Cultured cell isolates of the smooth muscle layer from the rat duodenum

A culture obtained from rat duodenal smooth muscle layer is described. The cells were isolated by trypsinization (0.2%), and the medium used for culture was either MEM with glutamine and non-essential AA or RPMI, both containing 10% foetal calf serum. The cell culture contained both smooth muscle cells and fibroplasts in proportions varying with the age of the culture. At day 6, cell differentiation is important. At day 12, when the cells are confluent, the majority of the cells are fibroblasts. Although it is difficult, the transfer of cells is possible at least twice.     

The uptake and expression of the factor VIII and reporter genes by vascular cells.

The conditions and efficacy of transfection of vascular cells in primary culture using DEAE-dextran, calcium phosphate and lipofectin have been investigated using chloramphenicol acetyltransferase and luciferase as reporter genes. Subsequently factor VIII was expressed in endothelial and smooth muscle cells. Both reporter genes could be expressed after transfection of umbilical vein endothelial cells, umbilical artery smooth muscle cells and fibroblasts. The expression of both reporter genes in endothelial and smooth muscle cells was highest using lipofectin. After transfection of smooth muscle cells with both full-length and mutant factor VIII genes, factor VIII activity and antigen were secreted into the culture medium, the secretion remaining stable to serial cell passage. The secretion of factor VIII from transfected smooth muscle cells was confirmed by the immunoprecipitation of [35S]methionine labelled protein. Endothelial cells also were successfully transfected with the mutant factor VIII gene.     

The mitogenic activity of endothelin-1 on megakaryocytopoiesis in vitro

Endothelin (ET)-1 induces proliferation of various cells including smooth muscle cells, fibroblasts, glomerular mesangial cells, endothelial cells and osteoblasts. ET-1 also stimulates synthesis of interleukin (IL)-6 in endothelial and bone marrow stromal cells of rat. It is well known that IL-6 modulates megakaryocytopoiesis. Some studies have indicated that megakaryocytes express both ET receptors and they are targets for ET. Therefore we planned to examine the effects of ET-1 on the growth of normal megakaryocytic cells in rat bone marrow primary cell culture. Bone marrow cells were cultured at 37 degrees C, in an incubator atmosphere of 5% CO2 in air and 95% relative humidity for nine days. ET-1 at 10(-7), 10(-8 ) and 10(-11) M, and control with saline were added at the beginning of the experiment protocol. At each day, plasma clots were stained using direct-coloring thiocholin method for acetylcholinesterase activity. Although 10(-7) M ET-1 did not change the proliferation of megakaryocytic cells, this could be due to the presence of over crowded fibroblasts in the same environment. 10(-8) M ET-1 stimulated megakaryocytic cell growth to 234% over the control on the fifth day. ET-1 at a concentration of 10(-11) M also rised the megakaryocytic cell number significantly reaching up to 86% at the sixth day. Our results indicate that ET-1 may modulate the growth of megakaryocytic cells by an autocrine and/or paracrine action.     

Platelet factors stimulate fibroblasts and smooth muscle cells quiescent in plasma serum to proliferate

Whole blood serum is widely recognized as essential for the growth of diploid cells in culture. Dermal fibroblasts and arterial smooth muscle cells fail to proliferate in culture in the presence of serum derived from platelet-poor plasma. Platelet-poor plasma serum is capable of maintaining monkey arterial smooth muscle cells quiescent in culture at either low (1.5 x 10(3)) or high (2.0 x 10(4)) population densities. The proportion of cell traversing the cell cycle under these conditions was approximately 3%. Equal numbers of quiescent smooth muscle cells initiated DNA synthesis and cell division when treated with whole blood serum or with an equivalent quantity of platelet-poor plasma serum supplemented with a factor(s) derived from a supernate obtained after exposure of human platelets to purified thrombin in vitro.     

