Expression of smooth muscle and nonmuscle myosin heavy chains in cultured vascular smooth muscle cells

We explored the hypothesis that discrepancies in the literature concerning the nature of myosin expression in cultured smooth muscle cells are due to the appearance of a new form of myosin heavy chain (MHC) in vitro. Previously, we used a very porous sodium dodecyl sulfate gel electrophoresis system to detect two MHCs in intact smooth muscles (SM1 and SM2) which differ by less than 2% in molecular weight (Rovner, A. S., Thompson, M. M., and Murphy, R. A. (1986) Am. J. Physiol. 250, C861-C870). Myosin-containing homogenates of rat aorta cells in primary culture were electrophoresed on this gel system, and Western blots were performed using smooth muscle-specific and nonmuscle-specific myosin antibodies. Subconfluent, rapidly proliferating cultures contained a form of heavy chain not found in rat aorta cells in vivo (NM) with electrophoretic mobility and antigenicity identical to the single unique heavy chain seen in nonmuscle cells. Moreover, these cultures expressed almost none of the smooth muscle heavy chains. In contrast, postconfluent growth-arrested cultures expressed increased levels of the two smooth muscle heavy chains, along with large amounts of NM. Analysis of cultures pulsed with [35S] methionine indicated that subconfluent cells were synthesizing almost exclusively NM, whereas postconfluent cells synthesized SM1 and SM2 as well as larger amounts of NM. Similar patterns of MHC content and synthesis were found in subconfluent and postconfluent passaged cells. These results show that cultured vascular smooth muscle cells undergo differential expression of smooth muscle- and nonmuscle-specific MHC forms with changes in their growth state, which appear to parallel changes in expression of the smooth muscle and nonmuscle forms of actin (Owens, G. K., Loeb, A., Gordon, D., and Thompson, M. M. (1986) J. Cell Biol. 102, 343-352). The reappearance of the smooth muscle MHCs in postconfluent cells suggests that density-related growth arrest promotes cytodifferentiation, but the continued expression of the nonmuscle MHC form in these smooth muscle cells indicates that other factors are required to induce the fully differentiated state while in culture.     

Platelet-derived growth factor regulates actin isoform expression and growth state in cultured rat aortic smooth muscle cells

The role of platelet-derived growth factor (PDGF) in the control of smooth muscle cell (SMC) differentiation was explored in vitro by examining its effects on expression of the smooth muscle (SM) specific contractile protein SM alpha actin in cultured rat aortic SMC. Quiescent, postconfluent SMC express maximal levels of alpha actin and responded to human platelet-derived growth factor (partially purified from platelets) by entering the cell cycle and undergoing approximately one synchronous round of DNA synthesis. Concomitantly, these cultures exhibited a marked reduction in alpha actin synthesis. Chronic treatment with PDGF (72 hours at 8 or 12 hour intervals) was associated with a transient increase in thymidine labeling index and a decrease in alpha actin expression. Interestingly, between 48 and 72 hours following initial treatment, thymidine labeling indices returned to near control levels while SM alpha actin expression remained depressed. This effect was reversible; fractional alpha actin synthesis increased immediately after PDGF removal. When subsequently stimulated with 10% fetal bovine serum (FBS), cells chronically pretreated with PDGF entered S phase approximately 4 hours earlier than cells pretreated with PDGF vehicle, consistent with the idea that the maintained suppression of alpha actin synthesis in SMC subjected to chronic PDGF treatment was associated with partial cell cycle transit. Chronic treatment with highly purified recombinant PDGF-BB elicited similar effects on alpha actin synthesis and partial cell cycle transit. Flow cytometric analysis of chronic PDGF-treated SMC demonstrated a 25% increase in forward angle light scatter, an index of cell size. These data implicate a possible role for PDGF in regulation of SMC differentiation and suggest a potentially important role for this mitogen in the phenotypic modulation accompanying SMC growth and in mediation of the cellular hypertrophy associated with cell cycle progression.     

