scholarly journals Characterization of a common progenitor pool of the epicardium and myocardium

Science ◽  
2021 ◽  
pp. eabb2986
Author(s):  
Richard C. V. Tyser ◽  
Ximena Ibarra-Soria ◽  
Katie McDole ◽  
Satish A. Jayaram ◽  
Jonathan Godwin ◽  
...  
Keyword(s):  
Cardiac Development ◽  
Cell Types ◽  
Trophic Factors ◽  
Mouse Heart ◽  
Genetic Lineage ◽  
Cardiac Cell ◽  
Embryonic Mouse ◽  
Cardiac Progenitors ◽  
Multiple Cell ◽  
Definition Of

The mammalian heart is derived from multiple cell lineages; however, our understanding of when and how the diverse cardiac cell types arise is limited. We mapped the origin of the embryonic mouse heart at single-cell resolution using a combination of transcriptomic, imaging, and genetic lineage labeling approaches. This provided a transcriptional and anatomic definition of cardiac progenitor types. Furthermore, it revealed a cardiac progenitor pool that is anatomically and transcriptionally distinct from currently known cardiac progenitors. Besides contributing to cardiomyocytes, these cells also represent the earliest progenitor of the epicardium, a source of trophic factors and cells during cardiac development and injury. This study provides detailed insights into the formation of early cardiac cell types, with particular relevance to the development of cell-based cardiac regenerative therapies.

scholarly journals Outflow Tract Formation—Embryonic Origins of Conotruncal Congenital Heart Disease

2021 ◽  
Vol 8 (4) ◽  
pp. 42
Author(s):  
Sonia Stefanovic ◽  
Heather C. Etchevers ◽  
Stéphane Zaffran
Keyword(s):  
Congenital Heart ◽  
Cardiac Development ◽  
Heart Defects ◽  
Dynamic Structure ◽  
Cell Types ◽  
Outflow Tract ◽  
Heart Tube ◽  
Heart Field ◽  
Multiple Cell ◽  
The Many

Anomalies in the cardiac outflow tract (OFT) are among the most frequent congenital heart defects (CHDs). During embryogenesis, the cardiac OFT is a dynamic structure at the arterial pole of the heart. Heart tube elongation occurs by addition of cells from pharyngeal, splanchnic mesoderm to both ends. These progenitor cells, termed the second heart field (SHF), were first identified twenty years ago as essential to the growth of the forming heart tube and major contributors to the OFT. Perturbation of SHF development results in common forms of CHDs, including anomalies of the great arteries. OFT development also depends on paracrine interactions between multiple cell types, including myocardial, endocardial and neural crest lineages. In this publication, dedicated to Professor Andriana Gittenberger-De Groot and her contributions to the field of cardiac development and CHDs, we review some of her pioneering studies of OFT development with particular interest in the diverse origins of the many cell types that contribute to the OFT. We also discuss the clinical implications of selected key findings for our understanding of the etiology of CHDs and particularly OFT malformations.

Abstract 255: A Fibroblast Population Shares A Developmental Origin With Cardiovascular Lineages

2014 ◽  
Vol 115 (suppl_1) ◽  
Author(s):  
Sara Ranjbarvaziri ◽  
Shah Ali ◽  
Mahmood Talkhabi ◽  
Peng Zhao ◽  
Young-Jae Nam ◽  
...  
Keyword(s):  
Heart Development ◽  
Cardiac Fibroblasts ◽  
Immunohistochemical Analysis ◽  
Cell Types ◽  
Mouse Heart ◽  
Developmental Potential ◽  
Reporter Mice ◽  
Significant Difference ◽  
Definition Of

Rationale: The traditional definition of “cardiovascular” lineages describes the eponymous cell types - cardiomyoctes, endothelial cells, and smooth muscle cells - that arise from a common mesodermal progenitor cell during heart development. Fibroblasts are an abundant mesenchymal population in the mammalian heart which may have multiple, discrete developmental origins. Mesp1 represents the earliest marker of cardiovascular progenitors, contributing to the majority of cardiac lineages. To date no link between Mesp1 and fibroblast generation has been reported. Objective: We hypothesized progenitor cells expressing Mesp1 can also give rise to cardiac fibroblasts during heart development. Methods and Results: We generated Mesp1cre/+;R26RmTmG reporter mice where Cre-mediated recombination results in GFP activation in all Mesp1 expressing cells and their progeny. To explore their developmental potential, we isolated GFP+ cells from E7.5 Mesp1cre/+;R26RmTmG mouse. In vitro culture and transplantation studies into SCID mouse kidney capsule as wells as chick embryos showed fibroblastic adoption. Results showed that at E9.5 Mesp1+ and Mesp1- progenitors contributed to the proepicardium organ and later at E11.5 they formed epicardium. Analysis of adult hearts demonstrated that the majority of cardiac fibroblasts are derived from Mesp1 expressing cells. Immunohistochemical analysis of heart sections demonstrated expression of fibroblast markers (including DDR2, PDGFRα and Col1) in cells derived from both Mesp1+ and Mesp1- progenitors. Additionally, we investigated whether the two distinct fibroblast populations have different potency towards reprogramming to cardiomyocytes. Results showed no significant difference between Mesp1 and non-Mesp1 isolated fibroblasts to convert to cardiomyocyte fate. Conclusions: Our data demonstrates that cardiovascular progenitors expressing Mesp1 contribute to the proepicardium. These cells, as cardiovascular progenitors, also give rise to the highest portion of cardiac fibroblasts in the mouse heart.