Proteoglycans in primate arteries. II. Synthesis and secretion of glycosaminoglycans by arterial smooth muscle cells in culture

Glycosaminoglycan synthesis and secretion by primate arterial smooth muscle have been examined in cell culture. Mass cultures of diploid primate arterial smooth muscle cells were either double labeled with [35S]sulfate and [3H]acetate or single labeled with [3H]glucosamine for 24 h and glycosaminoglycans were extracted and isolated from the culture medium. Incorporation of labeled precursors into glycosaminoglycan was maximal during stationary phase of smooth muscle cell growth in culture and reduced, but not eliminated during logarithmic growth. The glycosaminoglycans synthesized and secreted into the culture medium were characterized by differential susceptibility to glycosaminoglycan-degradative enzymes and by cellulose acetate electrophoresis. Both assay procedures indicate that cultured primate arterial smooth muscle cells synthesize principally dermatan sulfate (60%-80% of total), chondroitin sulfate A and/or C (10%-20%of total) and little or no hyaluronic acid (0%-5% of total). This pattern of glycosaminoglycan formation differed significantly from that exhibited by isologous skin fibroblasts cultured under identical conditions. Dermal fibroblasts synthesize and secrete primarily hyaluronic acid (50%-60% of total) with lesser amounts of dermatan sulfate (10%-20% of total) and chondroitin sulfate A and/or C (10%-20% of total). These results indicate that differences exist in proteoglycan metabolism between these two connective tissue-producing cells in vitro, and suggest that the observed pattern of in vitro glycosaminoglycan synthesis by primate arterial smooth muscle cells may be characteristic for this cell type and not a general response to conditions of cell culture.     

Identification,paracrine generation,and possible function of human breast carcinoma myofibroblasts in culture

Summary Myofibroblasts from human breast carcinomas were identified and experimentally generated in culture, and a possible function was examined. The frequency ofα-smooth muscle actin immunoreactive cells was evaluated as a measure of myofibroblast differentiation in primary culture. Few or noα-smooth muscle actin-positive stromal cells (6.1 ± 8.4%) were identified in primary cultures from normal breast tissue (n=9). In contrast, high frequencies (68.8 ± 15.1%) were observed in primary cultures from carcinomas (n=19). The frequencies of myofibroblasts in primary cultures were almost identical to those obtained in the corresponding cryostat sections (69.1 vs. 68.8%). A possible precursor cell to the myofibroblast was looked for among typical fibroblasts and vascular smooth muscle cells. Purified blood vessels containing both fibroblasts and vascular smooth muscle cells were embedded in collagen gel and incubated with medium conditioned by breast epithelial cells. Fibroblasts rather than smooth muscle cells were recruited from the blood vessels. In medium conditioned by carcinoma cell lines or in co-cultures of carcinoma cell lines and purified fibroblasts,α-smooth muscle actin and the typical myofibroblast phenotype were induced in otherwiseα-smooth muscle actin-negative fibroblasts. The effect of myofibroblasts on cellular movement—essential to neoplastic cells—was analyzed. Spontaneous motility of tumor cells (MCF-7) was entirely suppressed in a collagen gel assay. Under these conditions tumor cell motility was selectively mediated by direct cell-to-cell interaction between tumor cells and myofibroblasts. Under chemically defined conditions, interaction was dependent on the presence of plasminogen. Anti-plasminogen, soybean trypsin inhibitor, and anti-fibronectin partly neutralized the effect of plasminogen. It is concluded that elements of myofibroblast differentiation and function may be studied in culture.     

The smooth muscle cell. III. Elastin synthesis in arterial smooth muscle cell culture

Primate arterial smooth muscle cells and skin fibroblasts were examined for their ability to synthesize elastin in culture. In the presence of the lathyrogen beta-aminopropionitrile, the smooth muscle cells incorporate [3H]lysine into a lysyl oxidase substrate that was present in the medium and associated with the cell layer. A component having a mol wt of 72,000 and an electrophoretic mobility similar to that of authentic tropoelastin was isolated from the labeled smooth muscle cells by coacervation and fractionation with organic solvents. In the absence of beta-aminopropionitrile, long-term cultures of smooth muscle cells incorporated [14C]lysine into desmosine and isodesmosine, the cross-link amino acids unique to elastin. In contrast, no desmosine formation occurred in the fibroblast cultures. These characteristics demonstrate that arterial smooth muscle cells are capable of synthesizing both soluble and cross-lined elastin in culture.     

