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117 results on '"O'Meara, Caitlin C"'

1. Runx1 is sufficient but not required for cardiomyocyte cell cycle activation

Author

Akins, Kaelin A., primary, Flinn, Michael A., additional, Swift, Samantha K., additional, Chanjeevaram, Smrithi V., additional, Purdy, Alexandra L., additional, Buddell, Tyler, additional, Kolell, Mary E., additional, Andresen, Kaitlyn G., additional, Paddock, Samantha, additional, Buday, Sydney L., additional, O'Meara, Caitlin C., additional, Veldman, Matthew B., additional, and Patterson, Michaela, additional

Published
2024
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4. IL-13 promotes functional recovery after myocardial infarction via direct signaling to macrophages

Author

Alvarez-Argote, Santiago, primary, Paddock, Samantha J., additional, Flinn, Michael A., additional, Moreno, Caelan W., additional, Knas, Makenna C., additional, Almeida, Victor A., additional, Buday, Sydney L., additional, Bakhshian Nik, Amirala, additional, Patterson, Michaela, additional, Chen, Yi-Guang, additional, Lin, Chien-Wei, additional, and O’Meara, Caitlin C., additional

Published
2024
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6. Myofibroblast Ccn3 is regulated by Yap and Wwtr1 and contributes to adverse cardiac outcomes

Author

Flinn, Michael A., primary, Alvarez-Argote, Santiago, additional, Knas, Makenna C., additional, Almeida, Victor Alencar, additional, Paddock, Samantha J., additional, Zhou, Xiaoxu, additional, Buddell, Tyler, additional, Jamal, Ayana, additional, Taylor, Reiauna, additional, Liu, Pengyuan, additional, Drnevich, Jenny, additional, Patterson, Michaela, additional, Link, Brian A., additional, and O’Meara, Caitlin C., additional

Published
2023
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7. Collagen‐Specific HSP47 + Myofibroblasts and CD163 + Macrophages Identify Profibrotic Phenotypes in Deceased Hearts With SARS‐CoV‐2 Infections

Author

Puzyrenko, Andrii, primary, Jacobs, Elizabeth R., additional, Padilla, Nathan, additional, Devine, Adam, additional, Aljadah, Michael, additional, Gantner, Benjamin N., additional, Pan, Amy Y., additional, Lai, Shuping, additional, Dai, Qiang, additional, Rubenstein, Jason C., additional, North, Paula E., additional, Simpson, Pippa M., additional, Willoughby, Rodney E., additional, O'Meara, Caitlin C., additional, Flinn, Michael A., additional, Lough, John W., additional, Ibrahim, El‐Sayed H., additional, Zheng, Ze, additional, Sun, Yunguang, additional, Felix, Juan, additional, Hunt, Bryan C., additional, Ross, Gracious, additional, Rui, Hallgeir, additional, and Benjamin, Ivor J., additional

Published
2023
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8. Myofibroblast Ccn3 is regulated by Yap and Wwtr1 and contributes to adverse cardiac outcomes

Author

Flinn, Michael A., primary, Alvarez-Argote, Santiago, additional, Knas, Makenna C., additional, Almeida, Victor Alencar, additional, Paddock, Samantha J., additional, Zhou, Xiaoxu, additional, Buddell, Tyler, additional, Jamal, Ayana, additional, Liu, Pengyuan, additional, Drnevich, Jenny, additional, Patterson, Michaela, additional, Link, Brian A., additional, and O’Meara, Caitlin C., additional

Published
2022
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15. Collagen-Specific HSP47+ Myofibroblasts and CD163+ Macrophages Identify Profibrotic Phenotypes in Deceased Hearts With SARS-CoV-2 Infections.

Author

Puzyrenko, Andrii, Jacobs, Elizabeth R., Padilla, Nathan, Devine, Adam, Aljadah, Michael, Gantner, Benjamin N., Pan, Amy Y., Shuping Lai, Qiang Dai, Rubenstein, Jason C., North, Paula E., Simpson, Pippa M., Willoughby, Rodney E., O'Meara, Caitlin C., Flinn, Michael A., Lough, John W., Ibrahim, El-Sayed H., Ze Zheng, Yunguang Sun, and Felix, Juan

Published
2023
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16. Interleukin 4/13 signaling in cardiac regeneration and repair.

Author

Nik, Amirala Bakhshian, Alvarez-Argote, Santiago, and O’Meara, Caitlin C.

Subjects
CARDIAC regeneration, HEART development, WOUND healing, MYOCARDIAL injury, MACROPHAGE activation, RADIATION injuries, MYOCARDIAL infarction
Abstract

Interleukin 4 (IL4) and interleukin 13 (IL13) are closely related cytokines that have been classically attributed to type II immunity, namely, differentiation of T-helper 2 (TH2) cells and alternative activation of macrophages. Although the role of IL4/13 has been well described in various contexts such as defense against helminth parasites, pathogenesis of allergic disease, and several models of wound healing, relatively little is known about the role of IL4/13 in the heart following injury. Emerging literature has identified various roles for IL4/13 in animal models of cardiac regeneration as well as in the adult mammalian heart following myocardial injury. Notably, although IL4 and IL13 signal to hematopoietic cell types following myocardial infarction (MI) to promote wound healing phenotypes, there is substantial evidence that these cytokines can signal directly to non-hematopoietic cell types in the heart during development, homeostasis, and following injury. Comprehensive understanding of the molecular and cellular actions of IL4/13 in the heart is still lacking, but overall evidence to date suggests that activation of these cytokines results in beneficial outcomes with respect to cardiac repair. Here, we aim to comprehensively review the role of IL4 and IL13 and their prospective mechanisms in cardiac regeneration and repair. [ABSTRACT FROM AUTHOR]

Published
2022
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18. Reperfused vs. nonreperfused myocardial infarction: when to use which model

Author

Lindsey, Merry L., primary, de Castro Brás, Lisandra E., additional, DeLeon-Pennell, Kristine Y., additional, Frangogiannis, Nikolaos G., additional, Halade, Ganesh V., additional, O’Meara, Caitlin C., additional, Spinale, Francis G., additional, Kassiri, Zamaneh, additional, Kirk, Jonathan A., additional, Kleinbongard, Petra, additional, Ripplinger, Crystal M., additional, and Brunt, Keith R., additional

Published
2021
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19. A broadly applicable method for quantifying cardiomyocyte cell division identifies proliferative events following myocardial infarction

Author

Swift, Samantha K., Purdy, Alexandra L., Buddell, Tyler, Lovett, Jerrell J., Chanjeevaram, Smrithi V., Arkatkar, Anooj, O’Meara, Caitlin C., and Patterson, Michaela

Abstract

Cardiomyocyte proliferation is a challenging metric to assess. Current methodologies have limitations in detecting the generation of new cardiomyocytes and technical challenges that reduce widespread applicability. Here, we describe an improved cell suspension and imaging-based methodology that can be broadly employed to assess cardiomyocyte cell division in standard laboratories across a multitude of model organisms and experimental conditions. We highlight additional metrics that can be gathered from the same cell preparations to enable additional relevant analyses to be performed. We incorporate additional antibody stains to address potential technical concerns of miscounting. Finally, we employ this methodology with a dual-thymidine analog-labeling approach to a post-infarction murine model, which allowed us to robustly identify unique cycling events, such as cardiomyocytes undergoing multiple rounds of cell division.

Published
2024
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28. Soluble interleukin-13rα1: a circulating regulator of glucose

Author

Rachmin, Inbal, primary, O’Meara, Caitlin C., additional, Ricci-Blair, Elisabeth M., additional, Feng, Yilin, additional, Christensen, Emily M., additional, Duffy, Jeanne F., additional, Zitting, Kirsi M., additional, Czeisler, Charles A., additional, Pancoast, James R., additional, Cannon, Christopher P., additional, O’Donoghue, Michelle L., additional, Morrow, David A., additional, and Lee, Richard T., additional

Published
2017
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30. Yap is required for scar formation but not myocyte proliferation during heart regeneration in zebrafish.

Author

Flinn, Michael A, Jeffery, Brooke E, O'Meara, Caitlin C, and Link, Brian A

Subjects
CARDIAC regeneration, COFACTORS (Biochemistry), HEART development, RATTUS norvegicus, MORPHOGENESIS, SCARS
Abstract

Aims The Hippo signalling pathway regulates multiple cellular processes during organ development and maintenance by modulating activity of the transcriptional cofactor Yap. Core components of this pathway are required for neonatal mouse heart regeneration, however, investigations to date have typically focused on expression and activity in cardiomyocytes. Due to the regenerative capacity of zebrafish and the fact that global loss of Yap is not fully embryonic lethal in zebrafish, we leveraged a yap null mutant to investigate the impact of constitutive Yap deletion during zebrafish heart regeneration. Methods and results Following cryoinjury in adult hearts, myocyte proliferation was not decreased in yap mutants, contrary to expectations based on mouse data. Experiments in larval zebrafish (Danio rerio) revealed that deletion of either Yap or Taz had a modest effect on heart growth, reducing gross organ size, while their combined deletion was synergistic; thus, Yap and Taz share some overlapping roles in zebrafish heart development. Surprisingly, adult yap mutants exhibited decreased collagen composition at 7 days post-injury, suggesting a critical role for Yap in scar formation during heart regeneration. siRNA-mediated Yap knockdown in primary rat (Rattus norvegicus) cardiac cells revealed a fibroblast-specific role for Yap in controlling the expression of cytoskeletal and myofibroblast activation genes, as well as pro-inflammatory cyto/chemokines. Corroborating these RNAseq data, we observed increased macrophage infiltration in the scars of yap mutants at 7 days post-injury. Conclusion These results suggest that Yap deletion has minimal effect on myocyte proliferation in adults, but significantly influences scar formation and immune cell infiltration during zebrafish heart regeneration. Collectively, these data suggest an unexpected role for Yap in matrix formation and macrophage recruitment during heart regeneration. [ABSTRACT FROM AUTHOR]

Published
2019
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32. Nerves Regulate Cardiomyocyte Proliferation and Heart Regeneration

Author

Mahmoud, Ahmed I., primary, O’Meara, Caitlin C., additional, Gemberling, Matthew, additional, Zhao, Long, additional, Bryant, Donald M., additional, Zheng, Ruimao, additional, Gannon, Joseph B., additional, Cai, Lei, additional, Choi, Wen-Yee, additional, Egnaczyk, Gregory F., additional, Burns, Caroline E., additional, Burns, C. Geoffrey, additional, MacRae, Calum A., additional, Poss, Kenneth D., additional, and Lee, Richard T., additional

Published
2015
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33. SH2B3 Is a Genetic Determinant of Cardiac Inflammation and Fibrosis

Author

Flister, Michael J., primary, Hoffman, Matthew J., additional, Lemke, Angela, additional, Prisco, Sasha Z., additional, Rudemiller, Nathan, additional, O’Meara, Caitlin C., additional, Tsaih, Shirng-Wern, additional, Moreno, Carol, additional, Geurts, Aron M., additional, Lazar, Jozef, additional, Adhikari, Neeta, additional, Hall, Jennifer L., additional, and Jacob, Howard J., additional

Published
2015
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37. Identifying multiple causative genes at a single GWAS locus

Author

Flister, Michael J., primary, Tsaih, Shirng-Wern, additional, O'Meara, Caitlin C., additional, Endres, Bradley, additional, Hoffman, Matthew J., additional, Geurts, Aron M., additional, Dwinell, Melinda R., additional, Lazar, Jozef, additional, Jacob, Howard J., additional, and Moreno, Carol, additional

Published
2013
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38. SORCS1 contributes to the development of renal disease in rats and humans

