Zoll 2002 J Physiol

» PMID: 12181291 Open Access

Zoll J, Sanchez H, N'Guessan B, Ribera F, Lampert E, Bigard X, Surrurier B, Fortin D, Geny B, Veksler V, Ventura-Clapier R, Mettauer B (2002) J Physiol

Abstract: This study explores the importance of creatine kinase (CK) in the regulation of muscle mitochondrial respiration in human subjects depending on their level of physical activity. Volunteers were classified as sedentary, active or athletic according to the total activity index as determined by the Baecke questionnaire in combination with maximal oxygen uptake values (peak V(O₂), expressed in ml min(-1) kg(-1)). All volunteers underwent a cyclo-ergometric incremental exercise test to estimate their peak V(O₂) and V(O₂) at the ventilatory threshold (VT). Muscle biopsy samples were taken from the vastus lateralis and mitochondrial respiration was evaluated in an oxygraph cell on saponin permeabilised muscle fibres in the absence (V(0)) or in the presence (V(max)) of saturating [ADP]. While V(0) was similar, V(max) differed among groups (sedentary, 3.7 +/- 0.3, active, 5.9 +/- 0.9 and athletic, 7.9 +/- 0.5 micromol O₂ min(-1) (g dry weight)(-1)). V(max) was correlated with peak V(O₂) (P < 0.01, r = 0.63) and with V(T) (P < 0.01, r = 0.57). There was a significantly greater degree of coupling between oxidation and phosphorylation (V(max)/V(0)) in the athletic individuals. The mitochondrial K(m) for ADP was significantly higher in athletic subjects (P < 0.01). Mitochondrial CK (mi-CK) activation by addition of creatine induced a marked decrease in K(m) in athletic individuals only, indicative of an efficient coupling of mi-CK to ADP rephosphorylation in the athletic subjects only. It is suggested that increasing aerobic performance requires an enhancement of both muscle oxidative capacity and mechanisms of respiratory control, attesting to the importance of temporal co-ordination of energy fluxes by CK for higher efficacy.

• Bioblast editor: Gnaiger E

MitoEAGLE V_O2max/BME database

• Human vastus lateralis
• 2 females & 11 males
• 40.5 years
• Athletic; involved in a training programme with endurance sessions on a regular basis
• H = 1.74 m
• M = 68.2 kg
• BME = 0.11
• BMI = 22.5 kg·m^-2
• V_O2max/M = 53.9 mL·min^-1·kg^-1 (= V_O2peak/M/0.93)
• Permeabilized muscle fibres; 22 °C; GM_P; m_d; conversions: Gnaiger 2009 Int J Biochem Cell Biol
• J_O2,P(NS) = 145.8 µmol·s^-1·kg^-1 wet muscle mass (37 °C)

• J_O2,P(GM) = 106.4 µmol·s^-1·kg^-1 wet muscle mass (37 °C)
• J_O2,P(NS) = J_O2,P(GM)/0.73
• Fiber wet mass to dry mass ratio = 3.5 (N'Guessan 2004 Mol Cell Biochem)

• Human vastus lateralis
• 2 females & 6 males
• 45.6 years
• Active; performed physical activity regularly for professional or recreational purposes, but followed no regular training programme
• H = 1.73 m
• M = 78.1 kg
• BME = 0.29
• BMI = 26.1 kg·m^-2
• V_O2max/M = 39.0 mL·min^-1·kg^-1 (= V_O2peak/M/0.93)
• Permeabilized muscle fibres; 22 °C; GM_P; m_d; conversions: Gnaiger 2009 Int J Biochem Cell Biol
• J_O2,P(NS) = 108.9 µmol·s^-1·kg^-1 wet muscle mass (37 °C)

• J_O2,P(GM) = 79.5 µmol·s^-1·kg^-1 wet muscle mass (37 °C)
• J_O2,P(NS) = J_O2,P(GM)/0.73
• Fiber wet mass to dry mass ratio = 3.5 (N'Guessan 2004 Mol Cell Biochem)

• Human vastus lateralis
• 8 males
• 46.7 years
• Sedentary, no regular professinal or recreational physical activity
• H = 1.78 m
• M = 84.4 kg
• BME = 0.28
• BMI = 26.6 kg·m^-2
• V_O2max/M = 30.6 mL·min^-1·kg^-1 (= V_O2peak/M/0.93)
• Permeabilized muscle fibres; 22 °C; GM_P; m_d; conversions: Gnaiger 2009 Int J Biochem Cell Biol
• J_O2,P(NS) = 68.3 µmol·s^-1·kg^-1 wet muscle mass (37 °C)

• J_O2,P(GM) = 49.8 µmol·s^-1·kg^-1 wet muscle mass (37 °C)
• J_O2,P(NS) = J_O2,P(GM)/0.73
• Fiber wet mass to dry mass ratio = 3.5 (N'Guessan 2004 Mol Cell Biochem)

References: BME and VO2max

» VO2max

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Labels: MiParea: Respiration, Exercise physiology;nutrition;life style 

Organism: Human  Tissue;cell: Skeletal muscle  Preparation: Permeabilized tissue 

Coupling state: LEAK, OXPHOS  Pathway: N 

MitoEAGLE BME, BMI, VO2max, BME