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1. Mosaicism for the smooth muscle cell (SMC)-specific knock-in of the Acta2 R179C pathogenic variant: Implications for gene editing therapies

Author

Anita Kaw, Albert J. Pedroza, Abhijnan Chattopadhyay, Amelie Pinard, Dongchuan Guo, Kaveeta Kaw, Zhen Zhou, Rohan Shad, Michael P. Fischbein, Callie S. Kwartler, and Dianna M. Milewicz

Subjects
Gene Editing, Aortic Aneurysm, Thoracic, Mosaicism, Myocytes, Smooth Muscle, Humans, Cardiology and Cardiovascular Medicine, Molecular Biology, Actins
Published
2022

2. Preventing Cholesterol-Induced Perk (Protein Kinase RNA-Like Endoplasmic Reticulum Kinase) Signaling in Smooth Muscle Cells Blocks Atherosclerotic Plaque Formation

Author

Abhijnan Chattopadhyay, Pujun Guan, Suravi Majumder, Kaveeta Kaw, Zhen Zhou, Chen Zhang, Siddharth K. Prakash, Anita Kaw, L. Maximillian Buja, Callie S. Kwartler, and Dianna M. Milewicz

Subjects
Male, Mice, eIF-2 Kinase, Cholesterol, Myocytes, Smooth Muscle, Animals, Cardiology and Cardiovascular Medicine, Atherosclerosis, Endoplasmic Reticulum, Cells, Cultured, Muscle, Smooth, Vascular, Plaque, Atherosclerotic
Abstract

Background: Vascular smooth muscle cells (SMCs) undergo complex phenotypic modulation with atherosclerotic plaque formation in hyperlipidemic mice, which is characterized by de-differentiation and heterogeneous increases in the expression of macrophage, fibroblast, osteogenic, and stem cell markers. An increase of cellular cholesterol in SMCs triggers similar phenotypic changes in vitro with exposure to free cholesterol due to cholesterol entering the endoplasmic reticulum, triggering endoplasmic reticulum stress and activating Perk (protein kinase RNA-like endoplasmic reticulum kinase) signaling. Methods: We generated an SMC-specific Perk knockout mouse model, induced hyperlipidemia in the mice by AAV- PCSK9 DY injection, and subjected them to a high-fat diet. We then assessed atherosclerotic plaque formation and performed single-cell transcriptomic studies using aortic tissue from these mice. Results: SMC-specific deletion of Perk reduces atherosclerotic plaque formation in male hyperlipidemic mice by 80%. Single-cell transcriptomic data identify 2 clusters of modulated SMCs in hyperlipidemic mice, one of which is absent when Perk is deleted in SMCs. The 2 modulated SMC clusters have significant overlap of transcriptional changes, but the Perk-dependent cluster uniquely shows a global decrease in the number of transcripts. SMC-specific Perk deletion also prevents migration of both contractile and modulated SMCs from the medial layer of the aorta. Conclusions: Our results indicate that hypercholesterolemia drives both Perk-dependent and Perk-independent SMC modulation and that deficiency of Perk significantly blocks atherosclerotic plaque formation.

Published
2022

3. Cholesterol-Induced Phenotypic Modulation of Smooth Muscle Cells to Macrophage/Fibroblast–like Cells Is Driven by an Unfolded Protein Response

Author

Kaveeta Kaw, Anita Kaw, Abhijnan Chattopadhyay, Dianna M. Milewicz, Callie S. Kwartler, Scott A. LeMaire, Jiyuan Chen, Ying H. Shen, and Yanming Li

Subjects
Male, Vascular smooth muscle, phenotype, Phenotypic modulation, Eukaryotic Initiation Factor-2, Myocytes, Smooth Muscle, Phenotypic switching, Kruppel-Like Transcription Factors, macrophage, Muscle, Smooth, Vascular, fibroblast, Cell Line, Kruppel-Like Factor 4, eIF-2 Kinase, chemistry.chemical_compound, Transcription (biology), medicine, Animals, Fibroblast, smooth muscle cell, Basic Sciences, Chemistry, Cholesterol, Macrophages, cholesterol, Fibroblasts, Atherosclerosis, Endoplasmic Reticulum Stress, Activating Transcription Factor 4, Phenotype, Plaque, Atherosclerotic, Cell biology, Mice, Inbred C57BL, medicine.anatomical_structure, Cell Transdifferentiation, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, Unfolded Protein Response, Unfolded protein response, Female, Cardiology and Cardiovascular Medicine
Abstract

Supplemental Digital Content is available in the text., Objective: Vascular smooth muscle cells (SMCs) dedifferentiate and initiate expression of macrophage markers with cholesterol exposure. This phenotypic switching is dependent on the transcription factor Klf4 (Krüppel-like factor 4). We investigated the molecular pathway by which cholesterol induces SMC phenotypic switching. Approach and Results: With exposure to free cholesterol, SMCs decrease expression of contractile markers, activate Klf4, and upregulate a subset of macrophage and fibroblast markers characteristic of modulated SMCs that appear with atherosclerotic plaque formation. These phenotypic changes are associated with activation of all 3 pathways of the endoplasmic reticulum unfolded protein response (UPR), Perk (protein kinase RNA-like endoplasmic reticulum kinase), Ire (inositol-requiring enzyme) 1α, and Atf (activating transcription factor) 6. Blocking the movement of cholesterol from the plasma membrane to the endoplasmic reticulum prevents free cholesterol–induced UPR, Klf4 activation, and upregulation of the majority of macrophage and fibroblast markers. Cholesterol-induced phenotypic switching is also prevented by global UPR inhibition or specific inhibition of Perk signaling. Exposure to chemical UPR inducers, tunicamycin and thapsigargin, is sufficient to induce these same phenotypic transitions. Finally, analysis of published single-cell RNA sequencing data during atherosclerotic plaque formation in hyperlipidemic mice provides preliminary in vivo evidence of a role of UPR activation in modulated SMCs. Conclusions: Our data demonstrate that UPR is necessary and sufficient to drive phenotypic switching of SMCs to cells that resemble modulated SMCs found in atherosclerotic plaques. Preventing a UPR in hyperlipidemic mice diminishes atherosclerotic burden, and our data suggest that preventing SMC transition to dedifferentiated cells expressing macrophage and fibroblast markers contributes to this decreased plaque burden.

Published
2021

4. Expanding ACTA2 genotypes with corresponding phenotypes overlapping with smooth muscle dysfunction syndrome

Author

Anita Kaw, Kaveeta Kaw, Ellen M. Hostetler, Ana Beleza‐Meireles, Adam Smith‐Collins, Catherine Armstrong, Ingrid Scurr, Timothy Cotts, Rajani Aatre, Michael J. Bamshad, Dawn Earl, Abraham Groner, Katherine Agre, Yehuda Raveh, Callie S. Kwartler, and Dianna M. Milewicz

Subjects
Cerebrovascular Disorders, Heterozygote, Phenotype, Aortic Aneurysm, Thoracic, Mutation, Genetics, Humans, Muscle, Smooth, Moyamoya Disease, Ductus Arteriosus, Patent, Genetics (clinical), Actins
Abstract

Pathogenic variants in ACTA2, encoding smooth muscle α-actin, predispose to thoracic aortic aneurysms and dissections. ACTA2 variants altering arginine 179 predispose to a more severe, multisystemic disease termed smooth muscle dysfunction syndrome (SMDS; OMIM 613834). Vascular complications of SMDS include patent ductus arteriosus (PDA) or aortopulmonary window, early-onset thoracic aortic disease (TAD), moyamoya-like cerebrovascular disease, and primary pulmonary hypertension. Patients also have dysfunction of other smooth muscle-dependent systems, including congenital mydriasis, hypotonic bladder, and gut hypoperistalsis. Here, we describe five patients with novel heterozygous ACTA2 missense variants, p.Arg179Gly, p.Met46Arg, p.Thr204Ile, p.Arg39Cys, and p.Ile66Asn, who have clinical complications that align or overlap with SMDS. Patients with the ACTA2 p.Arg179Gly and p.Thr204Ile variants display classic features of SMDS. The patient with the ACTA2 p.Met46Arg variant exhibits exclusively vascular complications of SMDS, including early-onset TAD, PDA, and moyamoya-like cerebrovascular disease. The patient with the ACTA2 p.Ile66Asn variant has an unusual vascular complication, a large fusiform internal carotid artery aneurysm. The patient with the ACTA2 p.Arg39Cys variant has pulmonary, gastrointestinal, and genitourinary complications of SMDS but no vascular manifestations. Identifying pathogenic ACTA2 variants associated with features of SMDS is critical for aggressive surveillance and management of vascular and nonvascular complications and delineating the molecular pathogenesis of SMDS.

Published
2022

5. Contributors

Author

Bipul R. Acharya, Dritan Agalliu, V.A. Alexandrescu, Zakaria Almuwaqqat, Rheure Alves-Lopes, Ken Arai, Wadih Arap, Victoria L. Bautch, Lisa M. Becker, Michelle P. Bendeck, Jan Walter Benjamins, Saptarshi Biswas, E. Boesmans, Livia L. Camargo, Peter Carmeliet, Munir Chaudhuri, Nicholas W. Chavkin, Ondine Cleaver, Clément Cochain, Michael S. Conte, Azzurra Cottarelli, Christie L. Crandall, Anne Cuypers, Andreas Daiber, Alan Dardik, Jui M. Dave, J.O. Defraigne, Wenjun Deng, Robert J. DeStefano, Devinder Dhindsa, Danny J. Eapen, Anne Eichmann, Christian El Amm, Omotayo Eluwole, Christian Faaborg-Andersen, Steven A. Fisher, Zorina S. Galis, Guillermo García-Cardeña, Xin Geng, Michael A. Gimbrone, Luis Gonzalez, Daniel M. Greif, Xiaowu Gu, Shuzhen Guo, Tara L. Haas, Omar Hahad, Pim van der Harst, Peter K. Henke, Karen K. Hirschi, C. Holemans, Gonçalo Hora de Carvalho, Song Hu, Jay D. Humphrey, Shabatun J. Islam, Xinguo Jiang, Luis Eduardo Juarez-Orozco, Angelos D. Karagiannis, Anita Kaw, Kaveeta Kaw, Fatemeh Kazemzadeh, A. Kerzmann, Alexander S. Kim, Ageliki Laina, Eva K. Lee, Jinyu Li, Wenlu Li, Chien-Jung Lin, Xiaolei Liu, Eng H. Lo, Josephine Lok, Mark W. Majesky, Ziad Mallat, Muzi J. Maseko, Dianna M. Milewicz, Amanda L. Mohabeer, Augusto C. Montezano, Giorgio Mottola, Thomas Münzel, Daniel D. Myers, Karla B. Neves, Mark R. Nicolls, MingMing Ning, Andrea T. Obi, Guillermo Oliver, Renata Pasqualini, Alessandra Pasut, Alexandra Pislaru, Aleksander S. Popel, Raymundo A. Quintana, Arshed A. Quyyumi, Francisco J. Rios, Stanley G. Rockson, Martina Rudnicki, Junichi Saito, Charles D. Searles, Timothy W. Secomb, Cristina M. Sena, Richard L. Sidman, Federico Silva-Palacios, Tracey L. Smith, Suman Sood, Laurence S. Sperling, R. Sathish Srinivasan, Kimon Stamatelopoulos, Konstantinos Stellos, Naidi Sun, Wen Tian, Rhian M. Touyz, Nikolaos Ι. Vlachogiannis, Jessica E. Wagenseil, Thomas W. Wakefield, Charlotte R. Wayne, Changhong Xing, Ming Wai Yeung, Yu Zhang, and Chen Zhao

Published
2022

7. Resistance of Acta2

Author

Jiyuan, Chen, Kaveeta, Kaw, Hailong, Lu, Patricia M, Fagnant, Abhijnan, Chattopadhyay, Xue Yan, Duan, Zhen, Zhou, Shuangtao, Ma, Zhenan, Liu, Jian, Huang, Kristine, Kamm, James T, Stull, Callie S, Kwartler, Kathleen M, Trybus, and Dianna M, Milewicz

Subjects
actin folding, ACTA2, gene for smooth muscle α-actin, MRTF-A, myocardin-related transcription factor-A, Aortic Diseases, Mutation, Missense, SMC, smooth muscle cell, macromolecular substances, TIRF, total internal reflection fluorescence, Mice, SM, smooth muscle, RLC, regulatory light chain, Animals, Point Mutation, HTAD, heritable thoracic aortic disease, ACTA1, gene for skeletal muscle α-actin, Aorta, PE, phenylephrine, aortic disease, Actins, Mice, Inbred C57BL, L-NAME, l-Nω-nitroarginine methyl ester, smooth muscle actin, cardiovascular system, CCT, chaperonin-containing TCP-1, TAC, transverse aortic constriction, Chaperonin Containing TCP-1, Research Article
Abstract

Pathogenic variants of the gene for smooth muscle α-actin (ACTA2), which encodes smooth muscle (SM) α-actin, predispose to heritable thoracic aortic disease. The ACTA2 variant p.Arg149Cys (R149C) is the most common alteration; however, only 60% of carriers have a dissection or undergo repair of an aneurysm by 70 years of age. A mouse model of ACTA2 p.Arg149Cys was generated using CRISPR/Cas9 technology to determine the etiology of reduced penetrance. Acta2R149C/+ mice had significantly decreased aortic contraction compared with WT mice but did not form aortic aneurysms or dissections when followed to 24 months, even when hypertension was induced. In vitro motility assays found decreased interaction of mutant SM α-actin filaments with SM myosin. Polymerization studies using total internal reflection fluorescence microscopy showed enhanced nucleation of mutant SM α-actin by formin, which correlated with disorganized and reduced SM α-actin filaments in Acta2R149C/+ smooth muscle cells (SMCs). However, the most prominent molecular defect was the increased retention of mutant SM α-actin in the chaperonin-containing t-complex polypeptide folding complex, which was associated with reduced levels of mutant compared with WT SM α-actin in Acta2R149C/+ SMCs. These data indicate that Acta2R149C/+ mice do not develop thoracic aortic disease despite decreased contraction of aortic segments and disrupted SM α-actin filament formation and function in Acta2R149C/+ SMCs. Enhanced binding of mutant SM α-actin to chaperonin-containing t-complex polypeptide decreases the mutant actin versus WT monomer levels in Acta2R149C/+ SMCs, thus minimizing the effect of the mutation on SMC function and potentially preventing aortic disease in the Acta2R149C/+ mice.

Published
2021

8. Resistance of Acta2 mice to aortic disease is associated with defective release of mutant smooth muscle α-actin from the chaperonin-containing TCP1 folding complex

Author

Xue Yan Duan, Zhen Zhou, Kaveeta Kaw, Dianna M. Milewicz, Kristine E. Kamm, Abhijnan Chattopadhyay, James T. Stull, Jian Huang, Shuangtao Ma, Kathleen M. Trybus, Patricia M. Fagnant, Callie S. Kwartler, Zhenan Liu, Jiyuan Chen, and Hailong Lu

Subjects
Mutation, Contraction (grammar), biology, Chemistry, Mutant, Motility, macromolecular substances, Cell Biology, medicine.disease_cause, Biochemistry, Molecular biology, Chaperonin, Myosin, cardiovascular system, biology.protein, medicine, ACTA2, Molecular Biology, Actin
Abstract

Pathogenic variants of the gene for smooth muscle α-actin (ACTA2), which encodes smooth muscle (SM) α-actin, predispose to heritable thoracic aortic disease. The ACTA2 variant p.Arg149Cys (R149C) is the most common alteration; however, only 60% of carriers have a dissection or undergo repair of an aneurysm by 70 years of age. A mouse model of ACTA2 p.Arg149Cys was generated using CRISPR/Cas9 technology to determine the etiology of reduced penetrance. Acta2R149C/+ mice had significantly decreased aortic contraction compared with WT mice but did not form aortic aneurysms or dissections when followed to 24 months, even when hypertension was induced. In vitro motility assays found decreased interaction of mutant SM α-actin filaments with SM myosin. Polymerization studies using total internal reflection fluorescence microscopy showed enhanced nucleation of mutant SM α-actin by formin, which correlated with disorganized and reduced SM α-actin filaments in Acta2R149C/+ smooth muscle cells (SMCs). However, the most prominent molecular defect was the increased retention of mutant SM α-actin in the chaperonin-containing t-complex polypeptide folding complex, which was associated with reduced levels of mutant compared with WT SM α-actin in Acta2R149C/+ SMCs. These data indicate that Acta2R149C/+ mice do not develop thoracic aortic disease despite decreased contraction of aortic segments and disrupted SM α-actin filament formation and function in Acta2R149C/+ SMCs. Enhanced binding of mutant SM α-actin to chaperonin-containing t-complex polypeptide decreases the mutant actin versus WT monomer levels in Acta2R149C/+ SMCs, thus minimizing the effect of the mutation on SMC function and potentially preventing aortic disease in the Acta2R149C/+ mice.

Published
2021

9. Whole-Exome Sequencing in Familial Parkinson Disease

Author

Kaveeta Kaw, Hai Lin, Shalini N. Jhangiani, Preti Jain, Elizabeth W. Pugh, Zeynep H. Coban-Akdemir, Richard M. Myers, Kurt N. Hetrick, Hua Ling, Janson White, Janice L. Farlow, Laurie Robak, Joshua M. Shulman, Kevin M. Bowling, Tomasz Gambin, Dongbing Lai, Donna M. Muzny, Yunlong Liu, Shen Gu, Joseph Jankovic, James R. Lupski, Tatiana Foroud, Kimberly F. Doheny, Paula Porter, Eric Boerwinkle, and Richard A. Gibbs

Subjects
Adult, Male, 0301 basic medicine, Proband, Candidate gene, Neurogenetics, Disease, Biology, Bioinformatics, Cohort Studies, 03 medical and health sciences, symbols.namesake, 0302 clinical medicine, Parkinsonian Disorders, Humans, Exome, Genetic Predisposition to Disease, Family history, Exome sequencing, Aged, Sanger sequencing, Genetics, Genetic Variation, Tenascin, Sequence Analysis, DNA, Middle Aged, Protein-Tyrosine Kinases, 030104 developmental biology, Cohort, symbols, Female, Neurology (clinical), 030217 neurology & neurosurgery
Abstract

Importance Parkinson disease (PD) is a progressive neurodegenerative disease for which susceptibility is linked to genetic and environmental risk factors. Objective To identify genetic variants contributing to disease risk in familial PD. Design, Setting, and Participants A 2-stage study design that included a discovery cohort of families with PD and a replication cohort of familial probands was used. In the discovery cohort, rare exonic variants that segregated in multiple affected individuals in a family and were predicted to be conserved or damaging were retained. Genes with retained variants were prioritized if expressed in the brain and located within PD-relevant pathways. Genes in which prioritized variants were observed in at least 4 families were selected as candidate genes for replication in the replication cohort. The setting was among individuals with familial PD enrolled from academic movement disorder specialty clinics across the United States. All participants had a family history of PD. Main Outcomes and Measures Identification of genes containing rare, likely deleterious, genetic variants in individuals with familial PD using a 2-stage exome sequencing study design. Results The 93 individuals from 32 families in the discovery cohort (49.5% [46 of 93] female) had a mean (SD) age at onset of 61.8 (10.0) years. The 49 individuals with familial PD in the replication cohort (32.6% [16 of 49] female) had a mean (SD) age at onset of 50.1 (15.7) years. Discovery cohort recruitment dates were 1999 to 2009, and replication cohort recruitment dates were 2003 to 2014. Data analysis dates were 2011 to 2015. Three genes containing a total of 13 rare and potentially damaging variants were prioritized in the discovery cohort. Two of these genes ( TNK2 and TNR ) also had rare variants that were predicted to be damaging in the replication cohort. All 9 variants identified in the 2 replicated genes in 12 families across the discovery and replication cohorts were confirmed via Sanger sequencing. Conclusions and Relevance TNK2 and TNR harbored rare, likely deleterious, variants in individuals having familial PD, with similar findings in an independent cohort. To our knowledge, these genes have not been previously associated with PD, although they have been linked to critical neuronal functions. Further studies are required to confirm a potential role for these genes in the pathogenesis of PD.

Published
2016

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