Developmental changes in expression of contractile and cytoskeletal proteins in human aortic smooth muscle

To describe phenotypic changes of human aortic smooth muscle cells (SMCs), proportion of smooth muscle and nonmuscle variants of actin, myosin heavy chains (MHCs), vinculin, and caldesmon, during prenatal and several months of postnatal development was determined. In aortic SMCs from 9-10-week-old fetus, both nonmuscle and smooth muscle-specific variants of all four proteins were present, however, the nonmuscle forms were more abundant. During development, a shift towards the expression of muscle-specific variants was observed, although the time course of changes in protein variant content was not similar for all the proteins studied. By the 24th week of gestation, fractional content of alpha-smooth muscle actin and smooth muscle MHCs was rather close to that in the mature SMCs, and comprised approximately 80 and 90%, respectively, of the levels characteristic of SMCs from adult aortic media. On the contrary, fractional ratio of meta-vinculin and 150-kDa caldesmon was still rather low in the aorta from the 24-week-old fetus, did not increase in a 2-month-old child aorta, and did not reach the level characteristic of mature SMCs even in the 6-month-old child aorta. Thus changes in alpha-smooth muscle actin and smooth muscle MHC fractional content occur mainly during the prenatal period of development, before the 24th week of gestation; while meta-vinculin and the 150-kDa caldesmon proportion increases mainly in the postnatal period, during several months after birth. In the "Discussion," phenotypes of SMCs from developing aorta were compared to those from different layers of the adult aortic wall.     

Expression of cell adhesion molecule T-cadherin in the human vasculature

Alterations in expression of surface adhesion molecules on resident vascular and blood-derived cells play a fundamental role in the pathogenesis of cardiovascular disease. Smooth muscle cells (SMCs) have been shown to express T-cadherin (T-cad), an unusual GPI-anchored member of the cadherin family of adhesion molecules. Particular relevance for T-cad in cardiovascular tissues is indicated by our present screen (immunoblotting) of human tissues and organs whereby highest expression of T-cad was found in aorta, carotid, iliac and renal arteries and heart. To explore the (patho)physiological role for T-cad in the vasculature we performed an immunohistochemical analysis of T-cad expression in normal human aorta and atherosclerotic lesions of varying severity. T-cad was present both in the intima and media and was expressed in endothelial cells (ECs), SMCs and pericytes, but not in monocytes/macrophages, foam cells and lymphocytes. In the adventitia T-cad was present in the wall of vasa vasorum and was expressed in ECs, SMCs and pericytes. T-cad was differentially expressed in SMCs from distinct vascular layers of normal aorta (for example, high in the subendothelial (proteoglycan) layer of the intima, low in the musculoelastic intimal layer and in the media), as well as at different stages of lesion progression. In SMCs there was an apparent inverse relationship between the intensities of T-cad and smooth muscle alpha-actin expression, this being most prominent in lesions. The findings suggest a phenotype-associated expression of T-cad which may be relevant to control of the normal vascular architecture and its remodelling during atherogenesis.     

Developmental origin of smooth muscle cells in the descending aorta in mice

Aortic smooth muscle cells (SMCs) have been proposed to derive from lateral plate mesoderm. It has further been suggested that induction of SMC differentiation is confined to the ventral side of the aorta, and that SMCs later migrate to the dorsal side. In this study, we investigate the origin of SMCs in the descending aorta using recombination-based lineage tracing in mice. Hoxb6-cre transgenic mice were crossed with Rosa 26 reporter mice to track cells of lateral plate mesoderm origin. The contribution of lateral plate mesoderm to SMCs in the descending aorta was determined at different stages of development. SMC differentiation was induced in lateral plate mesoderm-derived cells on the ventral side of the aorta at embryonic day (E) 9.0-9.5, as indicated by expression of the SMC-specific reporter gene SM22alpha-lacZ. There was, however, no migration of SMCs from the ventral to the dorsal side of the vessel. Moreover, the lateral plate mesoderm-derived cells in the ventral wall of the aorta were replaced by somite-derived cells at E10.5, as indicated by reporter gene expression in Meox1-cre/Rosa 26 double transgenic mice. Examination of reporter gene expression in adult aortas from Hoxb6-cre/Rosa 26 and Meox1-cre/Rosa 26 double transgenic mice suggested that all SMCs in the adult descending aorta derive from the somites, whereas no contribution was recorded from lateral plate mesoderm.     

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.     

