Differential growth and multicellular villi direct proepicardial translocation to the developing mouse heart.

In the mammalian system the proepicardium (PE) arises from mesothelium of the septum transversum before translocation to the heart where it forms the epicardium and progenitor cells of the coronary vessels. Despite its importance, the process in which PE cells translocate to the myocardium in mammals is not well defined. The current paradigm states that cellular cysts of PE float across the pericardial space and contact the outer surface of the myocardium. This mechanism does not provide a satisfactory explanation for the directionality or localization of PE migration. To better define PE migration, we performed a detailed study of mouse PE development. We provide thorough documentation that redefines the size of the PE migratory field and the mechanism of migration. Our new model incorporates differential growth and direct contact between multicellular PE villi and the myocardium as mechanisms in formation of the epicardium.     

Developmental Progression of the Coronary Vasculature in Human Embryos and Fetuses

Although considerable advances in our understanding of mammalian and avian embryonic coronary development have occurred during the last decade, our current knowledge of this topic in humans is limited. Accordingly, the aim of this study was to determine if the development of the human coronary vasculature in humans is like that of other mammals and avians. The data document a progression of events involving mesenchymal cell‐containing villi from the proepicardium, establishment of blood islands and a capillary network. The major finding of the study is direct evidence that the capillary plexus associated with spindle cells and erythroblasts invades the base of the aorta to form coronary ostia. A role for the dorsal mesocardium is also indicated by the finding that cells from this region are continuous with the aorta and pulmonary artery. The development of the tunica media of the coronary arteries follows the same base‐apex progression as in other species, with the development of branches occurring late in the embryonic period. The fetal period is characterized by 1) growth and a numerical increase in the smallest arterial branches, veins, and venules, 2) innervation of arteries, and 3) inclusion of elastic fibers in the tunica media of the coronary arteries and development of the tunica adventitia. In conclusion, the data demonstrate that the development of the coronary system in humans is similar to that of other mammalian and avian species, and for the first time documents that the formation of the ostia and coronary stems in humans occurs by ingrowth of a vascular plexus and associated cells from the epicardium. Anat Rec, 299:25–41, 2016. © 2015 Wiley Periodicals, Inc.     

PDGF-A as an epicardial mitogen during heart development.

In the developing heart, reciprocal interactions between the epicardium and myocardium drive further sublineage specification and ventricular chamber morphogenesis. Several observations suggest that the epicardium is a source of secreted factors that influence cardiomyocyte proliferation, and these factors may have other roles as well. However, the identity of these epicardial factors remains mostly unknown. We have identified platelet-derived growth factor-A (PDGF-A) as one of several mitogens expressed by the rat EMC epicardial cell line (epicardial mesothelial cells), by embryonic epicardium and myocardium during mouse heart development, and by adult epicardium. Expression of the cognate receptor gene Pdgfra was detected in the epicardium, although a low level of expression in myocardium could not be ruled out. To address the potential role of PDGF signaling in heart development, we mutated both PDGF receptor genes in the myocardial and mesodermal compartments of the heart; however, this did not result in an observable cardiac phenotype. This finding suggests that mesodermal PDGF signaling is not essential in heart development, although its role may be redundant with other signaling pathways. Indeed, our results demonstrate the presence of additional mitogens that may have such an overlapping role.     

