Jimmy Matas scite author profile

Loss of neural input to skeletal muscle fibres induces atrophy and degeneration with evidence of mitochondria-mediated cell death. However, the effect of denervation on the permeability transition pore (PTP), a mitochondrial protein complex implicated in cell death, is uncertain. In the present study, the impact of 21 days of denervation on the sensitivity of the PTP to Ca 2+ -induced opening was studied in isolated muscle mitochondria. Muscle denervation increased the sensitivity to Ca 2+ -induced opening of the PTP, as indicated by a significant decrease in calcium retention capacity (CRC: 111 ± 12 versus 475 ± 33 nmol (mg protein) -1 for denervated and sham, respectively). This phenomenon was partly attributable to in vivo mitochondrial and whole muscle Ca 2+ overload. Cyclosporin A, which inhibits PTP opening by binding to cyclophilin D (CypD), was significantly more potent in mitochondria from denervated muscle and restored CRC to the level observed in mitochondria from sham-operated muscles. In contrast, the CypD independent inhibitor trifluoperazine was equally effective at inhibiting PTP opening in sham and denervated animals and did not correct the difference in CRC between groups. This phenomenon was associated with a significant increase in the content of the PTP regulating protein CypD relative to several mitochondrial marker proteins. Together, these results indicate that Ca 2+ overload in vivo and an altered expression of CypD could predispose mitochondria to permeability transition in denervated muscles.

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Compensated volume overload increases the vulnerability of heart mitochondria without affecting their functions in the absence of stress

Marcil

Ascah

Matas

et al. 2006

Journal of Molecular and Cellular Cardiology

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Increased expression and intramitochondrial translocation of cyclophilin-D associates with increased vulnerability of the permeability transition pore to stress-induced opening during compensated ventricular hypertrophy

Matas

Young

Bourcier-Lucas

et al. 2009

Journal of Molecular and Cellular Cardiology

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Early predictors of cardiac decompensation in experimental volume overload

et al. 2010

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In humans, volume overload (VOL) increases the risk of sudden cardiac death, but there is also important inter-individual variability, presumably because of differences in genetic backgrounds. Although VOL has rapid effects on myocardial properties, it is not known to which extent the severity of these early responses correlate with the effect of sustained VOL on mortality. In order to test this question, we induced VOL in male rats from two genetically distinct strains [i.e., Sprague-Dawley (SD) and Wistar Kyoto-derived Hyperactive (WKHA) rats] by creating a surgical aorto-caval fistula (ACF). Only 36% of SD rats remained alive after 39 weeks of ACF, in contrast to 82% of the operated WKHA rats. We also monitored myocardial hemodynamic function, mitochondrial properties, left ventricular (LV) morphology and LV wall diastolic properties at different times ranging from 2 to 12 weeks after either ACF or sham surgery. ACF had a rapid impact on the LV walls of both rat strains, but the only variables that were affected to a greater extent in the mortality-prone SD strain were normalized LV weight, LV cavity area, and myocardial wall stiffness. In contrast, there were only marginal strain-related differences in the way ACF affected hemodynamic and mitochondrial functions. Thus, while early morphologic responses of LV walls to ACF (along with their downstream consequences on myocardial diastolic wall stress) correlated well with strain-dependent differences in late mortality, other functional changes showed no predictive effects. Close monitoring of early changes in cardiac geometry (as well as new methods to analyze myocardial diastolic strain) might, therefore, be helpful to further improve risk stratification in humans with volume overload cardiopathies.

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Mössbauer spectra of alkaline ferrocyanides

Matas¹,

Zemčík²

1965

Physics Letters

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Jimmy Matas

Muscle denervation promotes opening of the permeability transition pore and increases the expression of cyclophilin D

Compensated volume overload increases the vulnerability of heart mitochondria without affecting their functions in the absence of stress

Increased expression and intramitochondrial translocation of cyclophilin-D associates with increased vulnerability of the permeability transition pore to stress-induced opening during compensated ventricular hypertrophy

Early predictors of cardiac decompensation in experimental volume overload

Mössbauer spectra of alkaline ferrocyanides

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