Regulation of Ca2+ leak and susceptibility to malignant hyperthermia and heat stroke

Hamilton, Susan 1 ; Van Petegem, Filip 2 ; Rodney, George 1 ; Cavazos, Courtney1 ; Jung, Sung Yun 1 ; Yee, Rachel Sue Zhen 1 ; Lee, Chang Seok 1 ; Yousif, Omar1

Research facility: Baylor College of Medicine

Published Sep 28, 2025 on Dryad. https://doi.org/10.5061/dryad.r2280gbpr

Data files

Sep 28, 2025 version files 252.81 KB

Data_for_all_panels_final_annotated2.xlsx

249.34 KB
README.md

3.46 KB

Abstract

Sarcoplasmic reticulum (SR) Ca2+ leak is elevated in many myopathies, but whether Ca2+ leak is a driver or consequence of the disease process is not always clear. The Ryanodine Receptor, RYR1, is the SR Ca2+ release channel required for both muscle contraction and Ca2+ leak. SPEG (striated muscle preferentially expressed protein kinase) regulates the Ca2+ leak properties of RYR1 by phosphorylation of serine 2902. Mutation of Serine S2902 to an aspartic acid to mimic SPEG phosphorylation of RYR1 decreases muscle temperature-dependent SR Ca2+ leak, restores the levels of excitation-contraction coupling proteins, and reduces the heat and volatile anesthetic sensitivity of mice with a malignant hyperthermia susceptibility mutation in RYR1 (Y524S, Y522S in humans). The S2902D mice allow a direct test of the role of SR Ca2+ leak in both normal muscle function (aging, exercise) and mice disease pathophysiology.

Dataset DOI: 10.5061/dryad.r2280gbpr

Description of the data and file structure

The data were generated to define the role of SR Ca²⁺ leak in muscle heat production and enhanced sensitivity to heat stroke. The data were generated with mouse models of malignant hyperthermia susceptibility with a mutation in the skeletal muscle Ca²⁺ release channel (RYR1), which serves as a model of enhanced sensitivity to heat and heat-induced Ca²⁺ leak. A second mouse model had a mutation in RYR1 to mimic phosphorylation of RYR1 by the striated muscle preferentially expressed protein kinase SPEG. These mice displayed reduced SR Ca²⁺ leak. This dataset includes multiple approaches to assessing the role of SR Ca2+ leak in the phenotypes of the mice.

Files and variables

File: Data_for_all_panels_final_annotated2.xlsx

The data file contains multiple sheets, each corresponding to a specific figure presented in the manuscript. Each sheet includes the relevant source data, along with a legend explaining the data and a list of any abbreviations used.

Description of variables:

Genotype: WT (wildtype, S2902D HET (mice heterozygous for a mutation in RYR1), S2902D HOM (mice homozygous for a mutation in RYR1), YS (mice with a heterozygous MHS mutation in RYR1), YS/S2902D (mice heterozygous for the YS and S2902D mutation).
Muscles: extensor digitorum longus (EDL), soleus, flexor digitorum brevis (FDB), tibialis anterior (TA), gastrocnemius.
Gender: male, female
phosphorylation sites detected by parallel reaction monitoring (iiBAQWesternblots (absorbance) normalized to wildtype controls and plotted as % WT
Body composition: weight (g), Fat (fat weight in g/ body weight), lean weight/body weight (g/g ).
food intake (g/day), activity in wheel turns per day, or cumulative wheel turns over 3 days,
heat generated during the day or night in kcal/hr,
Force (N/cm²) generated as a function of stimulation frequency (Hz), Fmax is the maximal force generated in the force-frequency curve, HZ50 is the half maximal stimulation frequency
Force(N/cm²) as a function of caffeine concentration (mM).
Mag-fluo 4 fluorescence (F-0/F0)
Manganese (Mn) quench data with fura2. Slope of passive influx (quenching of fluorescence)
Immunoprecipitation analyzed by volcano plots of log2(fold change) vs -log(q)
Bodu and muscle temperature in ^oC
Indirect calorimetry to measure VO2 (ml/kg/hr), VCO2 (ml/kg/hr), and respiratory exchange ratio (RER)

Code/software

Prism, Excel.

Code, written in IDL to analyze Ca²⁺ spark data, has been deposited in Zenodo (https://doi.org/10.5281/zenodo.17023652)

Access information

Other publicly accessible locations of the data: