Smooth Muscle Cells Derived From Second Heart Field and Cardiac Neural Crest Reside in Spatially Distinct Domains in the Media of the Ascending Aorta-Brief Report.

OBJECTIVE: Smooth muscle cells (SMCs) of the proximal thoracic aorta are embryonically derived from the second heart field (SHF) and cardiac neural crest (CNC). However, distributions of these embryonic origins are not fully defined. The regional distribution of SMCs of different origins is speculated to cause region-specific aortopathies. Therefore, the aim of this study was to determine the distribution of SMCs of SHF and CNC origins in the proximal thoracic aorta. APPROACH AND RESULTS: Mice with repressed LacZ in the ROSA26 locus were bred to those expressing Cre controlled by either the Wnt1 or Mef2c (myocyte-specific enhancer factor 2c) promoter to trace CNC- and SHF-derived SMCs, respectively. Thoracic aortas were harvested, and activity of ß-galactosidase was determined. Aortas from Wnt1-Cre mice had ß-galactosidase-positive areas throughout the region from the proximal ascending aorta to just distal of the subclavian arterial branch. Unexpectedly, ß-galactosidase-positive areas in Mef2c-Cre mice extended from the aortic root throughout the ascending aorta. This distribution occurred independent of sex and aging. Cross and sagittal aortic sections demonstrated that CNC-derived cells populated the inner medial aspect of the anterior region of the ascending aorta and transmurally in the media of the posterior region. Interestingly, outer medial cells throughout anterior and posterior ascending aortas were derived from the SHF. ß-Galactosidase-positive medial cells of both origins colocalized with an SMC marker, α-actin. CONCLUSIONS: Both CNC- and SHF-derived SMCs populate the media throughout the ascending aorta. The outer medial cells of the ascending aorta form a sleeve populated by SHF-derived SMCs.

Morphometric changes in the aortic arch with advancing age in fetal to mature thoroughbred horses.

Aortic rupture is a well recognized cause of sudden death in thoroughbred horses. Some microscopic lesions, such as those caused by cystic medial necrosis and medionecrosis, can lead to aortic rupture. However, these microscopic lesions are also observed in normal horses. On the other hand, a previous study of aortic rupture suggested that underlying elastin and collagen deposition disorders might be associated with aortic rupture. Therefore, the purpose of this study was to compare the structural components of the tunica media of the aortic arch, which is composed of elastin, collagen, smooth muscle cells and mucopolysaccharides (MPS), in fetal to mature thoroughbred horses. The percentage area of elastin was greatest in the young horses and subsequently decreased with aging. The percentage area of collagen increased with aging, and the elderly horses (aged ≥20) exhibited significantly higher percentage areas of collagen than the young horses. The percentage area of smooth muscle cells did not change with age. The percentage area of MPS was inversely proportional to the percentage area of elastin. The fetuses exhibited a markedly larger percentage area of MPS than the mature horses. We concluded that the medial changes seen in the aortic arch, which included a reduction in the amount of elastin and increases in the amounts of collagen and MPS, were age-related variations.

Aortic intima media thickness in fetuses and children with intrauterine growth restriction.

OBJECTIVE: To measure aortic intima media thickness and diameter by ultrasonography in fetuses with intrauterine growth restriction (IUGR) and in appropriate for gestational age (AGA) fetuses and in the same children after a mean follow-up of 18 months. METHODS: This was a prospective study performed between January 2006 and August 2008. Fetuses were classified as having IUGR if the estimated fetal weight was below the 10th percentile and umbilical artery pulsatility index was greater than 2 standard deviations; they were classified as AGA if the estimated fetal weight was between the 10th and 90th percentiles. Abdominal aortic intima media thickness and diameter were measured in each fetus with IUGR and in each AGA fetus at a mean gestational age of 32 weeks. The same measurements were taken in the children after a mean follow-up of 18 months. RESULTS: Thirty-eight fetuses with IUGR and 32 AGA fetuses were enrolled in the study. Aortic intima media thickness median values were significantly higher in IUGR than in AGA both in utero (1.9 mm compared with 1.15 mm; P<.001) and after birth (2.4 mm compared with 1.03 mm; P<.001) and were significantly correlated (P=.018, r=0.48). At 32 weeks of gestation, aortic intima media thickness in fetuses with IUGR was inversely correlated with estimated fetal weight (P<.003; r=-0.58). Median diameter of the abdominal aorta and blood-flow velocity at 32 weeks of gestation were significantly higher in fetuses with IUGR compared with AGA fetuses (median diameter 4.5 mm compared with 3.6 mm, P<.001, blood-flow velocity 42.5 cm/s compared with 23.3 cm/s, P<.001). At follow-up, in 25 children who had had IUGR and 25 children who had been AGA, there was no significant difference in median diameter of the abdominal aorta (6.8 mm compared with 7.5 mm, P=.21). CONCLUSION: Aortic wall thickening in fetuses and children with IUGR shows differences with respect to those who were AGA. This may reflect a correlation between impaired growth in utero, Doppler abnormalities, low birth weight, and early signs of vascular dysfunction. LEVEL OF EVIDENCE: II.

Embryology of the internal carotid artery dural crossing: apropos of a continuous series of 48 specimens.

The aim of this study was to describe the embryologic and foetal development of the anterior paraclinoid region and more precisely the relationship of the internal carotid artery to the dura mater. This has been done by examining a collection of histological sections, representing a continuous series of 48 embryologic and foetal specimens, covering the period of the first 6 months of intra-uterine life. Neurological and vascular elements develop during the embryologic period; the internal carotid artery is recognizable in the various sections of its course and acquires a histological adult parietal constitution. The foetal period corresponds to the development of the meningeal structures. The superior, medial and lateral walls appear on the fifteenth week of amenorrhoea and do not change after that. The internal carotid artery enters subarachnoid space accompanied by a sleeve of mesenchymatous cells, which fixes it to the anterior clinoid process. The constitution of this sleeve, arising from the superior wall of the lateral sellar compartment, remained independent of the principle vascular part, which allows the formation of a plan of cleavage. The foetal relations of the dura mater and the internal carotid artery were seen to be different from those of adult subjects described in the literature, suggesting an existence of period of maturation postnatally.

Pulmonary vascular morphology in a fetal rabbit model for congenital diaphragmatic hernia.

BACKGROUND/PURPOSE: Although the pulmonary vascular abnormalities in congenital diaphragmatic hernia (CDH) are described from a morphologic point of view, the treatment of pulmonary hypertension (PH) remains one of the main unsolved problems in clinical daily practice. For this reason, detailed studies in well-validated animal models could still be of significance in our understanding of the pathogenesis of CDH. METHODS: In does of 23 days' gestational age (GA), 39 fetuses underwent creation of diaphragmatic hernia (DH) and 15 fetuses a sham thoracotomy (SHAM). Thirty-nine nonoperated littermates served as internal controls (CTR). Fetuses were harvested by cesarean section on days 25, 27, 29, and 30 of gestation. Lung specimens were obtained and formalin fixed for further vascular morphometry studies. RESULTS: Lung vessels from DH fetuses started to show significantly smaller internal diameter (ID), external diameter (ED), larger arterial wall thickness (WT), and, in particular, a proportionally higher medial thickness (%MT) and adventitial thickness (%AT) from day 27 onward when compared with control fetuses. SHAM fetuses, which were harvested at term, showed no differences with CTR. CONCLUSIONS: This is the first report documenting changes over time in the vascular system in a rabbit fetal model of surgically induced DH. These changes mimic pathologic findings observed in human fetuses and are also concordant with earlier observations in the surgical ovine model and the toxic nitrofen rat model.

Angiotensin II type 1 and 2 receptors in conduit arteries of normal developing microswine.

OBJECTIVE: To identify vascular cells capable of responding to angiotensin II (Ang II) generated in conduit arteries, we examined the Ang II type 1 receptor (AT1R) and Ang II type 2 receptor (AT2R) in the thoracic aorta (TA) and abdominal aorta (AA) and branches in 90-day fetal, 3-week postnatal, and 6-month adult microswine. METHODS AND RESULTS: By autoradiography ((125)I-[Sar(1)Ile(8)]-Ang II with or without AT1R- or AT2R-selective analogues or (125)I-CGP 42112), there were striking rostrocaudal differences in (1) AT2R binding at all ages (prominent in AA wall and branches, sparse in TA wall and branches) and (2) a non-AT2R binding site for CGP 42112 (consistently evident in postnatal TA and branches but absent in AA and branches). Furthermore, patterns of AT2R distribution in infradiaphragmatic arteries were developmentally distinct. In fetal AAs, high-density AT2Rs occupied the inner 60% of the medial-endothelial wall. In postnatal AAs, AT2Rs were sparse in the medial-endothelial wall but prominent in a circumferential smooth muscle alpha-actin-negative cell layer at the medial-adventitial border, occupying approximately 20% to 25% of the AA cross-sectional area. AT1R density in the TA and AA medial-endothelial wall increased with age, whereas AT2R density decreased after birth. CONCLUSIONS: A novel AT2R-positive cell layer confined to postnatal infradiaphragmatic arteries physically links adventitial and medial layers, appears optimally positioned to transduce AT2R-dependent functions of local Ang II, and suggests that adventitial Ang II may elicit regionally distinct vascular responses.

Differentiation of the smooth muscle cell phenotypes during embryonic development of coronary vessels in the rat.

Smooth muscle cell (SMC) maturation during embryonic development of coronary arteries and veins was studied in rats using different markers of the contractile phenotypes. The spatio-temporal pattern of distribution of these markers compared with the developing tunica media was examined. Alpha-smooth muscle actin (alpha-SMA) was the first marker of the SMC in the tunica media of coronary arteries found in ED16 hearts, followed by smooth muscle myosin heavy chain isoform which occurred on ED17. Subsequently 1E12 antigen was expressed in coronary artery wall in ED18 hearts, and finally smoothelin. The markers occur within the proximal part of the coronary arteries and deploy toward the apex. They are also found within the great vessels. None of the markers except for the alpha-SMA were found in coronary veins during embryonic life. We conclude that the SMC population of the developing tunica media of coronary vessels differentiates by the acquisition of particular markers and this process lasts till the end of the prenatal and early postnatal life.

Antenatal dexamethasone administration inhibits smooth-muscle-cell DNA synthesis in pulmonary-arterial media in nitrofen-induced congenital diaphragmatic hernia in rats.

The aim of this study was to investigate the effect of antenatal glucocorticoid therapy on smooth-muscle-cell (SMC) DNA synthesis in the pulmonary arteries (PA) in a nitrofen-induced congenital diaphragmatic hernia (CDH) rat model following nitrofen administration on day 9.5 of gestation. Antenatal dexamethasone (DEX) was given intraperitoneally on days 18.5 and 19.5 of gestation. Bromodeoxyuridine (BrdU) was injected via a jugular vein into the dam 1 h before the fetuses were killed by cesarean section at term. The fetuses were divided into three groups: group I (n = 10): normal controls; group II (n = 10): nitrofen-induced CDH; group III (n = 10): nitrofen-induced CDH with antenatal DEX treatment. Immunostaining of the lungs with anti-BrdU antibody was obtained by a standard avidin-biotin complex method. The number of immunopositive cells in the PA media and adventitia were counted using an image analyzer and analyzed statistically. The number of BrdU-immunopositive cells in the media was significantly increased in group II (16.83 +/- 3.01) compared to groups I (9.16 +/- 2.20) and III (6.83 +/- 1.70) (P < 0.01). There was no significant difference between groups I and III. The number of BrdU-immunopositive cells in the adventitia was not significantly different between the three groups. Antenatal DEX treatment inhibits SMC DNA synthesis in PA media in CDH lungs. This may be a possible mechanism by which antenatal DEX prevents structural PA changes in nitrofen-induced CDH in rats.

Cardiac and smooth muscle cell contribution to the formation of the murine pulmonary veins.