Author

Lazar, Jozef, primary, O'Meara, Caitlin C., additional, Sarkis, Allison B., additional, Prisco, Sasha Z., additional, Xu, Haiyan, additional, Fox, Caroline S., additional, Chen, Ming-Huei, additional, Broeckel, Ulrich, additional, Arnett, Donna K., additional, Moreno, Carol, additional, Provoost, Abraham P., additional, and Jacob, Howard J., additional

Published
2013
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41. A 4.1-Mb Congenic Region of Rf-4 Contributes to Glomerular Permeability

Author

O’Meara, Caitlin C., primary, Lutz, Michelle M., additional, Sarkis, Allison B., additional, Xu, Haiyan, additional, Kothinti, Rajendra K., additional, Hoffman, Matthew, additional, Moreno, Carol, additional, Tabatabai, Niloofar M., additional, Lazar, Jozef, additional, Roman, Richard J., additional, and Jacob, Howard J., additional

Published
2012
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43. Cardiac myosin binding protein C regulates postnatal myocyte cytokinesis.

Author

Jianming Jiang, Burgon, Patrick G., Hiroko Wakimoto, Onoue, Kenji, Gorham, Joshua M., O'Meara, Caitlin C., Fomovsky, Gregory, McConnell, Bradley K., Lee, Richard T., Seidman, J. G., and Seidman, Christine E.

Subjects
CARRIER proteins, MYOSIN, HEART, EMBRYOLOGY, MUSCLE cells
Abstract

Homozygous cardiac myosin binding protein C-deficient (Mybpct/t) mice develop dramatic cardiac dilation shortly after birth; heart size increases almost twofold. We have investigated the mechanism of cardiac enlargement in these hearts. Throughout embryogenesis myocytes undergo cell division while maintaining the capacity to pump blood by rapidly disassembling and reforming myofibrillar components of the sarcomere throughout cell cycle progression. Shortly after birth, myocyte cell division ceases. Cardiac MYBPC is a thick filament protein that regulates sarcomere organization and rigidity. We demonstrate that many Mybpct/t myocytes undergo an additional round of cell division within 10 d postbirth compared with their wild-type counterparts, leading to increased numbers of mononuclear myocytes. Short-hairpin RNA knockdown of Mybpc3 mRNA in wild-type mice similarly extended the postnatal window of myocyte proliferation. However, adult Mybpct/t myocytes are unable to fully regenerate the myocardium after injury. MYBPC has unexpected inhibitory functions during postnatal myocyte cytokinesis and cell cycle progression. We suggest that human patients with homozygous MYBPC3-null mutations develop dilated cardiomyopathy, coupled with myocyte hyperplasia (increased cell number), as observed in Mybpct/t mice. Human patients, with heterozygous truncating MYBPC3 mutations, like mice with similar mutations, have hypertrophic cardiomyopathy. However, the mechanism leading to hypertrophic cardiomyopathy in heterozygous MYBPC3+/- individuals is myocyte hypertrophy (increased cell size), whereas the mechanism leading to cardiac dilation in homozygous Mybpc3-/- mice is primarily myocyte hyperplasia. [ABSTRACT FROM AUTHOR]

Published
2015
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46. Shroom3contributes to the maintenance of the glomerular filtration barrier integrity

Author

Yeo, Nan Cher, O’Meara, Caitlin C., Bonomo, Jason A., Veth, Kerry N., Tomar, Ritu, Flister, Michael J., Drummond, Iain A., Bowden, Donald W., Freedman, Barry I., Lazar, Jozef, Link, Brian A., and Jacob, Howard J.

