Evolutionary isolation of ryanodine receptor isoform 1 for muscle-based thermogenesis in mammals.

Resting skeletal muscle generates heat for endothermy in mammals but not amphibians, while both use the same Ca 2+ -handling proteins and membrane structures to conduct excitation-contraction coupling apart from having different ryanodine receptor (RyR) isoforms for Ca 2+ release. The sarcoplasmic reticulum (SR) generates heat following Adenosine triphosphate (ATP) hydrolysis at the Ca 2+ pump, which is amplified by increasing RyR1 Ca 2+ leak in mammals, subsequently increasing cytoplasmic [Ca 2+ ] ([Ca 2+ ] cyto ). For thermogenesis to be functional, rising [Ca 2+ ] cyto must not interfere with cytoplasmic effectors of the sympathetic nervous system (SNS) that likely increase RyR1 Ca 2+ leak; nor should it compromise the muscle remaining relaxed. To achieve this, Ca 2+ activated, regenerative Ca 2+ release that is robust in lower vertebrates needs to be suppressed in mammals. However, it has not been clear whether: i) the RyR1 can be opened by local increases in [Ca 2+ ] cyto ; and ii) downstream effectors of the SNS increase RyR Ca 2+ leak and subsequently, heat generation. By positioning amphibian and malignant hyperthermia-susceptible human-skinned muscle fibers perpendicularly, we induced abrupt rises in [Ca 2+ ] cyto under identical conditions optimized for activating regenerative Ca 2+ release as Ca 2+ waves passed through the junction of fibers. Only mammalian fibers showed resistance to rising [Ca 2+ ] cyto , resulting in increased SR Ca 2+ load and leak. Fiber heat output was increased by cyclic adenosine monophosphate (cAMP)-induced RyR1 phosphorylation at Ser2844 and Ca 2+ leak, indicating likely SNS regulation of thermogenesis. Thermogenesis occurred despite the absence of SR Ca 2+ pump regulator sarcolipin. Thus, evolutionary isolation of RyR1 provided increased dynamic range for thermogenesis with sensitivity to cAMP, supporting endothermy.