Embryonic Heart (embryonic + heart)

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Distribution within Life Sciences

Terms modified by Embryonic Heart

  • embryonic heart development

  • Selected Abstracts


    Tropomyosin expression and dynamics in developing avian embryonic muscles

    CYTOSKELETON, Issue 5 2008
    Jushuo Wang
    Abstract The expression of striated muscle proteins occurs early in the developing embryo in the somites and forming heart. A major component of the assembling myofibrils is the actin-binding protein tropomyosin. In vertebrates, there are four genes for tropomyosin (TM), each of which can be alternatively spliced. TPM1 can generate at least 10 different isoforms including the striated muscle-specific TPM1, and TPM1,. We have undertaken a detailed study of the expression of various TM isoforms in 2-day-old (stage HH 10,12; 33 h) heart and somites, the progenitor of future skeletal muscles. Both TPM1, and TPM1, are expressed transiently in embryonic heart while TPM1, is expressed in somites. Both RT-PCR and in situ hybridization data suggest that TPM1, is expressed in embryonic heart whereas TPM1, is expressed in embryonic heart, and also in the branchial arch region of somites, and in the somites. Photobleaching studies of Yellow Fluorescent Protein-TPM1, and -TPM1, expressed in cultured avian cardiomyocytes revealed that the dynamics of the two probes was the same in both premyofibrils and in mature myofibrils. This was in sharp contrast to skeletal muscle cells in which the fluorescent proteins were more dynamic in premyofibrils. We speculate that the differences in the two muscles is due to the appearance of nebulin in the skeletal myocytes premyofibrils transform into mature myofibrils. Cell Motil. Cytoskeleton 2008. © 2008 Wiley-Liss, Inc. [source]


    Role of VEGF and tissue hypoxia in patterning of neural and vascular cells recruited to the embryonic heart

    DEVELOPMENTAL DYNAMICS, Issue 11 2009
    Hongbin Liu
    Abstract We hypothesized that oxygen gradients and hypoxia-responsive signaling may play a role in the patterning of neural or vascular cells recruited to the developing heart. Endothelial progenitor and neural cells are recruited to and form branched structures adjacent to the relatively hypoxic outflow tract (OFT) myocardium from stages 27,32 (ED6.5,7.5) of chick development. As determined by whole mount confocal microscopy, the neural and vascular structures were not anatomically associated. Adenoviral delivery of a VEGF trap dramatically affected the remodeling of the vascular plexus into a coronary tree while neuronal branching was normal. Both neuronal and vascular branching was diminished in the hearts of embryos incubated under hyperoxic conditions. Quantitative analysis of the vascular defects using our recently developed VESGEN program demonstrated reduced small vessel branching and increased vessel diameters. We propose that vascular and neural patterning in the developing heart share dependence on tissue oxygen gradients but are not interdependent. Developmental Dynamics 238:2760,2769, 2009. © 2009 Wiley-Liss, Inc. [source]


    Origin and fate of cardiac mesenchyme

    DEVELOPMENTAL DYNAMICS, Issue 10 2008
    Brian S. Snarr
    Abstract The development of the embryonic heart is dependent upon the generation and incorporation of different mesenchymal subpopulations that derive from intra- and extra-cardiac sources, including the endocardium, epicardium, neural crest, and second heart field. Each of these populations plays a crucial role in cardiovascular development, in particular in the formation of the valvuloseptal apparatus. Notwithstanding shared mechanisms by which these cells are generated, their fate and function differ profoundly by their originating source. While most of our early insights into the origin and fate of the cardiac mesenchyme has come from experimental studies in avian model systems, recent advances in transgenic mouse technology has enhanced our ability to study these cell populations in the mammalian heart. In this article, we will review the current understanding of the role of cardiac mesenchyme in cardiac morphogenesis and discuss several new paradigms based on recent studies in the mouse. Developmental Dynamics 237:2804,2819, 2008. © 2008 Wiley-Liss, Inc. [source]


    NG2 proteoglycan is expressed exclusively by mural cells during vascular morphogenesis

