Aim: To determine whether endurance training can counterbalance the negative effects of hypoxia on itochondrial phosphorylation and expression of the long chain mitochondrial fatty acid transporter muscle carnitine palmitoyl transferase 1 (mCPT-1). Methods: Male Wistar rats were exposed either to hypobaric hypoxia (at a simulated altitude of 4000 m, PIO2 90 mmHg) or to normoxia (sea level) for 5 weeks. In each environment, rats were randomly assigned to two groups. The trained group went through a 5-week endurance training programme. The control group remained sedentary for the same time period. Muscle fatty acid oxidation capacity was evaluated after the 5-week period on isolated mitochondria prepared from quadriceps muscles with the use of palmitoylcarnitine or pamitoylCoA + carnitine. Results: Chronic hypoxia decreased basal (V0, )31% with pamitoyl- CoA + carnitine and )21% with palmitoylcarnitine, P < 0.05) and maximal (Vmax, )31% with pamitoylCoA + carnitine, P < 0.05) respiration rates, hydroxyacylCoA dehydrogenase activity ()48%, P < 0.05), mCPT-1 activity index ()34%, P < 0.05) and mCPT-1 protein content ()34%, P < 0.05). Five weeks of endurance training in hypoxia brought V0, mCPT-1 activity index and mCPT-1 protein content values back to sedentary normoxic levels. Moreover, in the group trained in hypoxia, Vmax reached a higher level than in the group that maintained a sedentary lifestyle in normoxia (24.2 nmol O2/ min/mg for hypoxic training vs. 19.9 nmol O2/min/mg for normoxic sedentarity, P < 0.05). Conclusion: Endurance training can attenuate chronic hypoxia-induced impairments in mitochondrial fatty acid oxidation. This training effect seems mostly mediated by mCPT-1 activity rather than by mCPT-1 content.