Variations in transfection efficiency of VEGF165 and VEGF121-cDNA

Little is known about the expression pattern of vascular endothelial growth factor (VEGF) among smooth muscle cells of different arterial regions. Therefore, we have conducted studies aimed at increasing expression of VEGF in cultured human smooth muscle cells (SMCs) from different sites: aorta, umbilical artery, and coronary artery. Two plasmids harboring human VEGF₁₂₁ and VEGF₁₆₅ isoforms, respectively, were constructed and lipotransfected into vascular SMCs, using the Fu-GENE 6. Extensive optimization of transfection conditions were performed prior to this. Different basal levels of VEGF were observed between cell types: from 0.51–0.95 pg/mL/μg protein in umbilical artery, through 2.32–2.39 pg/mL/μg protein in coronary artery, to 5.45–7.52 pg/mL/μg protein in aortic SMCs. Significant differences in responses to transfection were also observed: The increase in VEGF production was most pronounced in umbilical artery SMCs (e.g., with 4 μg VEGF₁₂₁-cDNA/in the wells)—an approximate 600-fold as opposed to an 18-fold increase in aortic SMCs and a 29-fold increase in coronary artery SMCs. In addition, we observed significant increases in proliferation rate of aortic and coronary endothelial cells (ECs), after incubation with conditioned medium from VEGF-transfected SMCs. Observed changes differed in relation to cell origin and isoform.     

Stem cells, vascular smooth muscle cells and atherosclerosis

Stem cells have the ability to differentiate into a variety of cells to replace dead cells or to repair tissue. Recently, accumulating evidence indicates that mechanical forces, cytokines and other factors can influence stem cell differentiation into vascular smooth muscle cells (SMCs). In developmental process, SMCs originate from several sources, which show a great heterogenicity in different vessel walls. In adult vessels, SMCs display a less proliferative nature, but are altered in response to risk factors for atherosclerosis. Traditional view on SMC origins in atherosclerotic lesions is challenged by the recent findings that stem cells and smooth muscle progenitors contribute to the development of atherosclerotic lesions. Vascular progenitor cells circulating in human blood and the presence of adventitia in animals are recent discoveries, but the source of these cells is still unknown. The present review gives an update on the progress of stem cell and SMC research in atherosclerosis, and discusses possible mechanisms of stem/progenitor cell differentiation that contribute to the disease process.     

Repression of Smooth Muscle Differentiation by a Novel High Mobility Group Box-containing Protein,HMG2L1

The molecular mechanisms regulating smooth muscle-specific gene expression during smooth muscle development are poorly understood. Myocardin is an extraordinarily powerful cofactor of serum response factor (SRF) that stimulates expression of smooth muscle-specific genes. In an effort to search for proteins that regulate myocardin function, we identified a novel HMG box-containing protein HMG2L1 (high mobility group 2 like 1). We found that HMG2L1 expression is correlated with the smooth muscle cell (SMC) synthetic phenotype. Overexpression of HMG2L1 in SMCs down-regulated smooth muscle marker expression. Conversely, depletion of endogenous HMG2L1 in SMCs increases smooth muscle-specific gene expression. Furthermore, we found HMG2L1 specifically abrogates myocardin-induced activation of smooth muscle-specific genes. By GST pulldown assays, the interaction domains between HMG2L1 and myocardin were mapped to the N termini of each of the proteins. Finally, we demonstrated that HMG2L1 abrogates myocardin function through disrupting its binding to SRF and abolishing SRF-myocardin complex binding to the promoters of smooth muscle-specific genes. This study provides the first evidence of this novel HMG2L1 molecule playing an important role in attenuating smooth muscle differentiation.     