    DEVELOPMENTAL DYNAMICS, Issue 2 2001
    Ugur Ozerdem
    Abstract Immunofluorescence mapping demonstrates that the NG2 proteoglycan is invariably expressed by the mural cell component of mouse neovascular structures. This pattern is independent of the developmental mechanism responsible for formation of the vasculature (vasculogenesis or angiogenesis). Thus, NG2 is expressed in the embryonic heart by cardiomyocytes, in developing macrovasculature by smooth muscle cells, and in nascent microvessels by vascular pericytes. Due to the scarcity of proven markers for developing pericytes, NG2 is especially useful for identification of this cell type. The utility of NG2 as a pericyte marker is illustrated by two observations. First, pericytes are associated with endothelial tubes at an early point in microvessel development. This early interaction between pericytes and endothelial cells has important implications for the role of pericytes in the development and stabilization of microvascular tubes. Second, the pericyte to endothelial cell ratio in developing capillaries varies from tissue to tissue. Because the extent of pericyte investment is likely to affect the physical properties of the vessel in question, it is important to understand the mechanisms that control this process. Additional insight into these and other aspects of vascular morphogenesis should be possible through use of NG2 as a mural cell marker. © 2001 Wiley-Liss, Inc. [source]


    Cell death and differentiation in the development of the endocardial cushion of the embryonic heart

    MICROSCOPY RESEARCH AND TECHNIQUE, Issue 5 2002
    Eltyeb Abdelwahid
    Abstract The transformation of the endocardial cushion into valves and septa is a critical step in cardiac morphogenesis as it initiates the development of the four-chambered heart. This transformation results from a region-specific balance between cellular proliferation, apoptosis, and differentiation. The development of the form and structure of the endocardial cushion is accompanied by precise patterns of abundant cell death having the morphological features of programmed cell death (apoptosis), which plays an important role in the elimination of redundant cells and in changes of phenotypic composition during histogenesis. Apoptosis is an essential process in morphogenesis as it balances mitosis in renewing tissues. It is controlled by one or more genetic programs that kill the targeted cell. However, the causes, role, and regulation of apoptosis in the developing endocardial cushion still remain to be determined. The clarification of the role of the apoptosis regulatory genes constitutes a major task in future studies of cell death in the developing heart. This new molecular histology of heart development awaits further experiments to clarify the interactive mechanisms that act to ensure the sculpting of the endocardial cushion into valves and septa by determining the size of the cushion cell populations. The relation between the expression of different factors and the modifications of the cushion region during cardiac development are reviewed. In addition, we review and summarize information on molecules identified in our experiments that imply the activity of a number of essential genes coinciding with the key steps in generating the overall architecture of the heart. We correlate their temporal and spatial expression with their proposed roles. Microsc. Res. Tech. 58:395,403, 2002. © 2002 Wiley-Liss, Inc. [source]


    TBX3 and its splice variant TBX3 + exon 2a are functionally similar

    PIGMENT CELL & MELANOMA RESEARCH, Issue 3 2008
    Willem M.H. Hoogaars
    Summary Tbx3, a member of the conserved family of T-box developmental transcription factors, is a transcriptional repressor required during cardiogenesis for the formation and specification of the sinoatrial node, the pacemaker of the heart. Both the TBX3 and the highly related TBX2 genes are also associated with several cancers, most likely as a consequence of their powerful anti-senescence properties mediated via suppression p14Arf and p21CIP expression. In melanoma, the TBX2 gene is frequently amplified and inhibition of Tbx2 function leads to senescence and up-regulation of p21CIP, a Tbx2 target gene. Tbx3 + 2a is a splice variant containing an extra 20 amino acids encoded by exon 2a inserted into the highly conserved T-box DNA-binding domain. We find here that Tbx3 + 2a is evolutionary conserved and that similar insertions are largely absent from the T-box domains of other T-box factors. Tbx3 + 2a has been reported to lack DNA-binding ability and act as a functional antagonist of Tbx3. By contrast, we now demonstrate that both Tbx3 and Tbx3 + 2a bind the consensus T-element, the p21CIP1 promoter, and the Nppa cardiac target gene. Both isoforms also function as repressors of p21CIP1 and Nppa promoter activity and interact with homeobox factor Nkx2-5. When ectopically expressed in the embryonic heart of mice, Tbx3 and Tbx3 + 2a both suppressed chamber formation and repressed expression of cardiac chamber markers Nppa and Cx40. The results suggest that in the assays used, Tbx3 and Tbx3 + 2a are functionally equivalent and that like Tbx2, Tbx3 may also function as an anti-senescence factor in melanoma. [source]