Previous studies have demonstrated that the primordial pulmonary veins originate as an outgrowth of the atrial cells and anastomosis with the pulmonary venous plexus. As a consequence of this embryologic origin the tunica media of these vessels is composed of cardiac cells that express atrial specific markers (Lyons et al. [1990] J Cell Biol 111:2427-2436; Jones et al. [1994] Dev Dyn 200:117-128). We used transgenic mice for the cardiac troponin I (cTNI) gene and smooth muscle (SM) myosin heavy chain as differentiation markers, to analyze how cardiac and SM cells contribute to the formation and structural remodeling of the pulmonary veins during development. We show here that the tunica media of the adult mouse pulmonary veins contains an outer layer of cardiac cells and an intermediate SM cell compartment lining down on the inner endothelium. This structural organization is well expressed in the intrapulmonary veins from the beginning of vasculogenesis, with cardiac cells accumulating over preexisting roots of endothelial and SM cells and extending to the third bifurcation of the pulmonary branches without reaching the more distal tips of the vessels. On the other hand, SM cells, which are widely distributed in the intrapulmonary veins from the embryonic stage E16, accumulate also in the extrapulmonary branches and reach the posterior wall of the left atrium, including the orifices of the pulmonary veins. This event takes place around birth when the pulmonary blood flow starts to function properly. A model for the development of the pulmonary veins is presented, based upon our analysis.

Neonatal intima formation in the human coronary artery.

Intimal masses develop in the human coronary arteries of all humans, becoming atherosclerotic in later life either because of focal accumulation of lipid or the resulting response to injury. We evaluated the time course of formation of the intimal mass in the proximal left anterior descending coronary artery in autopsy specimens from 91 patients between 17 weeks' gestation and 23 months of postnatal age. Intima was rarely found before 30 weeks' gestation; however, the frequency with which at least some intimal cells were observed increased to 35% between 36 weeks' gestation and birth. By 3 months after birth, all patients had an intimal mass at this coronary location. The mean intima/media ratio was 0.1 just after birth and increased continuously to the second postnatal year. Replication of medial smooth muscle cells, indicated by proliferating cell nuclear antigen staining, was high before birth and decreased between birth and 2 years of age. However, the replication index of the intima remained at 2% to 5%. Thus, coronary intimal cells appearing in the perinatal period may arise by migration after replication of medial smooth muscle, as is seen in models of carotid artery balloon injury. In conclusion, formation of the coronary artery intima is a rapid process, beginning in the peripartum or postpartum period. Given the clonality of the adult lesion and the lack of proliferation in later stages of lesion formation, it is intriguing to speculate that this event may form the basis for atherosclerosis in later life.

Intima-like smooth muscle cells: developmental link between endothelium and media?

The presence of non-contractile smooth muscle cells within the arterial wall raises questions as to their origin and function. These cells abound within the aortae of murine and porcine neonates, but are also present within the intimal and medial layers of adult arteries. They are largely devoid of smooth muscle-associated proteins and manifest an epithelioid form. Their morphological resemblance to endothelial cells prompted us to explore this potential relationship and to investigate their angiogenic properties in three-dimensional collagen gels. Using well-characterized smooth muscle cell lines, displaying either the intima-like (epithelioid) or media-like (spindle-shaped) morphology, we were able to show that intima-like cells share several features in common with endothelial ones and can transform into a media-like phenotype, whereby they irreversibly lose their characteristic pattern of protein expression. Intima-like, but not media-like, vascular smooth muscle cells are capable of forming capillary tubes, and, in co-cultures, can induce media-like ones to participate in this process. Such capillaries consist of a randomly-organized, mixed population of endothelial cells with intima-like or media-like smooth muscle ones. The functional significance of this diversity in smooth muscle cell type is not well understood, but phenotypic plasticity could conceivably figure as an important adaptive response to changes in the local environment.

The LKLF transcription factor is required for normal tunica media formation and blood vessel stabilization during murine embryogenesis.

