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Query: UNIPROT:Q9UIJ5 (
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58,342
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Previous studies of coronary artery ontogeny have stressed early development and therefore have dwelt mainly upon the origin of the endothelium of the nascent coronary artery stem. This study has analyzed the ontogeny of the vascular smooth muscle cells (VSMC) in the coronary arteries of the domestic chicken, by establishing the timing and deployment of
smooth muscle alpha-actin
(SMAA). Anti-SMAA was applied to sections of normal embryos, and to sections of experimental embryos that had undergone surgical ablation of the neural crest over somites 1-3. The results show an orderly symmetrical deployment of SMAA in control coronary arteries. SMAA was expressed significantly earlier in the coronary artery VSMC compared with those of the cardiac outflow vessels; this early expression may indicate a unique responsiveness to induction of the smooth muscle phenotype. The normal orderly development of coronary artery VSMC was dependent upon the presence of the neural crest, and therefore was disrupted in the experimental embryos whose neural crest was ablated.
Anat
Rec
1992 Oct
PMID:Coronary artery development in the chick: origin and deployment of smooth muscle cells, and the effects of neural crest ablation. 141 13
Previous studies have shown that the cells of the aorticopulmonary (AP) septum are similar to the smooth muscle cells of the mediae of the great vessels in their common origin from the cardiac neural crest and in their common expression of an elastic extracellular matrix. The purpose of this study was to test the cells of the AP septum for the presence of certain cytoplasmic proteins, especially
smooth muscle alpha-actin
(SMAA) whose presence is definitive of smooth muscle. A monoclonal antibody against SMAA was applied to normal chicken embryos at 3.5-8 days of incubation and to age-matched embryos from which the cardiac neural crest had been ablated surgically. Antibodies against the intermediate filaments desmin, cytokeratin, and vimentin also were applied. The results showed that the AP septal cells expressed SMAA during the process of septation, days 5-8; but when the cardiac neural crest was ablated and septation was defective, no cells in the conotruncal connective tissue expressed SMAA. None of the intermediate filament proteins were detected in the septum. These results indicate that the AP septal cells are smooth muscle and therefore may be hypothesized to have an active role in septation.
Anat
Rec
1990 Mar
PMID:Smooth muscle cells of neural crest origin form the aorticopulmonary septum in the avian embryo. 232 5
Morphological studies have hypothesized different origins for the precursors of the vascular smooth muscle cells (SMCs). The intriguing possibility that intimal SMCs may arise from the endothelium has newly emerged. As a first step towards understanding of the possible mechanisms involved in the transdifferentiation of endothelium into smooth muscle cells, we characterized the in vivo phenotype of the cells located in the aortic wall (distal to the aortic arches). This was accomplished using advanced stages of chicken embryo development. Furthermore, we investigated whether the cells present at the intimal thickening derive from the endothelial cell transdifferentiation. Immunolabeling of serial cryosections suggested that mesenchymal cells observed in the intimal thickening may arise from the endothelium. These cells may persist either as non-muscle throughout the development or possibly convert to cells expressing
smooth muscle alpha-actin
(SM alpha-actin). To determine whether endothelial cells may actually transdifferentiate into mesenchymal cells, aortic explants from 14-day-old chicken embryos (stage 40) were used. We found that explanted endothelial cells lose their cobblestone-appearance and migrate toward cell-free area. Some of these cells maintain the vWf immunoreactivity, whereas other cells coordinately lose vWf and gain SM alpha-actin expression (transitional cells). Taken together these findings strongly support the possibility that embryonic aortic endothelial transdifferentiate into mesenchymal cells, some of which express SM alpha-actin. Since TGFbeta-3 is considered an essential factor during epithelial to mesenchymal transitions in earlier chicken heart development, we also investigated the distribution of this growth factor at day 14. Our observations indicated that the immunoreactivity for TGFbeta-3 in this stage may be associated with migrating mesenchymal cells and that this immunoreactivity appears to decrease as cell differentiation advances. Therefore, the present study provides evidence that could help to explain 1) the presence of cells displaying a phenotype reminiscent of fetal-like cells in the normal chicken aorta and in the intimal region of the human aorta; 2) the SM lineage diversity in the chicken embryo reported by others; 3) a subpopulation of immature cells in the subendothelial region of the main pulmonary arteries of fetal, neonatal and adult bovines; and 4) the presence of intimal cushions, intimal pads, eccentric and diffuse intimal thickening that are observed in mammalian and avian vessels at birth.