    Expression of Lymphatic Markers During Avian and Mouse Cardiogenesis

    THE ANATOMICAL RECORD : ADVANCES IN INTEGRATIVE ANATOMY AND EVOLUTIONARY BIOLOGY, Issue 2 2010
    Ganga Karunamuni
    Abstract The adult heart has been reported to have an extensive lymphatic system, yet the development of this important system during cardiogenesis is still largely unexplored. The nuclear-localized transcription factor Prox-1 identified a sheet of Prox-1-positive cells on the developing aorta and pulmonary trunk in avian and murine embryos just before septation of the four heart chambers. The cells coalesced into a branching lymphatic network that spread within the epicardium to cover the heart. These vessels eventually expressed the lymphatic markers LYVE-1, VEGFR-3, and podoplanin. Before the Prox-1-positive cells were detected in the mouse epicardium, LYVE-1, a homologue of the CD44 glycoprotein, was primarily expressed in individual epicardial cells. Similar staining patterns were observed for CD44 in avian embryos. The proximity of these LYVE-1/CD44-positive mesenchymal cells to Prox-1-positive vessels suggests that they may become incorporated into the lymphatics. Unexpectedly, we detected LYVE-1/PECAM/VEGFR-3-positive vessels within the embryonic and adult myocardium, which remained Prox-1/podoplanin-negative. Lymphatic markers were surprisingly found in adult rat and embryonic mouse epicardial cell lines, with Prox-1 also exhibiting nuclear-localized expression in primary cultures of embryonic avian epicardial cells. Our data identified three types of cells in the embryonic heart expressing lymphatic markers: (1) Prox-1-positive cells from an extracardiac source that migrate within the serosa of the outflow tract into the epicardium of the developing heart, (2) individual LYVE-1-positive cells in the epicardium that may be incorporated into the Prox-1-positive lymphatic vasculature, and (3) LYVE-1-positive cells/vessels in the myocardium that do not become Prox-1-positive even in the adult heart. Anat Rec, 2010. © 2009 Wiley-Liss, Inc. [source]


    Abnormal Myocardial and Coronary Vasculature Development in Experimental Hypoxia

    THE ANATOMICAL RECORD : ADVANCES IN INTEGRATIVE ANATOMY AND EVOLUTIONARY BIOLOGY, Issue 10 2008
    Ondrej Nanka
    Freshly isolated quail embryonic heart at Hamburger-Hamilton stage 28, stained with voltage sensitive dye and optically mapped to reveal ventricular activation pattern (indicated by color isochrones in 1 ms intervals). The activation wave sweeps from left to right in the direction of the arrow. Maturation of ventricular activation patterns is accelerated by hypoxic incubation, as described in detail together with other changes in ventricular angio- and myoarchitecture. From "Abnormal Myocardial and coronary Vasculature Development in Experimental Hypoxia," by Ondrej Nanka, et al., on page 1187, in this issue. [source]