Cell cycle versus density dependence of smooth muscle alpha actin expression in cultured rat aortic smooth muscle cells

Cultured smooth muscle cells (SMC) undergo induction of smooth muscle (SM) alpha actin at confluency. Since confluent cells exhibit contact inhibition of growth, this finding suggests that induction of SM alpha actin may be associated with cell cycle withdrawal. This issue was further examined in the present study using fluorescence-activated cell sorting of SMC undergoing induction at confluency and by examination of the effects of FBS and platelet-derived growth factor (PDGF) on SM alpha actin expression in postconfluent SMC cultures that had already undergone induction. Cell sorting was based on DNA content or differential incorporation of bromodeoxyuridine (Budr). The fractional synthesis of SM alpha actin in confluent cells was increased two- to threefold compared with subconfluent log phase cells, but no differences were observed between confluent cycling (Budr+) and noncycling (Budr-) cells. In cultures not exposed to Budr, confluent cycling S + G2 cells exhibited similar induction. These data indicate that cell cycle withdrawal is not a prerequisite for the induction of SM alpha actin synthesis in SMC at confluency. Growth stimulation of postconfluent cultures with either FBS or PDGF resulted in marked repression of SM alpha actin synthesis but the level of repression was not directly related to entry into S phase in that PDGF was a more potent repressor of SM alpha actin synthesis than was FBS despite a lesser mitogenic effect. This differential effect of FBS versus PDGF did not appear to be due to transforming growth factor-beta present in FBS since addition of transforming growth factor-beta had no effect on PDGF-induced repression. Likewise, FBS (0.1-10.0%) failed to inhibit PDGF-induced repression. Taken together these data demonstrate that factors other than replicative frequency govern differentiation of cultured SMC and suggest that an important function of potent growth factors such as PDGF may be the repression of muscle-specific characteristics.     

Developmental changes in isoactin expression in rat aortic smooth muscle cells in vivo. Relationship between growth and cytodifferentiation

There is an inverse relationship between cellular proliferation and smooth muscle alpha-isoactin expression in cultured vascular smooth muscle cells (SMCs) (Owens, G.K., Loeb, A., Gordon, D., and Thompson, M.M. (1986) J. Cell Biol. 102, 343-352). In the present studies, changes in isoactin expression were studied during developmental growth of rat aortic SMCs (ages 1-180 days) to better understand interrelationships between growth and cytodifferentiation in these cells in vivo. Actin expression (i.e. content and synthesis) was evaluated by one- and two-dimensional gel electrophoresis and using isoactin-specific antibodies. The major actin present in cells from newborn rats was nonmuscle beta-actin (56% of total actin), whereas cells from adult animals contained principally smooth muscle alpha-actin (Sm-alpha-actin) (76% of total actin). Increases in Sm-alpha-actin content with increasing age were due, in part, to an increase in Sm-alpha-actin synthesis. However, in SMCs from 90- and 180-day-old rats, the fractional content of Sm-alpha-actin exceeded its fractional synthesis at a time when total Sm-alpha-actin content was increasing. This suggests that Sm-alpha-actin turns over more slowly in mature animals. Decreases in the frequency of SMCs undergoing DNA synthesis with age could not account for increases in Sm-alpha-actin expression with age. However, combined immunocytological and [3H]thymidine autoradiographic studies demonstrated that nearly 50% of the medial derived cells from newborn rat aortas did not show detectable staining with a monoclonal antibody to smooth muscle-specific isoactins, and the replicative frequency was much higher in these cells than in cells that contained Sm-alpha-isoactins. Taken together, the results of the present studies and previous studies in cultured SMCs support the hypothesis that cessation of proliferation during development is associated with the induction of Sm-alpha-actin expression, but that factors other than cellular growth state play an important role in determining the level of Sm-alpha-actin expression in fully differentiated SMCs.     