Expression of calponin in rabbit and human aortic smooth muscle cells

Summary Polyclonal antibodies to chicken gizzard calponin were used to localize calponin and determine calponin expression in rabbit and human aortic smooth muscle cells in culture. Calponin was localized on the microfilament bundles of cultured smooth muscle cells. Early in primary culture,ccalponin staining was accumulated preferentially in the central part of the cell body. With time in culture, the number of calponin-negative smooth muscle cells increased while the distribution of calponin in calponin-positive cells became more even along the stress fibers. Calponin content and the calponin/actin ratio decreased about 5-fold in rabbit aortic smooth muscle cells during the first week in primary culture and remained low in proliferating cells. The same tendency in calponin expression was observed when human vascular smooth muscle was studied. On cryostat sections of human umbilical cord, calponin antibodies mainly stained vessel walls of both the arteries and veins, although less intensive labelling was also observed in non-vascular tissue. When primary isolates of human aortic intimal and medial smooth muscle cells were compared with corresponding passaged cultures, it was found that calponin content was reduced about 9-fold in these cells in culture and was similar to the amount of calponin in endothelial cells and fibroblasts. Thus, high calponin expression may be used as an additional marker of vascular smooth muscle cell contractile phenotype.     

Biosynthesis of chick type VI collagen. II. Processing and secretion in fibroblasts and smooth muscle cells

The biosynthesis of type VI collagen was studied in "matrix-free" chick embryo smooth muscle cells and fibroblasts. Omission of ascorbate from the culture affected to a great extent the secretion in fibroblasts but had a very minor effect on smooth muscle cells. Quantitative analysis of the secretion process in continuous time course and in pulse-chase experiments confirmed that fibroblasts and smooth muscle cells secreted type VI collagen with the same chain composition but with different kinetics: after 4 h of chase more than 60% of the labeled type VI collagen was present in the culture medium of fibroblasts, whereas at the same time interval less than 25% was secreted by smooth muscle cells. The different kinetics depends on intrinsic properties of the cells, since it was detected also in adherent cells. However, even in fibroblasts, secretion of type VI collagen was much slower than secretion of fibronectin, of which more than 50% was already in the cell medium after 1 h of chase. Treatment of the cells with inhibitors of hydroxylation and glycosylation caused a shift in mobility that revealed a size heterogeneity in the Mr = 260,000 subunit. No evidence of processing was observed in chick cells for any of the subunits that were synthesized and secreted uncleaved. In addition, after several days of chase the Mr of the subunits of type VI collagen isolated from the matrix remained unchanged, thus excluding that in the chick even a partial or incomplete processing takes place.     

Biochemical and immunological heterogeneity of 100 A filament subunits from different chick cell types.

The 100 A filament subunit proteins of chick fibroblasts and gizzard smooth muscle were compared. These proteins are major cellular components in these cell types, constituting up to 98% of the cell's total protein. Co-electrophoresis of cytoskeletal fractions of fibroblasts and smooth muscle revealed that the subunit proteins differed in their molecular weights: 58,000 daltons in fibroblasts and 55,000 daltons in smooth muscle. Cytoskeletal fractions from other cell types were also examined: chondroblasts contained the 58,000 dalton subunit, and cytoskeletons of skeletal muscle and cardiac muscle contained both 55,000 and 58,000 dalton proteins. Chick skin and rat kangaroo Pt K2 cells had more complex subunit patterns which resemble prekeratin. The peptide patterns resulting from proteolytic digestion of the 58,000 dalton protein of fibroblasts, the 55,000 dalton proteins of smooth muscle and PT K2 cells, and chick brain tubulin differed from one another. Two-dimensional electrophoresis of reconstituted gizzard smooth muscle 100 A filaments showed the 55,000 dalton subunit to be composed of two major components, differing in their isoelectric points. Antibodies prepared against electrophoretically purified 55,000 dalton subunit protein reacted in immunodiffusion against the original smooth muscle antigen and cytoskeletal fractions from skeletal and cardiac muscle, but not from fibroblasts, brain, liver, or skin cells. A specific antigenic determinant common to subunit proteins in smooth, skeletal, and cardiac muscle, is therefore indicated. A previously described antibody against fibroblast subunit protein reacted weakly against smooth muscle filament protein in immunodiffusion revealing the presence of a common antigenic determinant between the two subunit proteins. These data demonstrate striking antigenic and primary structural differences in 100 A filament subunits from even such closely related cell types as fibroblasts on the one hand and muscle cells on the other.     

An analysis of the interactions between sympathetic nerve fibers and smooth muscle cells in tissue culture

The interactions between sympathetic nerve fibers and smooth muscle cells and fibroblasts from the newborn guinea pig vas deferens were studied in tissue culture with phase contrast microscopy, time-lapse microcinematography, catecholamine fluorescence histochemistry and scanning and transmission electron microscopy. The amount of sympathetic nerve fiber growth, its catecholamine fluorescence reaction and the size of the nerve cell bodies and their nuclei all increased in the presence of vas deferens tissue. Specific growth of nerve fibers to large clumps of vas deferens tissue was seen from distances of up to 2 mm. In contrast, no specific growth from a distance occurred to single cells or small groups of cells. However, random contact with a muscle cell often led to close, extensive, and long-lasting associations. Contact with fibroblasts was always transitory.The rate of sympathetic nerve fiber growth over individual muscle cells was faster than over fibroblasts, which, in turn, was faster than over the collagen-coated surface of the coverslip. Palpation of a muscle cell by a nerve fiber growth cone increased the rate of spontaneous contraction of the muscle cell, the extent of the increase being dependent on the number of nerve fibers involved. Multiple innervation of a smooth muscle cell occurred if nerve fibers reached the cell at about the same time, but not if there was a close association already established. These results are discussed in relation to possible interactions of sympathetic nerve fibers with smooth muscle cells in vivo.     

Characterization of myosin heavy chains in cultured aorta smooth muscle cells. A comparative study

Myosin heavy chains (MHCs) from rat aorta smooth muscle cells were analyzed prior to and after these cells were placed into cell culture using sodium dodecyl sulfate-5% polyacrylamide gels, immunoblots, and two-dimensional peptide maps of tryptic digests. Rat aorta smooth muscle cells prior to culture were found to contain two MHCs (mass = 204 and 200 kDa) which cross-reacted with antibodies raised to smooth muscle myosin, but not with antibodies raised to platelet myosin. Tryptic peptide maps of these two MHCs showed no major differences when compared to each other and to maps of vas deferens and uterus smooth muscle MHCs. When rat aorta smooth muscle cells were placed into culture, the MHCs isolated from the cell extracts differed, depending on whether the cells were rapidly growing or postconfluent. Extracts from log-phase cultures contained predominantly MHCs that migrated more rapidly than smooth muscle myosin in sodium dodecyl sulfate-polyacrylamide gel electrophoresis (mass = 196 kDa) and cross-reacted with antibodies raised to platelet myosin, but not to smooth muscle myosin. Tryptic peptide maps of this MHC were very similar to those obtained with MHCs from non-muscle sources such as platelets and fibroblasts. In contrast, extracts from postconfluent rat aorta cell cultures contained three MHCs (mass = 204, 200, and 196 kDa). Using immunoblots and peptide maps, the fastest migrating MHC was found to be identical to the 196-kDa non-muscle MHC, while the two slower migrating MHCs had the same properties as aorta smooth muscle MHCs prior to culture. These results suggest that smooth muscle cells grown in primary culture contain predominantly (greater than 80%) non-muscle myosin while actively growing, but at a postconfluent stage, contain more equivalent amounts of smooth muscle and non-muscle myosins.     

