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It is not clear how mitochondrial energy production is regulated in intact tissue when energy consumption suddenly changes. Whereas mitochondrial NADH (NADHm) may regulate cellular respiration rate and energetic state, it is not clear how NADHm itself is controlled during increased work in vivo. We have varied work and Ca2+ in intact cardiac muscle while assessing NADHm using fluorescence spectroscopy. When increased work was accompanied by increasing average Ca2+c (by increasing Ca2+c or pacing frequency), NADHm initially fell and subsequently recovered to a new steady state level. Upon reduction of work, NADHm overshot and then returned to control levels. In contrast, when work was increased without increasing average Ca2+o (by increasing sarcomere length), NADHm fell similarly, but no recovery or overshoot was observed. This Ca(2+)-dependent recovery and overshoot may be attributed to Ca(2+)-dependent stimulation of mitochondrial dehydrogenases. We conclude that the immediate initial increase in respiration rate upon elevation of work is not activated by increased NADHm (since NADHm rapidly fell) or by Ca2+o (since work could also be increased at constant Ca2+c). However, during sustained high work, a Ca(2+)-dependent mechanism causes slow recovery of NADHm toward control values. This demonstrates a Ca(2+)-dependent feed-forward control mechanism of cellular energetics in cardiac muscle during increased work.
Brandes et al. (Wed,) studied this question.