Expression of smooth muscle-specific alpha-isoactin in cultured vascular smooth muscle cells: relationship between growth and cytodifferentiation

The relationship between growth and cytodifferentiation was studied in cultured rat aortic smooth muscle cells (SMCs) using expression of the smooth muscle (SM)-specific isoactins (Vanderkerckhove, J., and K. Weber, 1979, Differentiation, 14:123-133) as a marker for differentiation in these cells. Isoactin expression was evaluated by: (a) measurements of fractional isoactin content and synthesis ([35S]methionine incorporation) by densitometric evaluation of two-dimensional isoelectric focusing sodium dodecyl sulfate gels, and (b) immunocytological examination using SM-specific isoactin antibodies. Results showed the following: (a) Loss of alpha-SM isoactin was not a prerequisite for initiation of cellular proliferation in primary cultures of rat aortic SMCs. (b) alpha-SM isoactin synthesis and content were low in subconfluent log phase growth cells but increased nearly threefold in density-arrested postconfluent cells. Conversely, beta-nonmuscle actin synthesis and content were higher in rapidly dividing subconfluent cultures than in quiescent postconfluent cultures. These changes were observed in primary and subpassaged cultures. (c) alpha-SM actin synthesis was increased by growth arrest of sparse cultures in serum-free medium (SFM; Libby, P., and K. V. O'Brien, 1983, J. Cell. Physiol., 115:217-223) but reached levels equivalent to density-arrested cells only after extended periods in SFM (i.e., greater than 5 d). (d) SFM did not further augment alpha-SM actin synthesis in postconfluent SMC cultures. (e) Serum stimulation of cells that had been growth-arrested in SFM resulted in a dramatic decrease in alpha-SM actin synthesis that preceded the onset of cellular proliferation. These findings demonstrate that cultured vascular SMCs undergo differential expression of isoactins in relation to their growth state and indicate that growth arrest promotes cytodifferentiation in these cells.     

Regulation of SM22 alpha expression by arginine vasopressin and PDGF-BB in vascular smooth muscle cells

Vascular smooth muscle (SM) cells (VSMC) undergo phenotypic modulation in vivo and in vitro. This process involves coordinated changes in expression of multiple SM-specific genes. In cultured VSMC, arginine vasopressin (AVP) increases and PDGF decreases expression of SM alpha-actin (SMA), the earliest marker of SM cells (SMC). However, it is unknown whether these agents regulate other SM genes in a similar fashion. SM22 alpha appears secondary to SMA during development and is also a marker for SMC. This study examined the regulation of SM22 alpha expression by AVP and PDGF in cultured VSMC. Levels of SM22 alpha mRNA and protein were increased by AVP and suppressed by PDGF. Consistent with these changes, AVP increased SM22 alpha promoter activity, whereas PDGF inhibited basal promoter activity and blocked AVP-induced increase. Activation of both JNK and p38 MAPK pathways was necessary for AVP-mediated induction of SM22 alpha promoter. Expression of constitutively active Ras produced similar suppressions on SM22 alpha promoter activity as PDGF. Signaling relayed from PDGF/Ras activation involved Raf, or a protein that competes for this site, Ral-GDS, and phosphatidylinositol 3-kinase activation. Truncational analysis showed that the proximal location of three CArG boxes in the promoter was sufficient for AVP stimulation. Mutations in this CArG box reduced basal and AVP-stimulated promoter activity without effecting PDGF suppression. Overexpression of serum response factor enhanced basal and AVP-stimulated promoter activity but had no effect on PDGF-BB-induced suppression. These data indicate that AVP and PDGF initiate specific signaling pathways that control expression of multiple SM genes leading to phenotypic modulation.     

Cell density and proliferation modulate collagen synthesis and procollagen mRNA levels in arterial smooth muscle cells.

Collagen synthesis and procollagen mRNA levels were determined and compared in (1) sparse, rapidly proliferating smooth muscle cells (SMC); (2) postconfluent, density-arrested SMC; and (3) sparse, nonproliferating (mitogen-deprived) rabbit arterial SMC. Collagen synthesis per SMC was decreased by 70% in postconfluent versus proliferating cells. However, relative collagen synthesis, expressed as the percentage of total protein synthesis, increased from 3.7% in sparse cultures to approximately 7% in postconfluent cultures. Slot blot analyses demonstrated that the relative steady state alpha 1(I) and alpha 1(III) procollagen mRNA levels were also increased in postconfluent cultures when compared to sparse cultures. As with collagen synthesis per cell, the mRNA levels per cell for types I and III procollagen in postconfluent cells, determined by densitometry of blots, were likewise approximately half that found in sparse, proliferating cells. In a separate study to determine if cell-cell contact was necessary for eliciting these changes in collagen synthesis, we determined collagen synthesis in mitogen-deprived and proliferating SMC cultures at low density. Mitogen-deprived cultures synthesized only 10% the amount of collagen produced (per cell) by proliferating cultures in 10% fetal bovine serum. Relative collagen synthesis in proliferating and nonproliferating cultures was 5.0 and 8.3%, respectively. These results demonstrate elevated collagen synthesis, per cell, by proliferating cultures compared with nonproliferating cultures, regardless of whether cells were rendered quiescent by density arrest or by mitogen deprivation. Results also suggest a pretranslational mechanism for the regulation of collagen synthesis in rabbit aortic smooth muscle cells.     