    Vasculogenesis of the embryonic heart: Origin of blood island-like structures

    THE ANATOMICAL RECORD : ADVANCES IN INTEGRATIVE ANATOMY AND EVOLUTIONARY BIOLOGY, Issue 3 2006
    Anna Ratajska
    Abstract The earliest vascular structures (blood island-like) in the embryonic heart are clusters of angioblasts and nucleated red blood cells (NRBCs), which differentiate into endothelial cells and erythrocytes, respectively. Our purpose was to define the area and chronology of NRBC appearance in the mouse embryonic heart at the stages before a patency between coronary vessels and peripheral circulation is established (10.5,13.5 dpc). Before and at the onset of vascularization, NBCs were not present within the proepicardium; however, Ter/119+ differentiating erythroblasts and single scattered CD45+ were found in the heart beginning from 10.5 dpc. The Ter/119+ cells were in close apposition to angioblasts (PECAM1+) and were recognized as components of blood island-like structures or vascular vesicles in transmission electron microscope and were located mostly in the subepicardium. Some of the NRBCs were not accompanied by angioblasts and located close to the endocardial endothelium or at the border of the endocardial endothelium or in the subepicardium. These erythroblasts were beginning to assemble with angioblasts. CD34+ NBCs as well as progenitor cells of erythroid lineage were not detected in the heart at these stages of development. The state of differentiation of NRBCs of blood islands was similar/the same as the morphology of circulating blood cells at the respective stages of embryo development. The presence of mature NRBCs in the subendocardial area and lack of progenitor cells of erythroid lineage within the heart indicate that erythroid commitment occurs outside the heart. We suggest that NRBCs enter the heart from the blood stream at 10.5,12 dpc independently from angioblasts. © 2006 Wiley-Liss, Inc. [source]


    Neurocan in the embryonic avian heart and vasculature

    THE ANATOMICAL RECORD : ADVANCES IN INTEGRATIVE ANATOMY AND EVOLUTIONARY BIOLOGY, Issue 2 2003
    Noboru Mishima
    Abstract The chondroitin sulfate proteoglycan (CSPG) neurocan was previously considered to be nervous-system specific. However, we have found neurocan in the embryonic heart and vasculature. In stage 11 quail embryos, neurocan was prominently expressed in the myocardium, dorsal mesocardium, heart-forming fields, splanchnic mesoderm, and vicinity of the extraembryonic vaculature, and at lower levels in the endocardium. A comparison of neurocan staining with QH1 staining of vascular endothelial cells demonstrates that neurocan is frequently expressed by cells adjacent to endothelial cells, rather than by endothelial cells themselves. In some cases, a dispersed subset of cells are neurocan-positive in a field of cells that otherwise appear uniform in morphology. Later in development, neurocan expression becomes relatively limited to the nervous system. However, even in 10-day embryos, neurocan is expressed in the chorio-allantoic membrane in the tissue that separates closely packed, small-diameter blood vessels. In summary, our results suggest that neurocan may function as a barrier that regulates vascular patterning during development. Anat Rec Part A 272A: 556,562, 2003. © 2003 Wiley-Liss, Inc. [source]


    Evidence by Expression Analysis of Candidate Genes for Congenital Heart Defects in the NF1 Microdeletion Interval

    ANNALS OF HUMAN GENETICS, Issue 5 2005
    M. Venturin
    Summary It was recently reported that congenital heart disease is significantly more frequent in patients with NF1 microdeletion syndrome than in those with classical NF1. The outcome of congenital heart disease in this subset of patients is likely caused by the haploinsufficiency of gene/s in the deletion interval. Following in silico analysis of the deleted region, we found two genes known to be expressed in adult heart, the Joined to JAZF1 (SUZ12) and the Centaurin-alpha 2 (CENTA2) genes, and seven other genes with poorly defined patterns of expression and function. With the aim of defining their expression profiles in human fetal tissues (15th,21st weeks of gestation), expression analysis by RT-PCR and Northern blotting was performed. C17orf40, SUZ12 and CENTA2 were found to be mainly expressed in fetal heart, and following RT-PCR on mouse embryos and embryonic heart and brain at different stages of development, we found that the orthologous genes C17orf40, Suz12 and Centa2 are also expressed in early stages of development, before and during the formation of the four heart chambers. The presence of binding sites for Nkx2-5, a transcription factor expressed early in heart development, in all three mouse orthologous genes was predicted by bioinformatics, thus reinforcing the hypothesis that these genes might be involved in heart development and may be plausible candidates for congenital heart disease. [source]