The transcriptional programs that regulate blood vessel formation are largely unknown. In this paper, we examine the role of the zinc finger transcription factor LKLF in murine blood vessel morphogenesis and homeostasis. By in situ hybridization and immunohistochemistry, we show that LKLF is expressed as early as embryonic day 9.5 (E9.5) in vascular endothelial cells throughout the developing mouse embryo. To better understand the function of LKLF, we used homologous recombination in embryonic stem (ES) cells to generate LKLF-deficient (LKLF-/-) mice. Both angiogenesis and vasculogenesis were normal in the LKLF-/- mice. However, LKLF-/- embryos died between E12.5 and E14.5 from severe intra-embryonic and intra-amniotic hemorrhaging. This bleeding disorder was associated with specific defects in blood vessel morphology. Umbilical veins and arteries in the LKLF-/- embryos displayed an abnormally thin tunica media and aneurysmal dilatation before rupturing into the amniotic cavity. Similarly, vascular smooth muscle cells in the aortae from the LKLF-/- animals displayed a cuboidal morphology and failed to organize into a compact tunica media. Consistent with these findings, electron microscopic analyses demonstrated endothelial cell necrosis, significant reductions in the number of vessel-wall pericytes and differentiating smooth muscle cells, and decreased deposition of extracellular matrix in the LKLF-/- vessels. Despite these defects, in situ hybridization demonstrated normal expression of platelet-derived growth factor B, Tie1, Tie2, transforming growth factor beta, and heparin-binding epidermal growth factor in the vasculature of the LKLF-/- embryos. Therefore, LKLF defines a novel transcriptional pathway in which endothelial cells regulate the assembly of the vascular tunica media and concomitant vessel wall stabilization during mammalian embryogenesis.

Trophoblast cell-mediated modifications to uterine spiral arteries during early gestation in the macaque.

A specialized subset of invasive embryonic cytotrophoblast cells gains access to maternal uterine arteries early in the gestation of higher primates. These cells continue to migrate extensively within the lumina of spiral arteries, converting them to the highly modified uteroplacental arteries of pregnancy. Although trophoblast cell-mediated modifications are considered critical to the progress of normal pregnancy, few studies have addressed the cellular interactions between maternal arteries and embryonic cells in situ. Macaque placentas and endometrial tissues were collected from 12 animals from day 14 of gestation (blastocyst implantation begins on day 9) to day 49. Standard indirect immunoperoxidase methods were used to identify matrix metalloproteinases (MMP-1, MMP-3, MMP-9), cathepsin B, cathepsin D, platelet-endothelial cell adhesion molecule, cytokeratins, smooth muscle actin, CD68, and factor VIII-related antigen. Cytotrophoblast cells were located deep within spiral arteries in each of the specimens examined. In some examples tightly packed clusters of cytotrophoblast occluded the lumina of invaded arteries. Initial penetration of arterial tunica intima was revealed by discontinuities in the staining pattern for factor VIII and cytotrophoblast intrusion was indicated by cytokeratin staining of the trophoblast cells. Continued cytotrophoblast intrusion into the tunica media was apparent by gaps in the smooth muscle. MMP-1, MMP-3, and MMP-9 were localized within intraluminal and intramural cytotrophoblast. By contrast, neither cathepsin B nor cathepsin D were present, although both were seen in uterine macrophages and stromal cells. Upon reaching the surrounding uterine stroma the cytotrophoblast cells ceased migration. As cytotrophoblast accumulated in the arterial wall the vascular lumen expanded. Evidence of cell death was rarely encountered in associated maternal or embryonic tissues. We conclude that intra-arterial cytotrophoblast cells express several proteinases with substrate specificities sufficient to permit independent remodeling of the extracellular matrix comprising uterine artery walls. The remodeling of the arteries, which involves extensive displacement of maternal endothelium and smooth muscle, in addition to degradation and synthesis of extracellular matrix, is accomplished with little evidence of cell death or loss of the integrity of the arteries. This process provides an interesting example of cooperation between different types of interacting tissues from genetically distinct individuals.

Anatomy of segmental duplication in the human basilar artery. Possible site of aneurysm formation.