Role of PDGF-A expression in the control of vascular smooth muscle cell growth by transforming growth factor-beta

Transforming growth factor-beta (TGF-beta) is a multifunctional regulatory peptide that can inhibit or promote the proliferation of cultured vascular smooth muscle cells (SMCs), depending on cell density (Majack, R. A. 1987. J. Cell Biol. 105:465-471). In this study, we have examined the mechanisms underlying the growth-promoting effects of TGF-beta in confluent SMC cultures. In mitogenesis assays using confluent cells, TGF-beta was found to potentiate the stimulatory effects of serum, PDGF, and basic fibroblast growth factor (bFGF), and was shown to act individually as a mitogen for SMC. In gene and protein expression experiments, TGF-beta was found to regulate the expression of PDGF-A and thrombospondin, two potential mediators of SMC proliferative events. The induction of thrombospondin protein and mRNA was density-dependent, delayed relative to its induction by PDGF and, based on cycloheximide experiments, appeared to depend on the de novo synthesis of an intermediary protein (probably PDGF-A). The relationship between PDGF-A expression and TGF-beta-mediated mitogenesis was investigated, and it was determined that a PDGF-like activity (probably PDGF-A) was the biological mediator of the growth-stimulatory effects of TGF-beta on confluent SMC. The effects of purified homodimers of PDGF-A on SMC replication were investigated, and it was determined that PDGF-AA was mitogenic for cultured SMC, particularly when used in combination with other growth factors such as bFGF and PDGF-BB. The data suggest several molecular mechanisms that may account for the ability of TGF-beta to promote the growth of confluent SMC in culture.     

Arterial smooth muscle cells in vivo: relationship between actin isoform expression and mitogenesis and their modulation by heparin

Quiescent smooth muscle cells (SMC) in normal artery express a pattern of actin isoforms with alpha-smooth muscle (alpha SM) predominance that switches to beta predominance when the cells are proliferating. We have examined the relationship between the change in actin isoforms and entry of SMC into the growth cycle in an in vivo model of SMC proliferation (balloon injured rat carotid artery). alpha SM actin mRNA declined and cytoplasmic (beta + gamma) actin mRNAs increased in early G0/G1 (between 1 and 8 h after injury). In vivo synthesis and in vitro translation experiments demonstrated that functional alpha SM mRNA is decreased 24 h after injury and is proportional to the amount of mRNA present. At 36 h after injury, SMC prepared by enzymatic digestion were sorted into G0/G1 and S/G2 populations; only the SMC committed to proliferate (S/G2 fraction) showed a relative slight decrease in alpha SM actin and, more importantly, a large decrease in alpha SM actin mRNA. A switch from alpha SM predominance to beta predominance was present in the whole SMC population 5 d after injury. To determine if the change in actin isoforms was associated with proliferation, we inhibited SMC proliferation by approximately 80% with heparin, which has previously been shown to block SMC in late G0/G1 and to reduce the growth fraction. The switch in actin mRNAs and synthesis at 24 h was not prevented; however, alpha SM mRNA and protein were reinduced at 5 d in the heparin-treated animals compared to saline-treated controls. These results suggest that in vivo the synthesis of actin isoforms in arterial SMC depends on the mRNA levels and changes after injury in early G0/G1 whether or not the cells subsequently proliferate. The early changes in actin isoforms are not prevented by heparin, but they are eventually reversed if the SMC are kept in the resting state by the heparin treatment.     

