Originally Posted by
terrymorse
There are many papers on mitochondria and exercise. A good jumping off place is
Granata et al, Training-Induced Changes in Mitochondrial Content and Respiratory Function in Human Skeletal Muscle, 2018.
"This review focuses on mitochondrial changes taking place following a series of exercise sessions (training-induced mitochondrial adaptations), providing an in-depth analysis of the effects of exercise intensity and training volume on changes in mitochondrial protein synthesis, mitochondrial content, and mitochondrial respiratory function."This rThis review focuses on mitochondrial changes taking place following a series of exercise sessions (training-induced mitochondrial adaptations), providing an in-depth analysis of the effects of exerciseintensity and training volume on changes in mitochondrial protein synthesis, mitochondrial content, and mitochondrial respiratory function.eview focuses on mitochondrial changes taking place following a series of exercise sessions (training-induced mitochondrial adaptations), providing an in-depth analysis of the effects of exerciseintensity and training volume on changes in mitochondrial protein synthesis, mitochondrial content, and mitochondrial respiratory function.
Interesting article but long...not a criticism. With respect to mitochondria biogenesis, it seems murky. What I know is that 4 billion years ago, mitochondria merged with simple life to set the stage for humans today. Mitochondria is a separate life form with its own DNA. And we get our mitochondria from our mother via her egg. Thank your mom for your mitochondria. Does mitochondria density change over time due to training stimulus - biogenesis? Not clear. I am not sure that it matters to us since we know that we need more time on the bike if we want to ride longer. Also, cells need to "ask" the mitochondria to make ATP. The communication may be corrupted due to aging...one theory. Does exercise improve communication/fix corrupted communication between cells and mitochondria?
I have been very interested in the role that blood plays in aerobic power. Increase hematocrit and there is more oxygen capability of the blood. What happens to mitochondria when faced with MORE oxygen than is needed? Does that cause biogenesis and or increase in respiration or enzyme activity?
And when it comes to hematocrit the kidneys are the boss. They determine blood volume and signal the bone marrow to make more red blood cells and thicken the blood. More oxygen capability of the blood supply that occurs naturally (no drugs) improves aerobic performance and recovery. Long distance riding destroys red blood cells which have to be replaced during recovery. Intensity, on the other hand, creates a hypoxic condition that causes the kidneys request the bone marrow to make more red blood cells. Of course, intensity will also destroy red blood cells.
So the training question is what is the correct prescription for 1. mitochondria biogenesis / increases in enzymes and 2. increases in blood hematocrit and 3. individual genetics. Very complicated.
However, one can measure blood in the lab and get feedback on blood markers as well as kidney filtration and other markers to see if diet and training are improving blood. Mitochondria performance is too tough to measure and not practical.