Segmental duplications of the basilar artery, previously reported exclusively as anatomical variations, owe their clinical interest to the possible association with aneurysms localized at the junctions of the fenestrated segments. The morphological characteristics of 5 cases of basilar artery segmental duplication without aneurysms, found at autopsy, are reported. In 3 of these the proximal junction of the fenestrated segment was studied with scanning electron microscopy and morphometry. In all cases the tunica media of the medial wall of the 2 branches showed a progressive thinning towards the junctions of the fenestrated segments and a small muscular gap at their apex. The limited medial defect might be embryologically ascribed to the persistence of the morphological individuality of the tunica media of the 2 branches at the point where the fusion of the primitive longitudinal neural arteries stopped. The review of the literature shows that the morphology of the junctions of the fenestrated segments is in conformity with that of the intracranial arterial bifurcations. For this reason the basilar artery fenestration exposes to the blood flow a new distal bifurcation where the same etiologic factors that are still under discussion in the origin of saccular intracranial aneurysms may be active.

Multiple phenotypically distinct smooth muscle cell populations exist in the adult and developing bovine pulmonary arterial media in vivo.

Different smooth muscle cell (SMC) functions may require different cell phenotypes. Because the main pulmonary artery performs diverse functions, we hypothesized that it would contain heterogeneous SMC populations. If the hypothesis were confirmed, we wished to determine the developmental origin of the different populations. Using specific antibodies, we analyzed the expression of smooth muscle (SM) contractile and cytoskeletal proteins (alpha-SM-actin, SM myosin, calponin, desmin, and meta-vinculin) in the main pulmonary artery of fetal (60 to 270 days of gestation), neonatal, and adult animals. We demonstrated the existence of a complex, site-specific heterogeneity in the structure and cellular composition of the pulmonary arterial wall. We found that at least four cell/SMC phenotypes, based on immunobiochemical characteristics, cell morphology, and elastic lamellae arrangement pattern, were simultaneously expressed within the mature arterial media. Further, we were able to assess phenotypic alterations in each of the four identified cell populations during development. We found that each cell population within the arterial media expressed alpha-SM-actin at least at certain stages of development, thus demonstrating its smooth muscle identity. However, each cell population progressed along different developmental pathways, suggesting the existence of multiple and distinct cell lineages. A novel anti-metavinculin antibody described in this study reliably distinguished one SMC population from the others during all the developmental stages analyzed. We conclude that the pulmonary arterial media is indeed composed of multiple phenotypically distinct cell/SMC populations with unique lineages. We speculate that these distinct cell populations may serve different functions within the arterial media and may also respond in unique ways to pathophysiological stimuli.

Ontogeny of vessel wall components in the outflow tract of the chick.

During development of the outflow tract, the walls of the truncus arteriosus change from a diffuse extracellular matrix (ECM) surrounded by an extension of the myocardium to alternating laminae of smooth muscle and elastic connective tissue. The transition rapidly follows septation, when mesenchyme associated with the endothelium differentiates. Using immunocytochemical methods with antibodies to components of the tunica media and the tunica adventitia we have analysed the differentiation of the vessel walls of the outflow tract of the chick. The tunica media marker, elastin, forms laminae in a radial sequence, beginning at the outer margin of the truncus mesenchyme. Conversely, smooth muscle myosin is first expressed in cells associated with the endothelium. Laminin is expressed as a cell surface component throughout the development of the outflow tract. Matrix fibronectin distribution is correlated with the regions that will form the tunica media and apparently forms a radial gradient which is highest near the endothelium. Markers for the tunica adventitia, collagen I and VI, are expressed first at the peripheries of the newly formed tunica media, and collagen VI expression spreads radially through the tunica media. Thus, the vessel wall components appear within the mesenchyme of the truncus arteriosus in opposed radial gradients of differentiation. The tunica media cells acquire secretory and contractile phenotypes independently and may be responding to different stimuli in their expression of these features.

[The development of pre- and post-natal veins]. / L'évolution des veines pré- et post-natales.

Superficial and deep veins have different evolutions, structures and functions. Phylogenetically, superficial veins of limbs appear before the deep ones. In mammals other than man, both anatomical and histological abnormalities of superficial and deep veins have been noticed. In phlebology, the date of the first appearance of these veins was examined, from the infantile age to the age of 60 in 2,259 patients. Incomplete truncal varicose veins or an excess of certain perforating veins were found in 13.9% cases among children of school age. In 71.0% cases, these defects had a hereditary origin.

