The DHPR Calcium Current in Mammalian Skeletal Muscle: Physiological Necessity or Tolerated Evolutionary Remnant?

In contrast to cardiac excitation-contraction coupling (ECC), skeletal-muscle ECC is based on Ca2+-influx-independent inter-channel communications between the dihydropyridine receptor (DHPR) and the ryanodine receptor (RyR1). The role of the small Ca2+ influx through the DHPR in mammalian skeletal muscle, which is not (immediately) required for ECC, is still enigmatic. Previously, we discovered that zebrafish, as well as all higher teleost fish, lack DHPR Ca2+ conductivity in skeletal muscle (Schredelseker et al., PNAS, 2010). Point mutation N617D in pore loop II of zebrafish DHPRα1S-b explained non-conductivity in fast muscle. To investigate the fascinating skeletal muscle DHPR Ca2+-conductivity / non-conductivity phenomenon we generated a non-conducting-DHPR knock-in mouse (n.c.DHPR) by introducing the N→D mutation into gene CACNA1S. Interestingly, homozygous n.c.DHPR mice are viable, fertile, visually indistinguishable, and identical in body-weight development to wild-type (WT) siblings. Myotubes isolated from newborn n.c.DHPR mice display complete lack of DHPR Ca2+ influx without altered ECC. No difference in locomotor activity (home cage activity), motor coordination (rotarod, beam walking), and muscle strength (endurance test, wire hang test) is observed in 3-7 months-old homozygous n.c.DHPR mice compared to WT. Identical results were obtained from forced frequency and fatigue tests on isolated EDL (fast twitch) and soleus (slow twitch) muscle fibers. As soon feasible, tests will be repeated on aged (18 months-old) mice to test for putative age-related accumulative effects on muscle performance, in order to understand if DHPR Ca2+ influx in mammalian skeletal muscle is a physiological necessity or just a tolerated evolutionary remnant of the ancestral pure Ca2+-influx dependent ECC of early chordates and phylogenetic branches below.Supported: FWF P-23229-B09; DK-W1101-B12.