Ning Ma1,2,3, Joe Z Zhang1,2,3, Ilanit Itzhaki1,2,3, Sophia L Zhang1,2,3, Haodong Chen1,2,3, Francois Haddad1,2,3, Tomoya Kitani1,2,3, Kitchener D Wilson1,2,3, Lei Tian1,2,3, Rajani Shrestha1,2,3, Haodi Wu1,2,3, Chi Keung Lam1,2,3, Nazish Sayed1,2,3, Joseph C Wu1,2,3. 1. Stanford Cardiovascular Institute (N.M., J.Z.Z., I.I., S.L.Z., H.C., F.H., T.K., K.D.W., L.T., R.S., H.W., C.L., N.S., J.C.W.). 2. Division of Cardiology, Department of Medicine (N.M., J.Z.Z., I.I., S.L.Z., H.C., F.H., T.K., K.D.W., L.T., R.S., H.W., C.L., N.S., J.C.W.). 3. Institute for Stem Cell Biology and Regenerative Medicine, Stanford University School of Medicine, CA (N.M., J.Z.Z., I.I., S.L.Z., H.C., F.H., T.K., K.D.W., L.T., R.S., H.W., C.L., N.S., J.C.W.).
Abstract
BACKGROUND: The progression toward low-cost and rapid next-generation sequencing has uncovered a multitude of variants of uncertain significance (VUS) in both patients and asymptomatic "healthy" individuals. A VUS is a rare or novel variant for which disease pathogenicity has not been conclusively demonstrated or excluded, and thus cannot be definitively annotated. VUS, therefore, pose critical clinical interpretation and risk-assessment challenges, and new methods are urgently needed to better characterize their pathogenicity. METHODS: To address this challenge and showcase the uncertainty surrounding genomic variant interpretation, we recruited a "healthy" asymptomatic individual, lacking cardiac-disease clinical history, carrying a hypertrophic cardiomyopathy (HCM)-associated genetic variant (NM_000258.2:c.170C>A, NP_000249.1:p.Ala57Asp) in the sarcomeric gene MYL3, reported by the ClinVar database to be "likely pathogenic." Human-induced pluripotent stem cells (iPSCs) were derived from the heterozygous VUS MYL3(170C>A) carrier, and their genome was edited using CRISPR/Cas9 to generate 4 isogenic iPSC lines: (1) corrected "healthy" control; (2) homozygous VUS MYL3(170C>A); (3) heterozygous frameshift mutation MYL3(170C>A/fs); and (4) known heterozygous MYL3 pathogenic mutation (NM_000258.2:c.170C>G), at the same nucleotide position as VUS MYL3(170C>A), lines. Extensive assays including measurements of gene expression, sarcomere structure, cell size, contractility, action potentials, and calcium handling were performed on the isogenic iPSC-derived cardiomyocytes (iPSC-CMs). RESULTS: The heterozygous VUS MYL3(170C>A)-iPSC-CMs did not show an HCM phenotype at the gene expression, morphology, or functional levels. Furthermore, genome-edited homozygous VUS MYL3(170C>A)- and frameshift mutation MYL3(170C>A/fs)-iPSC-CMs lines were also asymptomatic, supporting a benign assessment for this particular MYL3 variant. Further assessment of the pathogenic nature of a genome-edited isogenic line carrying a known pathogenic MYL3 mutation, MYL3(170C>G), and a carrier-specific iPSC-CMs line, carrying a MYBPC3(961G>A) HCM variant, demonstrated the ability of this combined platform to provide both pathogenic and benign assessments. CONCLUSIONS: Our study illustrates the ability of clustered regularly interspaced short palindromic repeats/Cas9 genome-editing of carrier-specific iPSCs to elucidate both benign and pathogenic HCM functional phenotypes in a carrier-specific manner in a dish. As such, this platform represents a promising VUS risk-assessment tool that can be used for assessing HCM-associated VUS specifically, and VUS in general, and thus significantly contribute to the arsenal of precision medicine tools available in this emerging field.