Role of ascorbic acid in procollagen expression and secretion by human intestinal smooth muscle cells

The role of ascorbate in the production and secretion of procollagen by human intestinal smooth muscle cells and the conditions in culture for optimal ascorbate bioefficacy were studied. Procollagen synthesis and secretion were determined by the incubation of cells with L-[5-³H]proline, and the quantitation of radiolabelled procollagen bands in the cell layer and the culture medium by polycrylamide slab gel electrophoresis and densitometry. When cells were cultured without ascorbate in the culture medium, procollagen secretion into the medium was 75% less than in cells receiving fresh ascorbate daily. In the cell layer, in contrast, procollagen accumulation was fourfold greater in the scorbutic cells than in the ascorbate-replete cells. These findings contrasted with those in a control line of scorbutic human dermal fibroblasts in which a 95% decrease in procollagen secretion was not associated with any procollagen accumulation in the cells. In the intestinal smooth muscle cells, the absence of ascorbate resulted in a 25 and 50% decrease in steady-state levels of procollagen I and III mRNA, respectively, compared to a 40 and 75% decrease in fibroblasts. Heat inactivation of the serum in the culture medium augmented the promotion of procollagen secretion by ascorbate two- to fourfold. L-ascorbate phosphate did not increase the activity of L-ascorbate when replaced in medium either daily or every 4 days, and its efficacy was not augmented by serum heat inactivation. The changing of culture medium induced collagen secretion in the absence of ascorbate, but this process was markedly enhanced by ascorbate and induced a transient decrease in the steady-state levels of both procollagen and nonprocollagen mRNAs. The predominant action of L-ascorbate on HISM cells in vitro is to promote procollagen secretion and not procollagen synthesis. L-ascorbate-phosphate is not an adequate substitute for L-ascorbate in this cell line. © 1995 Wiley-Liss, Inc.     

Determination of cell types and numbers during cardiac development in the neonatal and adult rat and mouse

Cardiac fibroblasts, myocytes, endothelial cells, and vascular smooth muscle cells are the major cellular constituents of the heart. The aim of this study was to observe alterations in myocardial cell populations during early neonatal development in the adult animal and to observe any variations of the cardiac cell populations in different species, specifically, the rat and mouse. Whole hearts were isolated from either mice or rats during the neonatal and adult stages of development, and single cell suspensions were prepared via sequential collagenase digestion. Heterogeneous cell populations were immunolabeled for specific cell types and analyzed using fluorescence-activated cell sorting (FACS). In addition, the left ventricle, right ventricle, and septa were isolated, fixed, and sectioned for morphometric analyses. These same cardiac regions were also analyzed using FACS. We observed that the adult murine myocardium is composed of approximately 56% myocytes, 27% fibroblasts, 7% endothelial cells, and 10% vascular smooth muscle cells. Moreover, our morphometric and FACS data demonstrated similar percentages in the three regions examined. During murine neonatal cardiac development, we observed a marked increase in numbers of cardiac fibroblasts and a resultant decrease in percentages of myocytes in late neonatal development (day 15). Finally, FACS analyses of the rat heart during development displayed similar results in relation to increases in cardiac fibroblasts during development; however, cell populations in the rat differed markedly from those observed in the mouse. Taken together, these data enabled us to establish a homeostatic model for the myocardium that can be compared with genetic and cardiac disease models.     