Altered haemodynamics causes aberrations in the epicardium

During embryo development, the heart is the first functioning organ. Although quiescent in the adult, the epicardium is essential during development to form a normal four‐chambered heart. Epicardial‐derived cells contribute to the heart as it develops with fibroblasts and vascular smooth muscle cells. Previous studies have shown that a heartbeat is required for epicardium formation, but no study to our knowledge has shown the effects of haemodynamic changes on the epicardium. Since the aetiologies of many congenital heart defects are unknown, we suggest that an alteration in the heart's haemodynamics might provide an explanatory basis for some of them. To change the heart's haemodynamics, outflow tract (OFT) banding using a double overhang knot was performed on HH21 chick embryos, with harvesting at different developmental stages. The epicardium of the heart was phenotypically and functionally characterised using a range of techniques. Upon alteration of haemodynamics, the epicardium exhibited abnormal morphology at HH29, even though migration of epicardial cells along the surface of the heart was found to be normal between HH24 and HH28. The abnormal epicardial phenotype was exacerbated at HH35 with severe changes in the structure of the extracellular matrix (ECM). A number of genes tied to ECM production were also differentially expressed in HH29 OFT‐banded hearts, including DDR2 and collagen XII. At HH35, the differential expression of these genes was even greater with additional downregulation of collagen I and TCF21. In this study, the epicardium was found to be severely impacted by altered haemodynamics upon OFT banding. The increased volume of the epicardium at HH29, upon OFT‐banding, and the expression changes of ECM markers were the first indicative signs of aberrations in epicardial architecture; by HH35, the phenotype had progressed. The decrease in epicardial thickness at HH35 suggests an increase in tension, with a force acting perpendicular to the surface of the epicardium. Although the developing epicardium and the blood flowing through the heart are separated by the endocardium and myocardium, the data presented here demonstrate that altering the blood flow affects the structure and molecular expression of the epicardial layer. Due to the intrinsic role the epicardium in cardiogenesis, defects in epicardial formation could have a role in the formation of a wide range of congenital heart defects.     

Avian embryonic coronary arterio‐venous patterning involves the contribution of different endothelial and endocardial cell populations

Background: Coronary vasculature irrigates the myocardium and is crucial to late embryonic and adult heart function. Despite the developmental significance and clinical relevance of these blood vessels, the embryonic origin and the cellular and molecular mechanisms that regulate coronary arterio‐venous patterning are not known in detail. In this study, we have used the avian embryo to dissect the ontogenetic origin and morphogenesis of coronary vasculature. Results: We show that sinus venosus endocardial sprouts and proepicardial angioblasts pioneer coronary vascular formation, invading the developing heart simultaneously. We also report that avian ventricular endocardium has the potential to contribute to coronary vessels, and describe the incorporation of cardiac distal outflow tract endothelial cells to the peritruncal endothelial plexus to participate in coronary vascular formation. Finally, our findings indicate that large sinus venosus‐independent sections of the forming coronary vasculature develop without connection to the systemic circulation and that coronary arterio‐venous shunts form a few hours before peritruncal arterial endothelium connects to the aortic root. Conclusions: Embryonic coronary vasculature is a developmental mosaic, formed by the integration of vascular cells from, at least, four different embryological origins, which assemble in a coordinated manner to complete coronary vascular development. Developmental Dynamics 247:686–698, 2018. © 2017 Wiley Periodicals, Inc.     

Morphological and molecular left–right asymmetries in the development of the proepicardium: A comparative analysis on mouse and chick embryos

The proepicardium (PE) is an embryonic progenitor cell population that delivers the epicardium, the majority of the cardiac interstitium, and the coronary vasculature. In the present study, we compared PE development in mouse and chick embryos. In the mouse, a left and a right PE anlage appear simultaneously, which subsequently merge at the embryonic midline to form a single PE. In chick embryos, the right PE anlage appears earlier than the left and only the right anlage acquires the full PE‐phenotype. The left anlage remains in a rudimentary state. The expression patterns of PE marker genes (Tbx18, Wt1) correspond to the morphological data, being bilateral in the mouse and unilateral in the chick. Bmp4, which is unilaterally expressed in the right PE of chick embryos, is symmetrically expressed in the sinus venosus wall cranial to the PE in mouse embryos. Asymmetric development of the chicken PE might reflect side‐specific differences in topographical relationships to tissues with PE‐inducing or repressing activity or might result from the PE‐repressing activity of the right PE, which grows earlier. To test these hypotheses, we analyzed PE development in chick embryos, firstly, subsequent to experimentally induced inversion of PE topographical relationships to neighbouring tissues; secondly, in organ cultures; and, thirdly, subsequent to induction of cardia bifida. In all three experiments, only the right PE develops the full PE phenotype. Our results suggest that PE development might be controlled by the L–R pathway in the chick but not in the mouse embryo. Developmental Dynamics 236:684–695, 2007. © 2007 Wiley‐Liss, Inc.     