scholarly journals Abcg2 labels multiple cell types in skeletal muscle and participates in muscle regeneration

2011 ◽  
Vol 195 (1) ◽  
pp. 147-163 ◽  
Author(s):  
Michelle J. Doyle ◽  
Sheng Zhou ◽  
Kathleen Kelly Tanaka ◽  
Addolorata Pisconti ◽  
Nicholas H. Farina ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Satellite Cells ◽  
Muscle Regeneration ◽  
Side Population ◽  
Cell Types ◽  
Lineage Tracing ◽  
Skeletal Muscle Regeneration ◽  
Genetic Lineage ◽  
Multiple Cell ◽  
A Minor

Skeletal muscle contains progenitor cells (satellite cells) that maintain and repair muscle. It also contains muscle side population (SP) cells, which express Abcg2 and may participate in muscle regeneration or may represent a source of satellite cell replenishment. In Abcg2-null mice, the SP fraction is lost in skeletal muscle, although the significance of this loss was previously unknown. We show that cells expressing Abcg2 increased upon injury and that muscle regeneration was impaired in Abcg2-null mice, resulting in fewer centrally nucleated myofibers, reduced myofiber size, and fewer satellite cells. Additionally, using genetic lineage tracing, we demonstrate that the progeny of Abcg2-expressing cells contributed to multiple cell types within the muscle interstitium, primarily endothelial cells. After injury, Abcg2 progeny made a minor contribution to regenerated myofibers. Furthermore, Abcg2-labeled cells increased significantly upon injury and appeared to traffic to muscle from peripheral blood. Together, these data suggest an important role for Abcg2 in positively regulating skeletal muscle regeneration.

Transplantation of embryonic stem cells into the infarcted mouse heart: formation of multiple cell types

2006 ◽  
Vol 40 (1) ◽  
pp. 195-200 ◽  
Author(s):  
Dinender K. Singla ◽  
Timothy A. Hacker ◽  
Lining Ma ◽  
Pamela S. Douglas ◽  
Ruth Sullivan ◽  
...  
Keyword(s):  
Stem Cells ◽  
Embryonic Stem Cells ◽  
Embryonic Stem ◽  
Cell Types ◽  
Mouse Heart ◽  
Multiple Cell ◽  
Heart Formation

scholarly journals Effects of metabolic acidosis on intracellular pH responses in multiple cell types

2014 ◽  
Vol 307 (12) ◽  
pp. R1413-R1427 ◽  
Author(s):  
Ahlam Ibrahim Salameh ◽  
Vernon A. Ruffin ◽  
Walter F. Boron
Keyword(s):  
Metabolic Acidosis ◽  
Intracellular Ph ◽  
Skeletal Muscles ◽  
Individual Cell ◽  
Cell Types ◽  
Cell Type ◽  
Ratiometric Fluorescence ◽  
Multiple Cell ◽  
Definition Of ◽  
The Individual