Prostaglandin synthesis by cells comprising the calf pulmonary artery

Prostaglandin (PG) production was evaluated in the three cell types (endothelial, smooth muscle, and fibroblast) comprising the bovine pulmonary artery. Prostacyclin (PGI2) was the predominant prostaglandin (PG) produced by endothelial, smooth muscle, and fibroblast cells as they exist in culture or in freshly excised tissue fragments. In addition to PGI2, measurable amounts of PGE2, PGF2a, and thromboxane A2 (TXA2) were also produced by these cells. Endothelial cells were the most active producers of PGs. However, the type of PG produced was characteristic of the particular cell type, while the level of production was dependent on external factors. Prostaglandin production by cultured cells, both under basal conditions and in response to stimulatory agents, was quite similar to that of the respective freshly excised tissue fragments containing a given cell type. These cells in culture could be stimulated to produce PGI2 by both angiotensin and bradykinin at very low (physiological) concentrations, a further indication of the retention of the physiological responsiveness of these cells in culture. Endothelial cells and fibroblasts were activated by bradykinin at concentrations as low as 10(-12) M but did not respond to angiotensin. Smooth muscle cells in primary and first passage cultures were activated by both bradykinin and angiotensin at 10(-12) M concentrations. Serial subcultivations of smooth muscle cells resulted in a progressive loss in their responsiveness to bradykinin stimulation. The state of cell growth proved to be an important determinant of PG production. Actively growing cells in culture synthesized less PG when compared to cells which had entered into a "quiescent" nongrowth state.     

Regulation of proliferation of bovine aortic endothelial cells, smooth muscle cells, and adventitial fibroblasts in collagen lattices

We compared the proliferation of bovine aortic cells grown in collagen lattices. Smooth muscle cells continued to divide for 2 weeks while adventitial fibroblasts ceased to divide after 4-5 days. Endothelial cells did not proliferate within an untreated collagen lattice; however, if the lattice was covered with culture medium, endothelial cells populated its surface and proliferated to form a monolayer. We also found that both smooth muscle cells and endothelial cells, like fibroblasts, are able to contract a collagen lattice to a small fraction of its original volume, although endothelial cells are able to do so only if the lattice is covered with culture medium.     

Biochemical markers of contraction in human myometrial smooth muscle cells in culture

Summary Phosphorylation of a light chain subunit of myosin by Ca²⁺ and calmodulin-dependent myosin light chain kinase is believed to be essential for smooth muscle contraction. The biochemical properties of the myosin phosphorylation system in human myometrial smooth muscle cells in monolayer culture were compared with those of human myometrial tissue and nonmuscle cells in culture. Native myosin was isolated from other cellular proteins of crude homogenates by polyacrylamide gel electrophoresis (in the presence of pyrophosphate) and quantified by densitometry. The myosin content of myometrial smooth muscle cells in culture and that of myometrial tissue were similar and four- to five-fold greater than that of human endometrial stromal cells or skin fibroblasts in culture. The specific activities of myosin light chain kinase in homogenates of myometrial smooth muscle cells that were maintained in culture and in myometrial tissue were similar (2.05±0.18 and 1.60±0.37 nmol phosphate incorporated per min per mg protein, respectively). On the other hand, enzyme activity in skin fibroblasts was only 5% of that in myometrial smooth muscle cells. Myosin light chain kinase activity in myometrial smooth muscle cells was dependent upon Ca²⁺ and was inhibited reversibly by the calmodulin antagonist, calmidazolium. The intracellular Ca²⁺ concentration measured by quin2 fluorescence was 0.12 μM in resting cells and increased in a concentration-dependent manner with KC1 to a maximal value of 0.47 μM. These results indicate that biochemical processes important for smooth muscle contraction are retained in human myometrial smooth muscle cells in culture. This research was supported by grants HL26043, HD11149, and GM07062 from the National Institutes of Health, Bethesda, MD.     

