Enrichment of mutant calmodulin protein in a murine model of a human calmodulinopathy
Wen-Chin Tsai, Chiu-Fen Yang, Shu-Yu Lin, Suh-Yuen Liang, Wei-Chung Tsai, Shuai Guo, Xiaochun Li, Susan Ofner, Kai-Chien Yang, Tzu-Ching Meng, Peng-Sheng Chen, Michael Rubart
Wen-Chin Tsai, Chiu-Fen Yang, Shu-Yu Lin, Suh-Yuen Liang, Wei-Chung Tsai, Shuai Guo, Xiaochun Li, Susan Ofner, Kai-Chien Yang, Tzu-Ching Meng, Peng-Sheng Chen, Michael Rubart
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Research Article Cardiology Cell biology

Enrichment of mutant calmodulin protein in a murine model of a human calmodulinopathy

Abstract

Heterozygosity for missense mutations in 1 of 3 seemingly redundant calmodulin-encoding (CALM-encoding) genes can cause life-threatening arrhythmias, suggesting that small fractions of mutant CALM protein suffice to cause a severe phenotype. However, the exact molar ratios of wild-type to mutant CALM protein in calmodulinopathy hearts remain unknown. The aim of the present study was to quantitate mutant versus wild-type CALM transcript and protein levels in hearts of knockin mice harboring the p.N98S mutation in the Calm1 gene. We found that the transcripts from the mutant Calm1 allele were the least abundantly expressed Calm transcripts in both hetero- and homozygous mutant hearts, while mutant hearts accumulated high levels of N98S-CALM protein in a Calm1N98S allele dosage-dependent manner, exceeding those of wild-type CALM protein. We further show that the severity of the electrophysiological phenotype incrementally increased with the graded increase in the mutant/wild-type CALM protein expression ratio seen in homozygous versus heterozygous mutant mice. We finally show a decrease in N98S-CALM protein degradation, suggesting that mutant CALM stabilization contributed to its enrichment in the heart. Our results support what we believe to be a novel mechanism by which a mutation in a single Calm gene can give rise to a severe phenotype.

Authors

Wen-Chin Tsai, Chiu-Fen Yang, Shu-Yu Lin, Suh-Yuen Liang, Wei-Chung Tsai, Shuai Guo, Xiaochun Li, Susan Ofner, Kai-Chien Yang, Tzu-Ching Meng, Peng-Sheng Chen, Michael Rubart

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Figure 1

Genotype frequencies and Calm gene expression in adult offspring derived from Calm1N98S/+ intercrosses.

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Genotype frequencies and Calm gene expression in adult offspring derived...
(A) Genotypes of postnatal day 10 (P10) offspring derived from Calm1N98S/+ intercrosses. We used χ2 analysis for genotypic ratios. Observed genotypic proportions significantly deviate from those expected for Mendelian inheritance (P < 0.0001), irrespective of sex. (B) RNA-Seq was performed and the expression levels of the 3 Calm genes were quantitated in male hearts (left ventricles, LVs) from Calm1+/+, Calm1N98S/+, and Calm1N98S/N98S littermate mice. Data are displayed as scatter dot plots with the lines representing the medians from 3 biological replicates per genotype. A linear model of log(expression) as explained by genotype, Calm gene expression type, and the interaction of the two was used to compare mean Calm gene expression within each genotype (left) and among genotypes (right). *P ≤ 0.009 vs. Calm1, P ≤ 0.003 vs. Calm2 in left panel; *P ≤ 0.043 vs. Calm1+/+, P ≤ 0.02 vs. Calm1N98S/+ in right panel. FPKM, fragments per kilobase of transcript per million reads mapped. (C) RT-PCR–based estimates of absolute Calm gene transcript levels in atria and RV. Mean fold-changes in expression of each Calm gene in the atria and RV relative to their expression in LV were calculated by 2–ΔΔCT, where ΔΔCT = average(ΔCT,atria or RV,Calm) – average(ΔCT,LV,Calm), multiplied by the LV FPKM value for the corresponding Calm gene and genotype to obtain estimates of average absolute Calm transcript levels in atria and RV. Vertical bars denote error margins given by 2–ΔΔCT+SEM and 2–ΔΔCT–SEM.