Metabolic acidosis (MAc), a decrease in extracellular pH (pHo) caused by a decrease in [HCO3−]o at a fixed [CO2]o, is a common clinical condition and causes intracellular pH (pHi) to fall. Although previous work has suggested that MAc-induced decreases in pHi (ΔpHi) differ among cell types, what is not clear is the extent to which these differences are the result of the wide variety of methodologies employed by various investigators. In the present study, we evaluated the effects of two sequential MAc challenges (MAc1 and MAc2) on pHi in 10 cell types/lines: primary-cultured hippocampal (HCN) neurons and astrocytes (HCA), primary-cultured medullary raphé (MRN) neurons, and astrocytes (MRA), CT26 colon cancer, the C2C12 skeletal muscles, primary-cultured bone marrow-derived macrophages (BMDM) and dendritic cells (BMDC), Ink4a/ARF-null melanocytes, and XB-2 keratinocytes. We monitor pHi using ratiometric fluorescence imaging of 2′,7′-bis-(2-carboxyethyl)-5-(and-6)-carboxyfluorescein while imposing MAc: lowering (pHo) from 7.4 to 7.2 by decreasing [HCO3−]o from 22 to 14 mM at 5% CO2 for 7 min. After MAc1, we return cells to the control solution for 10 min and impose MAc2. Using our definition of MAc resistance [(ΔpHi/ΔpHo) ≤ 40%], during MAc1, ∼70% of CT26 and ∼50% of C2C12 are MAc-resistant, whereas the other cell types are predominantly MAc-sensitive. During MAc2, some cells adapt [(ΔpHi/ΔpHo)2 < (ΔpHi/ΔpHo)1], particularly HCA, C2C12, and BMDC. Most maintain consistent responses [(ΔpHi/ΔpHo)2 ≅ (ΔpHi/ΔpHo)1], and a few decompensate [(ΔpHi/ΔpHo)2>(ΔpHi/ΔpHo)1], particularly HCN, C2C12, and XB-2. Thus, responses to twin MAc challenges depend both on the individual cell and cell type.

scholarly journals From Stripes to a Beating Heart: Early Cardiac Development in Zebrafish

2021 ◽  
Vol 8 (2) ◽  
pp. 17
Author(s):  
Cassie L. Kemmler ◽  
Fréderike W. Riemslagh ◽  
Hannah R. Moran ◽  
Christian Mosimann
Keyword(s):  
Congenital Heart Defects ◽  
Heart Development ◽  
Congenital Heart ◽  
Cardiac Development ◽  
Heart Defects ◽  
Lineage Tracing ◽  
Genetic Lineage ◽  
Zebrafish Model ◽  
Lateral Plate ◽  
Cardiac Progenitors

The heart is the first functional organ to form during vertebrate development. Congenital heart defects are the most common type of human birth defect, many originating as anomalies in early heart development. The zebrafish model provides an accessible vertebrate system to study early heart morphogenesis and to gain new insights into the mechanisms of congenital disease. Although composed of only two chambers compared with the four-chambered mammalian heart, the zebrafish heart integrates the core processes and cellular lineages central to cardiac development across vertebrates. The rapid, translucent development of zebrafish is amenable to in vivo imaging and genetic lineage tracing techniques, providing versatile tools to study heart field migration and myocardial progenitor addition and differentiation. Combining transgenic reporters with rapid genome engineering via CRISPR-Cas9 allows for functional testing of candidate genes associated with congenital heart defects and the discovery of molecular causes leading to observed phenotypes. Here, we summarize key insights gained through zebrafish studies into the early patterning of uncommitted lateral plate mesoderm into cardiac progenitors and their regulation. We review the central genetic mechanisms, available tools, and approaches for modeling congenital heart anomalies in the zebrafish as a representative vertebrate model.

scholarly journals Single cell transcriptional profiling reveals cellular diversity, communication, and sexual dimorphism in the mouse heart

2017 ◽  
Author(s):  
Daniel A. Skelly ◽  
Galen T. Squiers ◽  
Micheal A. McLellan ◽  
Mohan T. Bolisetty ◽  
Paul Robson ◽  
...  
Keyword(s):  
Sexual Dimorphism ◽  
Single Cell ◽  
Cell Biology ◽  
Immune Cell ◽  
Cardiac Development ◽  
Transcriptional Profiling ◽  
Cell Populations ◽  
Mouse Heart ◽  
Cardiac Cell ◽  
Immune Sensing

INTRODUCTORY PARAGRAPHCharacterization of the cardiac cellulome—the network of cells that form the heart—is essential for understanding cardiac development and normal organ function, and for formulating precise therapeutic strategies to combat heart disease. Recent studies have challenged assumptions about both the cellular composition1 and functional significance of the cardiac non-myocyte cell pool, with unexpected roles identified for resident fibroblasts2 and immune cell populations3,4. In this study, we characterized single-cell transcriptional profiles of the murine non-myocyte cardiac cellular landscape using single-cell RNA sequencing (scRNA-Seq). Detailed molecular analyses revealed the diversity of the cardiac cellulome and facilitated the development of novel techniques to isolate understudied cardiac cell populations such as mural cells and glia. Our analyses also revealed networks of intercellular communication as well as extensive sexual dimorphism in gene expression in the heart, most notably demonstrated by the upregulation of immune-sensing and pro-inflammatory genes in male cardiac macrophages. This study offers new insights into the structure and function of the mammalian cardiac cellulome and provides an important resource that will stimulate new studies in cardiac cell biology.