BACKGROUND: The progression toward low-cost and rapid next-generation sequencing has uncovered a multitude of variants of uncertain significance (VUS) in both patients and asymptomatic "healthy" individuals. A VUS is a rare or novel variant for which disease pathogenicity has not been conclusively demonstrated or excluded, and thus cannot be definitively annotated. VUS, therefore, pose critical clinical interpretation and risk-assessment challenges, and new methods are urgently needed to better characterize their pathogenicity. METHODS: To address this challenge and showcase the uncertainty surrounding genomic variant interpretation, we recruited a "healthy" asymptomatic individual, lacking cardiac-disease clinical history, carrying a hypertrophic cardiomyopathy (HCM)-associated genetic variant (NM_000258.2:c.170C>A, NP_000249.1:p.Ala57Asp) in the sarcomeric gene MYL3, reported by the ClinVar database to be "likely pathogenic." Human-induced pluripotent stem cells (iPSCs) were derived from the heterozygous VUS MYL3(170C>A) carrier, and their genome was edited using CRISPR/Cas9 to generate 4 isogenic iPSC lines: (1) corrected "healthy" control; (2) homozygous VUS MYL3(170C>A); (3) heterozygous frameshift mutation MYL3(170C>A/fs); and (4) known heterozygous MYL3 pathogenic mutation (NM_000258.2:c.170C>G), at the same nucleotide position as VUS MYL3(170C>A), lines. Extensive assays including measurements of gene expression, sarcomere structure, cell size, contractility, action potentials, and calcium handling were performed on the isogenic iPSC-derived cardiomyocytes (iPSC-CMs). RESULTS: The heterozygous VUS MYL3(170C>A)-iPSC-CMs did not show an HCM phenotype at the gene expression, morphology, or functional levels. Furthermore, genome-edited homozygous VUS MYL3(170C>A)- and frameshift mutation MYL3(170C>A/fs)-iPSC-CMs lines were also asymptomatic, supporting a benign assessment for this particular MYL3 variant. Further assessment of the pathogenic nature of a genome-edited isogenic line carrying a known pathogenic MYL3 mutation, MYL3(170C>G), and a carrier-specific iPSC-CMs line, carrying a MYBPC3(961G>A) HCM variant, demonstrated the ability of this combined platform to provide both pathogenic and benign assessments. CONCLUSIONS: Our study illustrates the ability of clustered regularly interspaced short palindromic repeats/Cas9 genome-editing of carrier-specific iPSCs to elucidate both benign and pathogenic HCM functional phenotypes in a carrier-specific manner in a dish. As such, this platform represents a promising VUS risk-assessment tool that can be used for assessing HCM-associated VUS specifically, and VUS in general, and thus significantly contribute to the arsenal of precision medicine tools available in this emerging field.
Authors: Ning Sun; Masayuki Yazawa; Jianwei Liu; Leng Han; Veronica Sanchez-Freire; Oscar J Abilez; Enrique G Navarrete; Shijun Hu; Li Wang; Andrew Lee; Aleksandra Pavlovic; Shin Lin; Rui Chen; Roger J Hajjar; Michael P Snyder; Ricardo E Dolmetsch; Manish J Butte; Euan A Ashley; Michael T Longaker; Robert C Robbins; Joseph C Wu Journal: Sci Transl Med Date: 2012-04-18 Impact factor: 17.956
Authors: Lu Han; Yang Li; Jason Tchao; Aaron D Kaplan; Bo Lin; You Li; Jocelyn Mich-Basso; Agnieszka Lis; Narmeen Hassan; Barry London; Glenna C L Bett; Kimimasa Tobita; Randall L Rasmusson; Lei Yang Journal: Cardiovasc Res Date: 2014-09-10 Impact factor: 10.787
Authors: Timon Seeger; Rajani Shrestha; Chi Keung Lam; Caressa Chen; Wesley L McKeithan; Edward Lau; Alexa Wnorowski; George McMullen; Matthew Greenhaw; Jaecheol Lee; Angelos Oikonomopoulos; Soah Lee; Huaxiao Yang; Mark Mercola; Matthew Wheeler; Euan A Ashley; Fan Yang; Ioannis Karakikes; Joseph C Wu Journal: Circulation Date: 2019-02-05 Impact factor: 29.690
Authors: Chi Keung Lam; Lei Tian; Nadjet Belbachir; Alexa Wnorowski; Rajani Shrestha; Ning Ma; Tomoya Kitani; June-Wha Rhee; Joseph C Wu Journal: Circ Res Date: 2019-05-13 Impact factor: 17.367
Authors: Nikhil V Chavali; Dmytro O Kryshtal; Shan S Parikh; Lili Wang; Andrew M Glazer; Daniel J Blackwell; Brett M Kroncke; Moore Benjamin Shoemaker; Bjorn C Knollmann Journal: Heart Rhythm Date: 2019-04-18 Impact factor: 6.343
Authors: Tomoya Kitani; Sang-Ging Ong; Chi Keung Lam; June-Wha Rhee; Joe Z Zhang; Angelos Oikonomopoulos; Ning Ma; Lei Tian; Jaecheol Lee; Melinda L Telli; Ronald M Witteles; Arun Sharma; Nazish Sayed; Joseph C Wu Journal: Circulation Date: 2019-05-21 Impact factor: 29.690