Dynamics of follicular growth and atresia of large follicles during the ovarian cycle of the guinea pig: Fate of the degenerating follicles,a quantitative study

Background: A quantitative integrated study of healthy ovarian follicles of different sizes and their mitotic activity and of clearly defined atretic stages of involuting large growing follicles at different stages of the guinea pig ovarian cycle is not available in the literature. We considered that such a study would reveal new aspects of ovarian tissue dynamics and provide new information in an organ with a continuous phenotypic transformation of its cellular components. Methods: Ovaries from guinea pigs were removed on days 1 (opening of the vagina), 3, 6, 9, 13, and 16 of the cycle, and the following were measured in serial sections: (1) total number of healthy follicles falling into categories based on the volume occupied by granulosa cells, (2) total number of atretic follicles falling into clearly defined morphological stages of the degenerative and involutionary process affecting medium to large follicles, and (3) proportion of metaphase-arrested granulosa cells, after colcemid injection, in healthy follicles of different size categories. Results: Dynamic patterns of follicular growth and degeneration were revealed that permitted the following main conclusions and observations: (1) small to middle-size follicles can reach the maximal category mass of granulosa mass within 6–7 days, and the number of granulosa cells can increase 6–7-fold during this interval, (2) the cohort that gives rise to 2–6 preovulatory follicles and to the large follicles that will undergo atresia during each cycle varied from 68 to 108 follicles, (3) cell death starts in the granulosa cell layers of large follicles even when neighbouring cells maintain a high mitotic activity and it spreads rapidly; dead granulosa cells are cleare by nucleolysis and cytolysis in the absence of blood leucocytes or neovascularization, (4) foci of atresia are observed also in a few preovulatory follicles, (5) antral cavities of follicles with dead granulosa cells in the process of being lysed shrink and are filled within 2–3 days with large fibroblast-like cells arising from phenotypic transformation of inner layers of theca interna, with no evidence of mitotic activity or angiogenesis; the outer layers of theca interna involute, and by progressive atrophy and a process of cell death, minute nodular structures arise with remnants of the ovum and zona pellucida, and (6) a transient wave of degeneration affects a proportion of small and middle-size follicles during the metestrous period. This process does not resemble the morphological phenomenology of follicular involution, which affects only large follicles. Conclusions: This study contributes to a fuller understanding of the dynamics and time relationships of follicular growth and loss in the guinea pig ovary and provides new morphogenetic information on the atretic process. It would be valuable for the design of experiments on endocrine and paracrine interactions involved in follicular growth and atresia. © 1995 Wiley-Liss, Inc.     

Platelet‐derived growth factor is involved in the differentiation of second heart field‐derived cardiac structures in chicken embryos

For the establishment of a fully functional septated heart, addition of myocardium from second heart field‐derived structures is important. Platelet‐derived growth factors (PDGFs) are known for their role in cardiovascular development. In this study, we aim to elucidate this role of PDGF‐A, PDGF‐C, and their receptor PDGFR‐α. We analyzed the expression patterns of PDGF‐A, ‐C, and their receptor PDGFR‐α during avian heart development. A spatiotemporal pattern of ligands was seen with colocalization of the PDGFR‐α. This was found in second heart field‐derived myocardium as well as the proepicardial organ (PEO) and epicardium. Mechanical inhibition of epicardial outgrowth as well as chemical disturbance of PDGFR‐α support a functional role of the ligands and the receptor in cardiac development. Developmental Dynamics 238:2658–2669, 2009. © 2009 Wiley‐Liss, Inc.     

PDGF-B signaling is important for murine cardiac development: its role in developing atrioventricular valves, coronaries, and cardiac innervation.