Anat
Rec
2000 01 01
PMID:Intimal thickening involves transdifferentiation of embryonic endothelial cells. 1060 48
The infrared sensory membranes of pit organs of pit vipers have an extremely rich capillary vasculature that forms many vascular loops, each serving a small number of infrared nerve terminals. We clarified the ultrastructure of capillary pericytes in the pit membranes by scanning and transmission electron microscopy, and examined the immunoreactivity in their cytoplasm to two contractile proteins:
smooth muscle alpha-actin
(SM alpha-actin) and desmin. The capillary pericytes had two major cytoplasmic processes: thickened primary processes that radiate to embrace the endothelial tube and flattened secondary processes that are distributed widely on the endothelium. Coexpression of SM alpha-actin and desmin was observed in the pericytes of entire capillary segments, and SM alpha-actin was characterized by prominent filament bundles directed mainly at right angles to the capillary long axis. This expression pattern was different from that of capillary pericytes of the scales, where SM alpha-actin was expressed diffusely in the cytoplasm. In a series of electron microscopic sections, we often observed the pericyte processes depressing the endothelial wall. We also observed a close relationship of the pericytes with inter-endothelial cell junctions, and pericyte processes connected with the endothelial cells via gap junctions. From these findings, we surmised that capillary pericytes in the pit membrane have a close functional relationship with the endothelium, and through their contractile and relaxing activity regulate capillary bloodflow to stabilize production of infrared nerve impulses.
Anat
Rec
2000 11 01
PMID:Ultrastructure of the capillary pericytes and the expression of smooth muscle alpha-actin and desmin in the snake infrared sensory organs. 1106 40
Monolayers of retracted endothelial cells exhibiting wounds or zones denuded of cells were obtained from aortic explants from 10- to 12-day-old chicken embryos. Using time-lapse videomicroscopy, we investigated the sequence of events that occurred both during and after closure of the monolayer wounds. Such wound closure (re-endothelialization process) occurred 4-12 hr after removing the explants, depending on wound width and presence of serum. The cells from along the wound edges appeared to move toward one another. We suggest an important role for bFGF and TGFbeta-2 and -3 during this process. Twenty-five hours after removal there were still some areas of retracted cells, and many of the cells displayed a weak von Willebrand's Factor (vWf) immunoreactivity. Surprisingly, after 63-65 hr many of the endothelial cells had become epithelioid in shape and the vWf immunoreactivity appeared increased. This epithelioid phenotype is currently considered typical of cultured vascular non-muscle-like cells and intimal thickening cells. By 5-7 days, the vast majority of cells in the monolayer had acquired an epithelioid morphology, showing a cobblestone appearance. These cells were significantly smaller than polygonal cells. Most importantly, they showed strong vWf immunoreactivity. At the edge of the monolayers we found that the majority of the cells had become epithelioid. Some of them detached from their neighbors and became round in shape and acquired mesenchymal characteristics, some expressing
smooth muscle alpha-actin
(SM alpha-actin). These findings demonstrate not only that embryonic endothelial cells that are transiently mechanically altered may change their phenotype to an epithelioid phenotype, but also that these cells may eventually transdifferentiate into mesenchymal cells expressing SM alpha-actin. Since some aspects of endothelial cell behavior have been shown to be regulated by locally released growth factors such as TGFbeta and FGF, we also investigated TGFbeta-2 and -3 and bFGF expression. Presence of TGFbeta-2 and -3 and bFGF-immunoreactive epithelioid and mesenchymal cells indicates that these growth factors may be involved in the changes described.
Anat
Rec
A Discov Mol Cell Evol Biol 2003 Jan
PMID:Mechanically altered embryonic chicken endothelial cells change their phenotype to an epithelioid phenotype. 1249 91
Differently graded areas of human prostate adenocarcinoma were examined after Masson's trichrome staining or immunohistochemistry for
smooth muscle alpha-actin
, type IV collagen and laminin. In addition, the ultrastructure of the prostatic smooth muscle cells (SMC) during glandular proliferation and epithelial invasion in selected tumors was studied. The SMC formed a thick layer below the epithelial structures in unaffected areas and were closely associated with each other in homotypic interactions. As the tumor grade increased, the SMC gradually lost interactions with each other and became atrophic. With the growth of the epithelial compartment, the SMC initially segregated to the tumor periphery and the intercellular spaces increased. In high grade tumors, the epithelial cancer cells invaded the spaces between the SMC. Immunohistochemical analysis of the basal membrane revealed increased disruption of the usually thick basal membrane, which became thinner and faintly stained with each of the antibodies used. We conclude that most SMC become atrophic following epithelial invasion in human tumors and that degradation of the basal membrane is an important factor in this process. At the ultrastructural level, different SMC phenotypes occur in prostatic tissues during epithelial invasion. Interconversion between these phenotypes is suggested and a probable relationship among them is proposed.
Anat
Rec
(Hoboken) 2008 Sep
PMID:Anatomy of smooth muscle cells in nonmalignant and malignant human prostate tissue. 1872 55