[A comparative ultrastructural and morphometric analysis of the smooth myocytes in the tunicae intima and media of the human fetal aorta]. / Sravnitel'nyi ul'trastrukturnyi i morfometricheskii analiz gladkikh miotsitov vnutrennei i srednei obolochek aorty ploda cheloveka.

Transmission electron microscopy was used for studying the thoracic part of the aorta of 9 human fetuses of 20-28 weeks of development. In the medial tunic of the human fetus aorta there are smooth myocytes (SM) of the contractile and synthetic phenotypes. The latter are localized mainly in the inner part of the media. In the inner tunic there are also SM of the synthetic phenotype. With the help of processes they make contacts with endotheliocytes and processes of SM of the media. In the gaps between the subendothelial SM and endothelium there are particles of elastin which form the structure resembling an additional elastic membrane. It is reasonable to think that the migration of SM into the intima is a stage of normal development of the vessel associated with the adaptation to local hemodynamic conditions rather than an initial manifestation of atherosclerosis.

Histogenesis of tunica media of the chick aorta.

We investigated the formation of the aortic tunica media in developing chicks from Hamburger-Hamilton stage (st) 12 to 1-day after hatching. At st 12, some cells of the lateral plate and the somite adjacent to the aorta extended processes toward the aortic endothelial tube. This is the first sign of the tunica media formation of the aorta. Then, these cells detached from the lateral plate and the somite attached to the aortic endothelial tube and covered it almost entirely by st 18. At this stage, bundles of microfilaments and spots of dense material were found in the peripheral region of cells of the tunica media (media cells); suggesting the earliest differentiation of smooth muscle cells. Subsequently, the tunica media increased in the number of cell-layers, reaching approximately 20 layers at st 34 (8-day incubation). The outer layers of the tunica media consisted of undifferentiated cells, whereas typical smooth muscle cells were found within the inner 4 to 5 layers. Elastic fibers first appeared at this st 34. With there was an increase in the elastic component, the tunica media assumed the lamella structure consisting of the alternating myocytes and elastic laminae. The aortic media 1-day after hatching essentially exhibited the same mature state as seen in the adult chickens.

Phenotypic changes of human smooth muscle cells during development: late expression of heavy caldesmon and calponin.

Expression of the regulatory contractile proteins, heavy caldesmon (h-caldesmon) and calponin was studied in human aortic smooth muscle cells (SMCs) during development and compared with the expression of alpha-SM-actin and smooth muscle-myosin heavy chain (SM-MHCs). For this study, novel monoclonal antibodies specific to SM-MHCs, h-caldesmon, and calponin were developed and characterized. Aortic SMCs from fetuses of 8-10 and 20-22 weeks of gestation express alpha-SM-actin and SM-MHCs, but neither h-caldesmon nor calponin were expressed as demonstrated by immunoblotting and immunofluorescence techniques. In the adult aortic tunica media, SMCs contain all four markers. Thus, the expression of calponin, similar to the expression of alpha-SM-actin, SM-MHCs, and h-caldesmon, is developmentally regulated in aortic SMCs. In the adult aortic subendothelial (preluminal) part of tunica intima, numerous cells containing SM-MHCs, but lacking h-caldesmon and calponin, were found. These results illustrate the similarity of SMCs from intimal thickenings and immature (fetal) SMCs. Expression of contractile proteins in the developing SMCs is coordinately regulated; however, distinct groups of proteins appear to exist whose expression is regulated differently. Actin and myosin, being major contractile proteins, also play a structural role and appear rather early in development, whereas caldesmon and calponin, being involved in regulation of contraction, can serve as markers of higher SMC differentiation steps. In contrast, h-caldesmon and calponin were already present in visceral SMCs (trachea, esophagus) of the 10-week-old fetus. These results demonstrate that the time course of maturation of visceral SMCs is different from that of vascular SMCs.