We hypothesized that PDGF-B/PDGFR-beta-signaling is important in the cardiac contribution of epicardium-derived cells and cardiac neural crest, cell lineages crucial for heart development. We analyzed hearts of different embryonic stages of both Pdgf-b-/- and Pdgfr-beta-/- mouse embryos for structural aberrations with an established causal relation to defective contribution of these cell lineages. Immunohistochemical staining for alphaSMA, periostin, ephrinB2, EphB4, VEGFR-2, Dll1, and NCAM was performed on wild-type and knockout embryos. We observed that knockout embryos showed perimembranous and muscular ventricular septal defects, maldevelopment of the atrioventricular cushions and valves, impaired coronary arteriogenesis, and hypoplasia of the myocardium and cardiac nerves. The abnormalities correspond with models in which epicardial development is impaired and with neuronal neural crest-related innervation deficits. This implies a role for PDGF-B/PDGFR-beta-signaling specifically in the contribution of these cell lineages to cardiac development.     

The identification of different endothelial cell populations within the mouse proepicardium

The proepicardium is a transient embryonic structure that is a source of precursors of the epicardium, coronary smooth muscle cells, and may be a source of coronary endothelial cells (EC). To better understand proepicardium development a systematic analysis of EC appearance was performed. Multiple marker analysis showed that EC are present in the mouse proepicardium at embryonic day (E) 9.0 through E9.75. Distinct populations of EC were found that were associated with the liver bud, and the sinus venosus, as well as a population that do not appear to be associated with either of these structures. There was a temporal increase in the number of EC and temporal changes in the distribution of EC within the different populations during PE development. These findings indicate that EC exist in the proepicardium before coronary vasculogenesis, and support a model in which there is a heterogeneous origin for EC in the proepicardium.     

The Development of the Epicardium in the Sturgeon Acipenser naccarii

This article reports on the development of the epicardium in alevins of the sturgeon Acipenser naccarii, aged 4–25 days post‐hatching (dph). Epicardial development starts at 4 dph with formation of the proepicardium (PE) that arises as a bilateral structure at the boundary between the sinus venosus and the duct of Cuvier. The PE later becomes a midline organ arising from the wall of the sinus venosus and ending at the junction between the liver, the sinus venosus and the transverse septum. This relative displacement appears related to venous reorganization at the caudal pole of the heart. The mode and time of epicardium formation is different in the various heart chambers. The conus epicardium develops through migration of a cohesive epithelium from the PE villi, and is completed through bleb‐like aggregates detached from the PE. The ventricular epicardium develops a little later, and mostly through bleb‐like aggregates. The bulbus epicardium appears to derive from the mesothelium located at the junction between the outflow tract and the pericardial cavity. Strikingly, formation of the epicardium of the atrium and the sinus venosus is a very late event occurring after the third month of development. Associated to the PE, a sino‐ventricular ligament develops as a permanent connection. This ligament contains venous vessels that communicate the subepicardial coronary plexus and the sinus venosus, and carries part of the heart innervation. The development of the sturgeon epicardium shares many features with that of other vertebrate groups. This speaks in favour of conservative mechanisms across the evolutionary scale. Anat Rec, 2009. © 2009 Wiley‐Liss, Inc.     

Cardiac malformations in Pdgfrα mutant embryos are associated with increased expression of WT1 and Nkx2.5 in the second heart field

Platelet‐derived growth factor receptor alpha (Pdgfrα) identifies cardiac progenitor cells in the posterior part of the second heart field. We aim to elucidate the role of Pdgfrα in this region. Hearts of Pdgfrα‐deficient mouse embryos (E9.5–E14.5) showed cardiac malformations consisting of atrial and sinus venosus myocardium hypoplasia, including venous valves and sinoatrial node. In vivo staining for Nkx2.5 showed increased myocardial expression in Pdgfrα mutants, confirmed by Western blot analysis. Due to hypoplasia of the primary atrial septum, mesenchymal cap, and dorsal mesenchymal protrusion, the atrioventricular septal complex failed to fuse. Impaired epicardial development and severe blebbing coincided with diminished migration of epicardium‐derived cells and myocardial thinning, which could be linked to increased WT1 and altered α4‐integrin expression. Our data provide novel insight for a possible role for Pdgfrα in transduction pathways that lead to repression of Nkx2.5 and WT1 during development of posterior heart field–derived cardiac structures. Developmental Dynamics 239:2307–2317, 2010. © 2010 Wiley‐Liss, Inc.     