Pericyte growth and contractile phenotype: Modulation by endothelial-synthesized matrix and comparison with aortic smooth muscle

We compared the effects of endothelial-synthesized matrix and purified matrix molecules on pericyte (PC) and aortic smooth muscle cell (SMC) growth, heparin sensitivity, and contractile phenotype in vitro. When PC are plated on endothelial-synthesized (EC) matrix, cell number is, on average, 3.1-fold higher than identical populations grown on plastic. Under the same conditions, SMC proliferation is stimulated 1.6-fold. Purified matrix molecules, such as collagen type IV (COLL) or fibronectin (FN), both major components of the EC matrix, stimulate PC/SMC growth 1.2–1.7-fold. Heparin (100 μg/ml), which inhibits the growth of early passage SMC by 60%, inhibits PC growth ～50%, when cells were plated on plastic. However, PC plated on EC matrix in the presence of heparin (100 μg/ml) grow as well as parallel cultures grown on plastic (in the absence of heparin). Concomitant with matrix-stimulated proliferation, we observed a marked reduction in PC containing alpha vascular smooth muscle actin (αVSMA), as seen by immunofluorescence using affinity-purified antibodies (173/615 positive pericytes on DOC matrix (28%) vs. 221/285 (77%) positive on glass). SMC respond similarly. Whereas αVSMA protein is markedly altered when PC and SMC are cultured on EC matrix, similar reductions in mRNA are not observed. However, Northern blotting does reveal that PC contain 17–30 times the steady-state levels of αVSMA mRNA compared to SMC. When SMC and PC cultures on plastic are treated with heparin, the steady-state levels of vascular smooth muscle actin mRNA increase 5 and 1.5 fold, respectively. Similarly, heparin treatment of PC grown on plastic induces a 1.8 fold increase in nonmuscle actin mRNA. These heparin-induced alterations in isoactin mRNA levels are not seen when PC are cultured on EC matrix. We also observed reductions in αVSMA and β actin mRNA levels when PC are plated on FN, where they maintain a ratio of 13:1 (α:β). Similar ratios are found in SMC present in rat and bovine aortae in vivo. These steady-state isoactin mRNA ratios are slightly different from those seen in cultured PC (8–10:1; α:β). These results suggest that selective synthesis and remodelling of the endothelial basal lamina may signal alterations in pericyte growth and contractile phenotype during normal vascular morphogenesis, angiogenesis, or during the microvascular remodelling that accompanies hypertensive onset. © 1993 Wiley-Liss, Inc.     

Changes in expression and organization of smooth-muscle-specific α-actin during fibronectin-mediated modulation of arterial smooth muscle cell phenotype

The spreading of freshly isolated arterial smooth muscle cells on a substrate of fibronectin is mediated by an integrin receptor on the cell surface. It is associated with organization of actin filaments in stress fibers and marked changes in cell morphology and function, collectively referred to as a transition from a contractile to a synthetic phenotype. To study further how extracellular matrix components affect smooth muscle phenotype, we have analyzed the expression and organization of smooth-muscle-specific alpha-actin in freshly isolated rat aortic smooth muscle cells cultured on a substrate of fibronectin under serum-free conditions. Northern-blot analysis showed that the expression of mRNA for smooth muscle alpha-actin, but not for nonmuscle actin, was strongly repressed during primary culture. On the other hand, the cellular content of alpha-actin was only moderately changed during the same period. Indirect immunofluorescence staining revealed that nonmuscle actin was rapidly organized in stress fibers, which did not stain with a monoclonal antibody against smooth muscle alpha-actin. Filament bundles containing alpha-actin were most prominent in the central parts of the cytoplasm and gradually disappeared as the spreading of the cells progressed. In contrast to the situation with nonmuscle actin, there was no apparent overlap in the staining for alpha-actin and the fibronectin receptor (alpha 5 beta 1), indicating that this receptor interacted with nonmuscle actin during the initial spreading process. Taken together, the results show that the expression and organization of smooth muscle alpha-actin are changed during interaction of the cells with fibronectin early in primary culture. They support the notion that integrin-mediated interactions between extracellular matrix components and arterial smooth muscle cells take part in the control of smooth muscle phenotype.     