    Teratogenic effects of bis-diamine on the developing myocardium

    BIRTH DEFECTS RESEARCH, Issue 3 2004
    Nobuhiko Okamoto
    Abstract BACKGROUND Bis-diamine induces conotruncal anomalies and disproportional ventricular development in rat embryos when administered to the mother. To evaluate the mechanisms of disproportional ventricular development in the anomalous heart, we analyzed the morphology of the embryonic heart and investigated cardiomyocytic DNA synthesis and apoptosis. METHODS A single dose of 200 mg of bis-diamine was administered to pregnant rats Wistar on day 9.5 of pregnancy. The embryos were removed on each embryonic day from 10.5 to 18.5. Expression of cardiotrophin-1 and hepatocyte growth factor was investigated on the sections, and cardiotrophin-1, hepatocyte growth factor and myocyte enhancer factor 2 mRNA expression was examined by reverse transcriptase,polymerase chain reaction. Myocardial DNA synthesis was investigated using 5-bromo-2,-deoxyuridine and the labeling index was calculated for each heart. Apoptosis was also analyzed using TUNEL reaction and electrophoresis of DNA fragmentation. RESULTS The embryos treated with bis-diamine had conotruncal anomalies associated with thin left ventricular wall in the later stage. The labeling index on embryonic day 15.5 and 16.5 was significantly lower than those in the controls. Hepatocyte growth factor and cardiotrophin-1 mRNA expression was upregulated on embryonic day 12.5 and 15.5 in bis-diamine,treated hearts. Fewer apoptotic cells were detected in the hearts of bis-diamine,treated embryos than in control hearts from embryonic day 14.5 to 16.5. CONCLUSIONS The ventricular disproportion in the bis-diamine,treated heart may be caused by the early myocardial differentiation delay and poor proliferation and reduced apoptosis associated with anomalous circulatory condition in the later stage. Birth Defects Research (Part A), 2004. © 2004 Wiley-Liss, Inc. [source]


    Patterning the heart, a template for human cardiomyocyte development

    DEVELOPMENTAL DYNAMICS, Issue 7 2006
    Susana M. Chuva de Sousa Lopes
    Abstract Although in mice, the dynamics of gene expression during heart development is well characterized, information on humans is scarce due to the limited availability of material. Here, we analyzed the transcriptional distribution of Mlc-2a, Mlc-1v, Mlc-2v, and atrial natriuretic factor (ANF) in human embryonic hearts between 7 and 18 weeks of gestation and in healthy and hypertrophic adult hearts by in situ hybridization and compared expression with that in mice. Strikingly, Mlc-2a, Mlc-1v, and ANF, which are essentially chamber-restricted in mice by mid-gestation, showed a broader distribution in humans. On the other hand, Mlc-2v may prove to be an adequate ventricular marker in humans in contrast to mouse. This study emphasizes the importance of careful comparative human,animal analyses during embryonic development and adulthood, as avoiding erroneous extrapolations may be critical to develop new and successful myocardial replacement therapies. Development Dynamics 235:1994,2002, 2006. © 2006 Wiley-Liss, Inc. [source]


    Melatonin and its analogs potentiate the nifedipine-sensitive high-voltage-activated calcium current in the chick embryonic heart cells

    JOURNAL OF PINEAL RESEARCH, Issue 1 2001
    Y.A. Mei
    Effects of melatonin and its analogs on the voltage-activated calcium current of embryonic chick ventricular cardiomyocytes were investigated. Myocytes were dissociated from 14- to 16-day-old chicks (yellow Red Rob) embryonic hearts and cultured for 2,3 days. Calcium currents were studied by the patch-clamp technique. Whole-cell current recording showed nifedipine-sensitive, high-voltage-activated L-type calcium current inactivated in 70,100 ms during the voltage step period of 200 ms. There was no evidence of low-voltage-activated T-type calcium channels. Melatonin (ejected solution: 50 ,mol/L melatonin; concentration at the vicinity of recording cell: about 1,5 ,mol/L melatonin) and its analogs, 2-iodomelatonin and 2-iodo-n-butanol-5-methoxytryptamine, significantly increased the amplitude of the calcium current by 42,62%. The effect of melatonin on the L-type calcium current was not desensitised by repeated melatonin treatment. Our results suggest a specific melatonin receptor-mediated action on the calcium channel of the embryonic chick myocyte. The melatonin-induced increase in high-voltage calcium current may increase myocyte contractility and enhance cardiac output. A regulatory role of melatonin on the chick cardiac function should be further considered. [source]


    Expression pattern of neuronal and skeletal muscle voltage-gated Na+ channels in the developing mouse heart