Abstract

Genome-wide association studies (GWAS) identify regions of the genome correlated with disease risk but are restricted in their ability to identify the underlying causative mechanism(s). Thus, GWAS are useful “roadmaps” that require functional analysis to establish the genetic and mechanistic structure of a particular locus. Unfortunately, direct functional testing in humans is limited, demonstrating the need for complementary approaches. Here we used an integrated approach combining zebrafish, rat, and human data to interrogate the function of an established GWAS locus (SHROOM3) lacking prior functional support for chronic kidney disease (CKD). Congenic mapping and sequence analysis in rats suggested Shroom3was a strong positional candidate gene. Transferring a 6.1-Mb region containing the wild-type Shroom3gene significantly improved the kidney glomerular function in FHH (fawn-hooded hypertensive) rat. The wild-type Shroom3allele, but not the FHH Shroom3allele, rescued glomerular defects induced by knockdown of endogenous shroom3in zebrafish, suggesting that the FHH Shroom3allele is defective and likely contributes to renal injury in the FHH rat. We also show for the first time that variants disrupting the actin-binding domain of SHROOM3may cause podocyte effacement and impairment of the glomerular filtration barrier.

Published
2015
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48. Abstract 025.

Author

Yeo, Nan Cher, O'Meara, Caitlin C, Veth, Kerry N, Tomar, Ritu, Flister, Michael J, Drummond, Iain A, Lazar, Jozef, Link, Brian A, and Jacob, Howard J

Abstract

SHROOM3 has been associated with chronic kidney disease by genome-wide association studies (GWAS), yet its role in renal function and diseases was completely unknown. Here, we leveraged the integrated physiological genomic approach in rat models and zebrafish to dissect the renal function of SHROOM3 and its contribution to renal impairments. Congenic mapping and sequence analysis in rats suggested Shroom3 was a strong positional candidate gene. Transferring a 14.50-21.40 Mbp region of the BN (Brown Norway) chromosome 14 containing the Shroom3 gene onto the FHH (Fawn-Hooded Hypertensive) background significantly lowered the level of albuminuria (31.07±3.98 vs 51.92±5.69 mg/day; P=0.001), glomerular permeability to albumin (0.48±0.02 vs 0.59±0.02; P<0.001), and glomerular sclerosis (0.72±0.03 vs 1.82±0.05; P<0.001). The FHH Shroom3 allele contains 13 amino acid variants compared to BN rat. In vivo injection of the wild-type BN Shroom3 mRNA, but not the FHH Shroom3, rescued the glomerular leakage induced by endogenous knockdown of shroom3 in zebrafish, suggesting that the FHH Shroom3 allele is defective and likely contributes to glomerular impairments seen in the FHH rat. Functional screening of the 13 FHH Shroom3 variants identified a mutation, which decreased Shroom3 binding affinity to actins (5.85±2.69 vs 52.28±16.18; P<0.05) and consequently, impaired glomerular permeability. These results demonstrate that Shroom3-mediated interaction with actin is a crucial mechanism underlying the control of glomerular filtration barrier. Furthermore, we showed that podocyte-specific shroom3 disruption in zebrafish caused glomerular impairments and podocyte effacement, indicated by reduced foot process number (2.85±0.07 vs 4.2±0.35; P<0.001) and increased foot process size (319.85±19.42 vs 164.39±8.24 nm; P<0.001). Taken together, these experiments provide the first direct demonstration that Shroom3 is functionally involved in renal pathophysiology by the control of glomerular podocyte function. [ABSTRACT FROM AUTHOR]

Published
2014

49. Novel Insights into Post-Myocardial Infarction Cardiac Remodeling through Algorithmic Detection of Cell-Type Composition Shifts.

Author

Gural B, Kirkland L, Hockett A, Sandroni P, Zhang J, Rosa-Garrido M, Swift SK, Chapski D, Flinn MA, O'Meara CC, Vondriska TM, Patterson M, Jensen BC, and Rau CD