Platelet-derived growth factor-BB (PDGF-BB) induces differentiation of bone marrow endothelial progenitor cell-derived cell line TR-BME2 into mural cells, and changes the phenotype

Blood vessels are composed of endothelial cells (EC) and mural cells, and the interaction between EC and mural cells is essential for the development and maintenance of the vasculature. EC differentiate from bone marrow-derived endothelial progenitor cells (EPC). Recently, we established a conditionally immortalized bone marrow EPC-derived cell line, TR-BME2, and a brain capillary EC (BCEC) line, TR-BBB, from temperature-sensitive-SV40 T-antigen gene transgenic rats. To understand the function of EPC, it is important to analyze the difference between EPC and mature EC such as BCEC. In this study, we identified EPC-specific genes by means of subtractive hybridization between TR-BME2 and TR-BBB. There was no significant difference between TR-BME2 and TR-BBB in the mRNA level of annexin II, which is expressed in EC. In contrast, the mRNA level of smooth muscle cell (SMC) markers such as smooth muscle protein 22 (SM22), calvasculin, and platelet-derived growth factor (PDGF) receptor-beta, was higher in TR-BME2 than in TR-BBB. Moreover, the mRNA level of contractile SMC markers, such as smooth muscle alpha-actin and SM22, was increased in the absence of EC growth factors, such as vascular endothelial growth factor. The mRNA level of synthetic SMC markers, such as matrix Gla protein, was increased by the addition of PDGF-BB. The SMC derived from TR-BME2 showed an altered phenotype, from contractile-type to synthetic-type, when they were cultured in the absence of PDGF-BB. These results show that TR-BME2 cells have higher levels of SMC markers compared with mature EC, and can differentiate into contractile- or synthetic-type SMC.     

Regulation of fibronectin by platelet-derived growth factors in cultured rat thoracic aortic smooth muscle cells

Induction of Fibronectin (FN) gene expression by platelet-derived growth factor (PDGF) isoforms in rat thoracic aortic smooth muscle cells (SMC) was examined. PDGF-BB enhances FN levels in SMC cultures in a time- and concentration-response fashion. PDGF-AA and PDGF-AB show no effect on FN levels. The effects of insulin and insulin-like growth factor-I (IGF-I) on PDGF-BB-induced FN levels were examined. No additivity of FN levels is observed between PDGF-BB and insulin and/or IGF-I. Experiments also show that PDGF-BB enhances FN mRNA levels, implying that acquisition of additional FN mRNA units accounts for the increase in FN levels. Induction of FN and FN mRNA levels by PDGF-BB could be one of the initial events in vascular SMC proliferation and extracellular matrix expansion, leading to atherosclerosis and hypertension.     

A quantitative proteomic analysis of growth factor-induced compositional changes in lipid rafts of human smooth muscle cells

Signals that promote proliferation and migration of smooth muscle cells (SMC) have been implicated in pathologic growth of hollow organs. Members of the platelet-derived growth factor (PDGF) family, potent mitogens and motility factors for SMC, have been shown to signal through cholesterol-enriched lipid rafts. We recently demonstrated that PDGF-stimulated DNA synthesis in urinary tract SMC was dependent on the integrity of lipid rafts. Despite its known ability to rapidly alter discrete proteins within rafts, the effect of PDGF on overall raft protein composition is unknown. In this study, we employed isotope coded affinity tag (ICAT) analysis to evaluate PDGF-induced protein changes in lipid rafts of primary culture human SMC. Following acute (i.e., 15 min) exposure of SMC to PDGF, 23 proteins increased in rafts >20%. In contrast, raft localization of only three proteins increased after 12 h of PDGF treatment. Among the proteins that increased at 15 min were the glycophosphatidylinositol-anchored proteins Thy-1, 5'-nucleotidase, and CD55, the cytoskeletal proteins actin, actinin, tropomyosin-3 and -4, and the endocytosis-related proteins clathrin and beta-adaptin. In addition, eight Rho family members were localized to rafts by ICAT analysis. Collectively, these observations suggest a role for lipid rafts in regulation of PDGF-stimulated changes in the cytoskeleton.