle hypertrophy; activin type IIB receptor; myostatin; force; fatigue ACTIVIN TYPE IIB RECEPTOR (ActRIIB) is a transmembrane serinethreonine kinase receptor highly expressed in mammalian skeletal muscle. It mediates signaling for myostatin (GDF8) and other members of the transforming growth factor-␤ family that are involved in the negative regulation of skeletal muscle development (16,37). Disruption of the ActRIIB signaling pathway leads to a rapid and massive increase in muscle mass resulting from fiber hypertrophy with increased myofiber protein synthesis (10, 58). In that context, several pharmacological approaches based on the postnatal ActRIIB signaling blockade have been considered for counteracting muscle wasting commonly associated to aging, neuromuscular disorders and various catabolic diseases (17,33,38). These approaches mainly include the systemic delivery of neutralizing antibodies against ActRIIB or myostatin (31, 36), and injection of a soluble recombinant form of ActRIIB (sActRIIB-Fc), which acts as a decoy receptor disrupting the interaction of endogenous ActRIIB receptor with its ligands (5,38,44).Although ActRIIB signaling blockade has been already tested in patients (30, 57) and animal models (10,44,47) suffering from dystrophi...

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Quantification of skeletal muscle mitochondrial function by ³¹P magnetic resonance spectroscopy techniques: a quantitative review

Cited by 127 publications

References 299 publications

Evaluation of in vivo mitochondrial bioenergetics in skeletal muscle using NMR and optical methods

Evaluation of in vivo mitochondrial bioenergetics in skeletal muscle using NMR and optical methods

Impaired Mitochondrial Function and Reduced Energy Cost as a Result of Muscle Damage

Mitochondrial impairment induced by postnatal ActRIIB blockade does not alter function and energy status in exercising mouse glycolytic muscle in vivo

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Quantification of skeletal muscle mitochondrial function by 31P magnetic resonance spectroscopy techniques: a quantitative review

Cited by 127 publications

References 299 publications

Evaluation of in vivo mitochondrial bioenergetics in skeletal muscle using NMR and optical methods

Evaluation of in vivo mitochondrial bioenergetics in skeletal muscle using NMR and optical methods

Impaired Mitochondrial Function and Reduced Energy Cost as a Result of Muscle Damage

Mitochondrial impairment induced by postnatal ActRIIB blockade does not alter function and energy status in exercising mouse glycolytic muscle in vivo

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Quantification of skeletal muscle mitochondrial function by ³¹P magnetic resonance spectroscopy techniques: a quantitative review