Patient mutations linked to arrhythmogenic cardiomyopathy enhance calpain-mediated desmoplakin degradation
Ronald Ng, Heather Manring, Nikolaos Papoutsidakis, Taylor Albertelli, Nicole Tsai, Claudia J. See, Xia Li, Jinkyu Park, Tyler L. Stevens, Prameela J. Bobbili, Muhammad Riaz, Yongming Ren, Christopher E. Stoddard, Paul M.L. Janssen, T. Jared Bunch, Stephen P. Hall, Ying-Chun Lo, Daniel L. Jacoby, Yibing Qyang, Nathan Wright, Maegen A. Ackermann, Stuart G. Campbell
Ronald Ng, Heather Manring, Nikolaos Papoutsidakis, Taylor Albertelli, Nicole Tsai, Claudia J. See, Xia Li, Jinkyu Park, Tyler L. Stevens, Prameela J. Bobbili, Muhammad Riaz, Yongming Ren, Christopher E. Stoddard, Paul M.L. Janssen, T. Jared Bunch, Stephen P. Hall, Ying-Chun Lo, Daniel L. Jacoby, Yibing Qyang, Nathan Wright, Maegen A. Ackermann, Stuart G. Campbell
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Research Article Cardiology Genetics

Patient mutations linked to arrhythmogenic cardiomyopathy enhance calpain-mediated desmoplakin degradation

Abstract

Arrhythmogenic cardiomyopathy (ACM) is an inherited disorder with variable genetic etiologies. Here, we focused on understanding the precise molecular pathology of a single clinical variant in DSP, the gene encoding desmoplakin. We initially identified a potentially novel missense desmoplakin variant (p.R451G) in a patient diagnosed with biventricular ACM. An extensive single-family ACM cohort was assembled, revealing a pattern of coinheritance for R451G desmoplakin and the ACM phenotype. An in vitro model system using patient-derived induced pluripotent stem cell lines showed depressed levels of desmoplakin in the absence of abnormal electrical propagation. Molecular dynamics simulations of desmoplakin R451G revealed no overt structural changes, but a significant loss of intramolecular interactions surrounding a putative calpain target site was observed. Protein degradation assays of recombinant desmoplakin R451G confirmed increased calpain vulnerability. In silico screening identified a subset of 3 additional ACM-linked desmoplakin missense mutations with apparent enhanced calpain susceptibility, predictions that were confirmed experimentally. Similar to R451G, these mutations are found in families with biventricular ACM. We conclude that augmented calpain-mediated degradation of desmoplakin represents a shared pathological mechanism for select ACM-linked missense variants. This approach for identifying variants with shared molecular pathologies may represent a powerful new strategy for understanding and treating inherited cardiomyopathies.

Authors

Ronald Ng, Heather Manring, Nikolaos Papoutsidakis, Taylor Albertelli, Nicole Tsai, Claudia J. See, Xia Li, Jinkyu Park, Tyler L. Stevens, Prameela J. Bobbili, Muhammad Riaz, Yongming Ren, Christopher E. Stoddard, Paul M.L. Janssen, T. Jared Bunch, Stephen P. Hall, Ying-Chun Lo, Daniel L. Jacoby, Yibing Qyang, Nathan Wright, Maegen A. Ackermann, Stuart G. Campbell

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Figure 7

Decreased stability of recombinant desmoplakin NH2-terminus with R451G mutation.

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Decreased stability of recombinant desmoplakin NH2-terminus with R451G m...
(A) A recombinant glutathione-S-transferase–tagged desmoplakin fragment consisting of the first 883 amino acids (GST-DSP1–883WT) was bacterially expressed and purified. After the fragment was incubated with calpain for 5-, 10-, 15-, or 30-minute intervals, degradation products were separated via SDS-PAGE and visualized by staining with Sypro Ruby. Very little degradation was observed. (B) The same experiment was repeated with a fragment containing the R451G amino acid substitution (GST-DSP1–883R451G). This gel shows substantial decrease of the intact fragment over time as it is exposed to calpain. (C) Quantification of gel images across repeated experiments reveals a significant increase in calpain-mediated degradation of the mutant R451G recombinant DSP protein relative to WT (*P < 0.05 for 2-tailed unpaired t test at 30-minute time point; GST-DSP1–883WT n = 4; GST-DSP1–883R451G n = 3). Error bars represent SEM.