Transcriptional regulation of early cardiovascular development

2018 ◽  
Author(s):  
F. Gabriella Fulcoli ◽  
Antonio Baldini
Keyword(s):  
Transcription Factors ◽  
Current Knowledge ◽  
Cell Types ◽  
Regulatory Elements ◽  
Developmental Time ◽  
Special Focus ◽  
Cardiovascular Development ◽  
Cardiac Progenitors ◽  
Multiple Cell

The two major cardiac cell lineages of the vertebrate heart, the first and second cardiac fields (FHF and SHF), have different developmental ontogeny and thus different transcription programs. Most remarkably, the fate of cardiac progenitors (CPs) of the FHF is restricted to cardiomyocyte differentiation. In contrast, SHF CPs, which are specified independently, are maintained in a multipotent state for a relatively longer developmental time and can differentiate into multiple cell types. The identity of the transcription factors and regulatory elements involved in progenitor cell programming and fate are only now beginning to emerge. Apparent inconsistencies between studies based on tissue culture and in vivo embryonic studies confirm that the ontogeny of cardiac progenitors is strongly driven or affected by regionalization, and thus by the signals that they receive in different regions. This chapter summarizes current knowledge about transcription factors and mechanisms driving CP ontogeny, with special focus on SHF development.

scholarly journals Embryonic Mouse Cardiodynamic OCT Imaging

2020 ◽  
Vol 7 (4) ◽  
pp. 42
Author(s):  
Andrew L. Lopez ◽  
Shang Wang ◽  
Irina V. Larina
Keyword(s):  
Blood Flow ◽  
Congenital Heart Defects ◽  
Heart Development ◽  
Congenital Heart ◽  
Cardiac Development ◽  
Heart Defects ◽  
Cellular Level ◽  
Mouse Heart ◽  
Embryonic Mouse ◽  
Insight Into

The embryonic heart is an active and developing organ. Genetic studies in mouse models have generated great insight into normal heart development and congenital heart defects, and suggest mechanical forces such as heart contraction and blood flow to be implicated in cardiogenesis and disease. To explore this relationship and investigate the interplay between biomechanical forces and cardiac development, live dynamic cardiac imaging is essential. Cardiodynamic imaging with optical coherence tomography (OCT) is proving to be a unique approach to functional analysis of the embryonic mouse heart. Its compatibility with live culture systems, reagent-free contrast, cellular level resolution, and millimeter scale imaging depth make it capable of imaging the heart volumetrically and providing spatially resolved information on heart wall dynamics and blood flow. Here, we review the progress made in mouse embryonic cardiodynamic imaging with OCT, highlighting leaps in technology to overcome limitations in resolution and acquisition speed. We describe state-of-the-art functional OCT methods such as Doppler OCT and OCT angiography for blood flow imaging and quantification in the beating heart. As OCT is a continuously developing technology, we provide insight into the future developments of this area, toward the investigation of normal cardiogenesis and congenital heart defects.

scholarly journals Coupled myovascular expansion directs growth and regeneration of the neonatal mouse heart

2021 ◽  
Author(s):  
Paige DeBenedittis ◽  
Anish Karpurapu ◽  
Albert Henry ◽  
Michael C Thomas ◽  
Timothy J McCord ◽  
...  
Keyword(s):  
Cell Types ◽  
Neonatal Mouse ◽  
Border Zone ◽  
Mouse Heart ◽  
Heart Regeneration ◽  
Cardiac Growth ◽  
Spatial Coupling ◽  
Epicardial Cells ◽  
Multiple Cell ◽  
Vegfr2 Signaling

ABSTRACTInnate heart regeneration in zebrafish and neonatal mammals requires multiple cell types, such as epicardial cells, nerves, and macrophages, to enable proliferation of spared cardiomyocytes (CMs). How these cells interact to create growth niches is unclear. Here we profile proliferation kinetics of cardiac endothelial cells (CECs) and CMs in the neonatal mouse heart and find that CM and CEC expansion is spatiotemporally coupled. We show that coupled myovascular expansion during cardiac growth or regeneration is dependent upon VEGF-VEGFR2 signaling, as genetic deletion of Vegfr2 from CECs or inhibition of VEGFA abrogates both CEC and CM proliferation. Repair of cryoinjury, a model of incomplete regeneration, displays poor spatial coupling of CEC and CM proliferation. Boosting CEC density in the border zone by injection of virus encoding Vegfa enhances CM proliferation and the efficacy of heart regeneration, suggesting that revascularization strategies to increase CEC numbers may be an important adjunct for approaches designed to promote CM proliferation after injury. Finally, we use a human Mendelian randomization study to demonstrate that circulating VEGFA levels are positively associated with higher myocardial mass among healthy individuals, suggesting similar effects on human cardiac growth. Our work demonstrates the importance of coupled CEC and CM expansion for cardiomyogenesis and reveals the presence of a myovascular niche that underlies cardiac growth and regeneration.

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