Neovascular responses induced by cultured aortic endothelial cells

Neovascularization was studied in the chorioallantoic membrane of the chick embryo after implantation of bovine aortic endothelial and smooth muscle cells, Swiss and BALB/c 3T3 cells and human diploid fibroblasts cultured separately on microcarrier beads. Quantitative analysis of neovascularization indicated a 3 1/2-fold increase in the number of blood vessels responding to endothelial cells while smooth muscle cells induced a twofold increase when compared to the response of beads without cells. Skin fibroblasts and Swiss 3T3 cells did not elicit a comparable response. The marked angiogenic response induced by endothelial cells was characterized by a 137% increase in total vessel length and a 35% increase in average vessel area when compared to controls. Two of the properties required for an angiogenesis factor--stimulation of cellular migration and proliferation--can also be demonstrated using endothelial cell-conditioned medium in cell culture systems. Medium from cultured bovine aortic endothelium stimulates DNA synthesis, proliferation, and migration of smooth muscle cells. In addition, conditioned media from both endothelial cells and smooth muscle cells produced an angiogenic response in the chorioallantoic membrane assay, which was comparable to that produced by intact cells growing on microcarrier beads. Similar responses were not evident with medium conditioned by other cell types. These results indicate the potential importance of endothelial cells and endothelial cell products in regulating blood vessel growth.     

Electron microscopic study of the prenatal development of the thoracic aorta in the rat

Prenatal development of the thoracic aorta of the rat during the period ranging from gestational days 12 to 21 was examined by transmission electron microscopic and morphometric studies. The process of wall formation occurred in four major phases. At phase I (gestational day 12), the dorsal aorta consists of an endothelium and loosely surrounding mesenchymal cells. Collagen fibrils and fine filamentous materials are sparsely present in the intercellular space. At phase II (days 13 to 16), the mesenchymal cells begin to differentiate to myoblasts, which have small clusters of myofilaments with dense bodies, rough endoplasmic reticulum, and a discontinuous basal lamina. The differentiating cells form a few compact cell layers around the endothelium. Elastic fibers first occur sparsely in juxtacellular spaces at days 13-14. The thickness of the aorta increases rapidly from 1-3 layers of cells at day 13 to 5-8 layers at day 17, leading to a maximum of 5-9 cell layers at day 20. The differentiation of myoblasts and elastogenesis are initiated in the inner layers, and later progress toward the outer layer of the aortic wall. At phase III (days 17 to 19), the myoblasts continue to develop into typical smooth muscle cells, and elastic fibers rapidly increase in both size and number. At phase IV (day 20 and later), smooth muscle cells have well-developed myofilaments in the cell periphery, and rough endoplasmic reticulum and other organelles tend to accumulate in the apical portion of the cytoplasm. Elastic laminae appear in a few inner layers of the aortic wall.     

Regulation of Vascular Endothelial Growth Factor Expression by cAMP in Rat Aortic Smooth Muscle Cells

Vascular endothelial growth factor (VEGF) is an endothelial cell mitogen which stimulates angiogenesis. VEGF is regulated by multiple factors such as hypoxia, phorbol esters, and growth factors. However, data concerning the expression of VEGF in the different vascular cell types and its regulation by cAMP are not available. In the present study, we have investigated the effect of adenylate cyclase activation on VEGF mRNA expression in rat vascular cells in primary culture. Basal VEGF expression is greater in smooth muscle cells than in endothelial cells and fibroblasts. A 4-h treatment with forskolin (10⁻⁵M) induced a 2-fold stimulation of VEGF mRNA expression in smooth muscle cells and fibroblasts, but, in contrast, did not affect VEGF expression in endothelial cells. In smooth muscle cells, a pharmacologically induced increase in intracellular cAMP levels using iloprost or isoprenaline led to a rise in VEGF mRNA expression comparable to that induced by forskolin. Adenosine, which increases cAMP levels in smooth muscle cells, also increases VEGF expression. Moreover, the 2.2-fold stimulation of VEGF expression by adenosine was enhanced following a cotreatment with cobalt chloride (a hypoxia miming agent). The observed additive effect (4.3-fold increase) suggests that these two factors, hypoxia and adenosine, regulate VEGF mRNA expression in smooth muscle cells by independent mechanisms.