A BAG3 chaperone complex maintains cardiomyocyte function during proteotoxic stress
Luke M. Judge, Juan A. Perez-Bermejo, Annie Truong, Alexandre J.S. Ribeiro, Jennie C. Yoo, Christina L. Jensen, Mohammad A. Mandegar, Nathaniel Huebsch, Robyn M. Kaake, Po-Lin So, Deepak Srivastava, Beth L. Pruitt, Nevan J. Krogan, Bruce R. Conklin
Luke M. Judge, Juan A. Perez-Bermejo, Annie Truong, Alexandre J.S. Ribeiro, Jennie C. Yoo, Christina L. Jensen, Mohammad A. Mandegar, Nathaniel Huebsch, Robyn M. Kaake, Po-Lin So, Deepak Srivastava, Beth L. Pruitt, Nevan J. Krogan, Bruce R. Conklin
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Research Article Cardiology Cell biology

A BAG3 chaperone complex maintains cardiomyocyte function during proteotoxic stress

Abstract

Molecular chaperones regulate quality control in the human proteome, pathways that have been implicated in many diseases, including heart failure. Mutations in the BAG3 gene, which encodes a co-chaperone protein, have been associated with heart failure due to both inherited and sporadic dilated cardiomyopathy. Familial BAG3 mutations are autosomal dominant and frequently cause truncation of the coding sequence, suggesting a heterozygous loss-of-function mechanism. However, heterozygous knockout of the murine BAG3 gene did not cause a detectable phenotype. To model BAG3 cardiomyopathy in a human system, we generated an isogenic series of human induced pluripotent stem cells (iPSCs) with loss-of-function mutations in BAG3. Heterozygous BAG3 mutations reduced protein expression, disrupted myofibril structure, and compromised contractile function in iPSC-derived cardiomyocytes (iPS-CMs). BAG3-deficient iPS-CMs were particularly sensitive to further myofibril disruption and contractile dysfunction upon exposure to proteasome inhibitors known to cause cardiotoxicity. We performed affinity tagging of the endogenous BAG3 protein and mass spectrometry proteomics to further define the cardioprotective chaperone complex that BAG3 coordinates in the human heart. Our results establish a model for evaluating protein quality control pathways in human cardiomyocytes and their potential as therapeutic targets and susceptibility factors for cardiac drug toxicity.

Authors

Luke M. Judge, Juan A. Perez-Bermejo, Annie Truong, Alexandre J.S. Ribeiro, Jennie C. Yoo, Christina L. Jensen, Mohammad A. Mandegar, Nathaniel Huebsch, Robyn M. Kaake, Po-Lin So, Deepak Srivastava, Beth L. Pruitt, Nevan J. Krogan, Bruce R. Conklin

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Figure 2

BAG3 mutations produce contractile deficits in iPS-CMs cultured on micropatterned substrates.

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BAG3 mutations produce contractile deficits in iPS-CMs cultured on micro...
Day >30 purified induced pluripotent stem cell–derived cardiomyocytes (iPS-CMs) were cultured on micropatterned polyacrylamide hydrogel substrates with a mechanical stiffness of 10 kPa. BAG3 KO1 mutant lines were used. (A) Contraction power was calculated from the measured force and contraction velocity determined by traction force microscopy from the movement of fluorescent beads in the substrate. Results were normalized to WT and individual replicates plotted with mean and SD. Brackets indicate significant differences (P < 0.001) by 1-way ANOVA with Bonferroni’s test for multiple comparisons. (B) Sarcomere shortening was measured in LifeAct-labeled myofibrils. Results were normalized to WT and individual replicates plotted with mean and SD. Brackets indicate significant differences (P < 0.05) by 1-way ANOVA with Bonferroni’s test for multiple comparisons. Measurements were obtained from 3 independent device cultures, prepared from 2 separate differentiation batches. For force measurements, 40–51 total cells were analyzed per line. For sarcomere shortening, 9–26 total cells were analyzed per line. (C) Representative images of patterned LifeAct-labeled cells, and associated heatmaps for surface traction stress (scale in Pa) are shown. Scale bars: 20 μm.