Understanding The Molecular Defects Of Human MH And CCD

Abstract

Malignant Hyperthermia (MH) and Central Core Disease (CCD) are skeletal muscle disorders linked to mutations in the skeletal muscle ryanodine receptor (RyR1). Based on their phenotypes, disease-causing RyR1 mutations can be separated into three major groups: MH-only, both MH and CCD (MH/CCD), and CCD-only. The molecular basis for these different genotype-phenotype relationships is largely undefined. We have recently demonstrated that the porcine MH mutation, R615C, increases the sensitivity of the RyR1 channel to luminal Ca2+ activation and reduces the threshold for spontaneous Ca2+ release during store Ca2+ overload, also known as store-overload-induced Ca2+ release (SOICR). To investigate whether human MH and CCD mutations also alter the luminal Ca2+ activation of RyR1 and SOICR, we have generated a number of MH-only, MH/CCD, and CCD-only mutations located in the NH2 terminal, central, and COOH-terminal regions, and established stable, inducible HEK293 cell lines expressing these mutants. Using single cell Ca2+ imaging, we found that MH-only and MH/CCD mutations enhance the propensity for SOICR. On the other hand, some CCD-only mutations suppress or abolish SOICR, but retain caffeine-induced Ca2+ release, while other CCD-only mutants display little or no ryanodine- or caffeine-sensitive channel activity. Single channel studies reveal that, like the R615C MH mutation, MH/CCD mutations markedly sensitize the RyR1 channel to activation by luminal Ca2+. To assess their impact in the context of muscle cells, we are currently establishing stable, inducible mouse skeletal muscle C2C12 cell lines expressing MH and CCD RyR1 mutants. Further studies will address the question of whether altered luminal Ca2+ activation of RyR1 underlies a common defect of human MH and CCD mutations.