The fastest and most manoeuvrable terrestrial animals are found in savannah habitats, where predators chase and capture running prey. Hunt outcome and success rate are critical to survival, so both predator and prey should evolve to be faster and/or more manoeuvrable. Here we compare locomotor characteristics in two pursuit predator-prey pairs, lion-zebra and cheetah-impala, in their natural savannah habitat in Botswana. We show that although cheetahs and impalas were universally more athletic than lions and zebras in terms of speed, acceleration and turning, within each predator-prey pair, the predators had 20% higher muscle fibre power than prey, 37% greater acceleration and 72% greater deceleration capacity than their prey. We simulated hunt dynamics with these data and showed that hunts at lower speeds enable prey to use their maximum manoeuvring capacity and favour prey survival, and that the predator needs to be more athletic than its prey to sustain a viable success rate.
Rainbow trout, Oncorhynchus mykiss, were exercise trained for 28–52 days. Trained fish were 13% larger and swam 12% faster in an aerobic swimming test. Training induced cardiac growth that was isometric with body growth, since ventricle mass relative to body mass was constant. The proportions of compact and spongy myocardia in the ventricle were also unchanged by training. Trained fish had significantly higher levels of citrate synthase, β-hydroxyacyl CoA dehydrogenase, and hexokinase in both compact and spongy myocardium. Ligation of a 0.5- to 1.0-cm section of the coronary artery produced only a temporary interruption of coronary flow to the compact myocardium because new vessels grew around the ligation site in the majority of fish during the 28- to 52-day experiment. Nonetheless, coronary ligation resulted in a significantly smaller (17%) proportion of compact myocardium with lower levels of citrate synthase, β-hydroxyacyl CoA dehydrogenase, and hexokinase. Exercise-induced increases in the levels of these enzymes in the compact myocardium were prevented by coronary ligation. The decrease of enzymes in the compact myocardium as a result of coronary ligation was compensated for by a 30% increase in the levels of the aerobic enzymes citrate synthase and β-hydroxyacyl CoA dehydrogenase and a 32% increase in the mass of spongy myocardium. As a result of these compensations and coronary regrowth, chronic coronary ligation did not affect maximum prolonged swimming speed. These experiments clearly reveal that cardiac plasticity allows compensatory changes that are necessary for the heart to maintain adequate oxygen delivery to exercising skeletal muscle. The compensatory changes were isometric increases in heart mass or proportionately larger increases in heart mass and compact tissue if the coronary artery was ligated and an increase in metabolic enzymes associated with ATP generation, namely, citrate synthase, β-hydroxyacyl CoA dehydrogenase, and hexokinase.
Background: Cardiac myosin regulatory light chain (RLC) phosphorylation alters cardiac muscle function.Results: Phosphorylation affects mechanical parameters of cardiac muscle contraction during shortening.Conclusion: Phosphorylation impacts mechanical function of cardiac muscle and is altered during cardiac disease.Significance: Understanding RLC regulation by phosphorylation in cardiac muscle contraction is crucial for understanding changes in disease.
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