Abstract

Background: Recent advances in single cell sequencing have led to an increased focus on the role of cell-type composition in phenotypic presentation and disease progression. Cell-type composition research in the heart is challenging due to large, frequently multinucleated cardiomyocytes that preclude most single cell approaches from obtaining accurate measurements of cell composition. Our in silico studies reveal that ignoring cell type composition when calculating differentially expressed genes (DEGs) can have significant consequences. For example, a relatively small change in cell abundance of only 10% can result in over 25% of DEGs being false positives., Methods: We have implemented an algorithmic approach that uses snRNAseq datasets as a reference to accurately calculate cell type compositions from bulk RNAseq datasets through robust data cleaning, gene selection, and multi-sample cross-subject and cross-cell-type deconvolution. We applied our approach to cardiomyocyte-specific α1A adrenergic receptor (CM-α1A-AR) knockout mice. 8-12 week-old mice (either WT or CM-α1A-KO) were subjected to permanent left coronary artery (LCA) ligation or sham surgery (n=4 per group). Transcriptomes from the infarct border zones were collected 3 days later and analyzed using our algorithm to determine cell-type abundances, corrected differential expression calculations using DESeq2, and validated these findings using RNAscope., Results: Uncorrected DEGs for the CM-α1A-KO X LCA interaction term featured many cell-type specific genes such as Timp4 (fibroblasts) and Aplnr (cardiomyocytes) and overall GO enrichment for terms pertaining to cardiomyocyte differentiation (P=3.1E-4). Using our algorithm, we observe a striking loss of cardiomyocytes and gain in fibroblasts in the α1A-KO + LCA mice that was not recapitulated in WT + LCA animals, although we did observe a similar increase in macrophage abundance in both conditions. This recapitulates prior results that showed a much more severe heart failure phenotype in CM-α1A-KO + LCA mice. Following correction for cell-type, our DEGs now highlight a novel set of genes enriched for GO terms such as cardiac contraction (P=3.7E-5) and actin filament organization (P=6.3E-5)., Conclusions: Our algorithm identifies and corrects for cell-type abundance in bulk RNAseq datasets opening new avenues for research on novel genes and pathways as well as an improved understanding of the role of cardiac cell types in cardiovascular disease.

Published
2024
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50. Runx1 is sufficient but not required for cardiomyocyte cell-cycle activation.

Author

Akins KA, Flinn MA, Swift SK, Chanjeevaram SV, Purdy AL, Buddell T, Kolell ME, Andresen KG, Paddock S, Buday SL, Veldman MB, O'Meara CC, and Patterson M

Subjects
Animals, Regeneration, Mice, Animals, Newborn, Polyploidy, Mice, Inbred C57BL, Myocytes, Cardiac metabolism, Core Binding Factor Alpha 2 Subunit metabolism, Core Binding Factor Alpha 2 Subunit genetics, Cell Cycle, Cell Proliferation
Abstract

Factors responsible for cardiomyocyte proliferation could serve as potential therapeutics to stimulate endogenous myocardial regeneration following insult, such as ischemic injury. A previously published forward genetics approach on cardiomyocyte cell cycle and ploidy led us to the transcription factor, Runx1 . Here, we examine the effect of Runx1 on cardiomyocyte cell cycle during postnatal development and cardiac regeneration using cardiomyocyte-specific gain- and loss-of-function mouse models. RUNX1 is expressed in cardiomyocytes during early postnatal life, decreases to negligible levels by 3 wk of age, and increases upon myocardial injury, all consistent with observed rates of cardiomyocyte cell-cycle activity. Loss of Runx1 transiently stymied cardiomyocyte cell-cycle activity during normal postnatal development, a result that corrected itself and did not extend to the context of neonatal heart regeneration. On the other hand, cardiomyocyte-specific Runx1 overexpression resulted in an expansion of diploid cardiomyocytes in uninjured hearts and expansion of 4 N cardiomyocytes in the context of neonatal cardiac injury, suggesting Runx1 overexpression is sufficient to induce cardiomyocyte cell-cycle responses. Persistent overexpression of Runx1 for >1 mo continued to promote cardiomyocyte cell-cycle activity resulting in substantial hyperpolyploidization (≥8 N DNA content). This persistent cell-cycle activation was accompanied by ventricular dilation and adverse remodeling, raising the concern that continued cardiomyocyte cell cycling can have detrimental effects. NEW & NOTEWORTHY Runx1 is sufficient but not required for cardiomyocyte cell cycle.

Published
2024
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