Regulation of CCL5 expression in smooth muscle cells following arterial injury

Chemokines play a crucial role in inflammation and in the pathophysiology of atherosclerosis by recruiting inflammatory immune cells to the endothelium. Chemokine CCL5 has been shown to be involved in atherosclerosis progression. However, little is known about how CCL5 is regulated in vascular smooth muscle cells. In this study we report that CCL5 mRNA expression was induced and peaked in aorta at day 7 and then declined after balloon artery injury, whereas IP-10 and MCP-1 mRNA expression were induced and peaked at day 3 and then rapidly declined.The expression of CCL5 receptors (CCR1, 3 & 5) were also rapidly induced and then declined except CCR5 which expression was still relatively high at day 14 after balloon injury. In rat smooth muscle cells (SMCs), similar as in aorta CCL5 mRNA expression was induced and kept increasing after LPS plus IFN-gamma stimulation, whereas IP-10 mRNA expression was rapidly induced and then declined. Our data further indicate that induction of CCL5 expression in SMCs was mediated by IRF-1 via binding to the IRF-1 response element in CCL5 promoter. Moreover, p38 MAPK was involved in suppression of CCL5 and IP-10 expression in SMCs through common upstream molecule MKK3. The downstream molecule MK2 was required for p38-mediated CCL5 but not IP-10 inhibition. Our findings indicate that CCL5 induction in aorta and SMCs is mediated by IRF-1 while activation of p38 MAPK signaling inhibits CCL5 and IP-10 expression. Methods targeting MK2 expression could be used to selectively regulate CCL5 but not IP-10 expression in SMCs.     

Isolation of a morphologically and functionally distinct smooth muscle cell type from the intimal aspect of the normal rat aorta. Evidence for smooth muscle cell heterogeneity

Summary Recent studies indicate that the neointima of injured rat arteries is composed of a subpopulation of smooth muscle cells (SMCs) distinct from medial smooth muscle cells. However, SMC diversity in normal adult aorta has remained elusive. This study characterizes two morphologically and functionally distinct SMC types isolated from different anatomic regions of the normal rat aorta. Rat aortic medial smooth muscle cells (MSMCs) were isolated from the media after removal of the intimal and adventitial cells. Rat aortic intimal smooth muscle cells (ISMCs) were isolated from the intimal aspect of everted rat aortas. The two cell types were characterized morphologically and immunohistochemically and were compared for their capacity to contract collagen gels in response to endothelin-1. MSMCs were spindle-shaped and grew in hills and valleys showing features previously described for vascular SMCs. Conversely, ISMCs displayed a polygonal and epithelioid shape, grew mainly as a monolayer, and had a higher proliferative rate. Both cell types expressed alpha-smooth muscle actin and were negative for Factor VIII-RAg. ISMCs produced large amounts of a laminin and type IV collagen-rich extracellular matrix which had a characteristic pericellular distribution. ISMCs, but not MSMCs, rapidly contracted collagen gels in response to endothelin-1. This study indicates that the normal rat aorta contains two types of SMCs located in anatomically distinct regions of the vessel wall. Because of their functional characteristics, the SMCs isolated from the intimal aspect of the aorta may play an important role in physiologic as well as pathologic conditions.     

Human smooth muscle VLA-1 integrin: purification, substrate specificity, localization in aorta, and expression during development

A membrane glycoprotein complex was isolated and purified from human smooth muscle by detergent solubilization and affinity chromatography on collagen-Sepharose. The complex was identified as VLA-1 integrin and consisted of two subunits of 195 and 130 kD in SDS-PAGE. Liposomes containing the VLA-1 integrin adhered to surfaces coated with type I, II, III, and IV collagens, Clq subcomponent of the first component of the complement, and laminin. The liposomes specifically adhered to these proteins in a Ca2+, Mg2(+)-dependent manner, but did not bind to gelatin, fibronectin, and thrombospondin substrates. The expression of VLA-1 integrin in different human tissues and cell types, and during aorta smooth muscle development was studied by SDS-PAGE, and subsequent quantitative immunoblotting was performed with antibodies recognizing alpha 1 and beta 1 subunits of the VLA-1 integrin. A high level of VLA- 1 integrin expression was an exceptional feature of smooth muscles. Fibroblasts, endothelial cells, keratinocytes, striated muscles, and platelets contained trace amounts of VLA-1 integrin. In the 10-wk-old human fetal aorta, VLA-1 integrin was found only in smooth muscle cells whereas mesenchymal cells, surrounding aortic smooth muscle cells, were VLA-1 integrin negative. By the 24th wk of gestation, the amount of VLA- 1 integrin was significantly reduced in the aortic media (4.3-fold for alpha 1 subunit and 2.5-fold for beta 1 subunit) compared with that in the 10-wk-old aortic smooth muscle cells. After birth, the expression of VLA-1 integrin increased and in the 1.5-yr-old child aorta the VLA-1 integrin level was almost the same as in adult aortic media. Smooth muscle cells from intimal thickening of adult aorta express five times less alpha 1 subunit of VLA integrin that smooth muscle cells from adult aortic media. In primary culture of aortic smooth muscle cells, the content of the VLA-1 integrin was dramatically reduced and subcultured cells did not contain VLA-1 integrin at all.