Understanding the roles of basophils: breaking dawn

Early studies that used parasite-infected interleukin-4 (IL-4) reporter animals led us to identify basophils as the primary source of IL-4 and hence propose the hypothesis that basophils trigger the development of antigen-specific T helper type 2 (Th2) immune responses in vivo. These findings appeared to resolve a long-standing puzzle underlying Th2 immunity, that is, ‘what is the source of the initial IL-4 necessary for CD4 T-cell differentiation into Th2 effector cells?’. However, results from extensive investigations of the contribution of basophils to Th2 immunity unveiled some controversial data that cast doubt on the initial hypothesis. In this review, the consensus and the controversy regarding the roles of basophils in infection and immunity, as well as outstanding questions for the future, are discussed.     

Interleukin 9 and its Receptor: An Overview of Structure and Function

Interleukin-9 (IL-9) is a multifunctional cytokine produced by activated TH2 clones in vitro and during TH2-like T cell responses in vivo. Although IL-9 was initially described as a T cell growth factor, its role in T cell responses is still unclear. While freshly isolated normal T cells do not respond to IL-9, this cytokine induces the proliferation of murine T cell lymphomas in vitro, and in vivo overexpression of IL-9 results in the development of thymic lymphomas. In the human, the existence of an IL-9 mediated autocrine loop has been suggested for some malignancies such as Hodgkin's disease. Various observations indicate that IL-9 is actively involved in mast cells responses by inducing the proliferation and differentiation of these cells. Other potential biological targets for IL-9 include B lymphocytes, and hematopoietic progenitors, for which higher responses were observed with foetal or transformed cells as compared to normal adult progenitors. The IL-9 receptor is a member of the hemopoietin receptor superfamily and interacts with the 7 chain of the IL-2 receptor for signaling. Signal transduction studies have stressed the role of the Jak-STAT pathway in various IL-9 bioactivities, whereas the 4PS/IRS2 adaptor protein might also play a significant role in IL-9 signaling.     

Macrophages: Current Views on Their Differentiation, Structure, and Function

Macrophages are large mononuclear phagocytes that represent the major differentiated elements of the mononuclear phagocytic system. They arise from distinct progenitors in the bone marrow, and their immediate precursors, the monocytes, emigrate from the vascular compartment into many tissues and organs where they develop into mature macrophages. The latter display diverse morphological and functional characteristics, depending on the environmental stimuli that they receive. This phenotypic heterogeneity is, therefore, the final consequence of a series of down-regulation of some cellular processes and the up-regulation of others. The kinetics of the production of macrophages and their participation in various physiological and pathological phenomena is the subject of this review.     

The Fate of Intravenously Administered bFGF and the Effect of Heparin

Abstract

The fate and effects of intravascular bFGF are unknown. We have investigated the fate of bFGF administered intravenously to rats in the presence and absence of heparin, and evaluated the effect of a 3-day IV infusion of bFGF on proliferation of endothelial and vascular smooth muscle cells in situ. [¹²⁵I]bFGF, administered as an IV bolus, was rapidly cleared from the circulation (t_1/2 = 1.5 min) by the liver. Nevertheless, it was maintained at a constant, predictable concentration in the blood (9.7 ± 4% of the amount infused) by continuous IV infusion. Heparin consistently altered the pattern: slowing the rate of clearance (t_1/2 = 4.5 min), increasing the plateau concentration in the blood during continuous infusion (32.5 ± 14.3% of the amount infused), and allowing intact (as determined by gel analysis) bFGF to cross from the circulation into the urine. A 3-day infusion of bFGF alone (2.5 ng/kg/min) and with adenosine (11.6 μM/kg/hr) did not increase [³H]thymidine incorporation in either endothelial cells or vascular smooth muscle cells, suggesting that they are refractory to this factor when it is administered intravascularly.