    THE JOURNAL OF PHYSIOLOGY, Issue 3 2005
    Volker Haufe
    In the mammalian heart, a variety of voltage-gated Na+ channel transcripts and proteins have been detected. However, little quantitative information is available on the abundance of each transcript during development, or the contribution of TTX-sensitive Na+ channels to the cardiac sodium current (INa). Using competitive and real-time RT-PCR we investigated the transcription of six Na+ channels (Nav1.1,Nav1.6) and the ,1 subunit during mouse heart development. Nav1.5 was predominantly expressed in the adult heart, whereas the splice variant Nav1.5a was the major Na+ channel isoform in embryonic hearts. The TTX-resistant Na+ channel transcripts (Nav1.5 and Nav1.5a) increased 1.7-fold during postnatal development. Transcripts encoding TTX-sensitive Na+ channels (Nav1.1,Nav1.4) and the ,1 subunit gradually increased up to fourfold from postnatal day (P)1 to P126, while the Nav1.6 transcript level remained low and constant over the same period. In adults, TTX-sensitive channel mRNA accounted for 30,40% of the channel pool in whole-heart preparations (Nav1.3 > Nav1.4 > Nav1.2 , Nav1.1 , Nav1.6), and 16% in mRNA from isolated cardiomyocytes (Nav1.4 > Nav1.3 > Nav1.2 > Nav1.1 > Nav1.6). Confocal immunofluorescence on ventricular myocytes suggested that Nav1.1 and Nav1.2 were localized at the intercalated disks and in the t tubules. Nav1.3 labelling predominantly produced a diffuse but strong intracellular signal. Nav1.6 fluorescence was detected only along the Z lines. Electrophysiological recordings showed that TTX-sensitive and TTX-resistant Na+ channels, respectively, accounted for 8% and 92% of the INa in adult ventricular cardiomyocytes. Our data suggest that neuronal and skeletal muscle Na+ channels contribute to the action potential of cardiomyocytes in the adult mammalian heart. [source]


    Trichloroethylene effects on gene expression during cardiac development

    BIRTH DEFECTS RESEARCH, Issue 7 2003
    J. Michael Collier
    Abstract BACKGROUND Halogenated hydrocarbon exposure is associated with changes in gene expression in adult and embryonic tissue. Our study was undertaken to identify differentially expressed mRNA transcripts in embryonic hearts from Sprague-Dawley rats exposed to trichloroethylene (TCE) or potential bio-transformation products dichloroethylene (DCE) and trichloroacetic acid (TCAA). METHODS cDNA subtractive hybridization was used to selectively amplify expressed mRNA obtained from control or halogenated hydrocarbon exposed rat embryos. The doses used were 1100 and 110 ppm (8300 and 830 ,M) TCE, 110 and 11 ppm (1100 and 110 ,M) DCE, and 27.3 and 2.75 mg/ml (100 and 10 mM) TCAA. Control animals were given distilled drinking water throughout the period of experiments. RESULTS Sequencing of over 100 clones derived from halogenated hydrocarbon exposed groups resulted in identification of numerous differentially regulated gene sequences. Up-regulated transcripts identified include genes associated with stress response (Hsp 70) and homeostasis (several ribosomal proteins). Down-regulated transcripts include extracellular matrix components (GPI-p137 and vimentin) and Ca2+ responsive proteins (Serca-2 Ca2+ -ATPase and ,-catenin). Two possible markers for fetal TCE exposure were identified: Serca-2 Ca2+ -ATPase and GPI-p137, a GPI-linked protein of unknown function. Differential regulation of expression of both markers by TCE was confirmed by dot blot analysis and semi-quantitative RT-PCR with levels of TCE exposure between 100 and 250 ppb (0.76 and 1.9 ,M) sufficient to decrease expression. CONCLUSIONS Sequences down-regulated with TCE exposure appear to be those associated with cellular housekeeping, cell adhesion, and developmental processes, while TCE exposure up-regulates expression of numerous stress response and homeostatic genes. Birth Defects Research (Part A) 67488,495, 2003. © 2003 Wiley-Liss, Inc. [source]