Phenotype modulation in primary cultures of arterial smooth-muscle cells: reorganization of the cytoskeleton and activation of synthetic activities

During primary culture, arterial smooth-muscle cells (SMCs) undergo transition from a contractile to a synthetic phenotype. As a consequence, they lose the ability to contract and, instead, acquire the ability to synthesize DNA, divide and produce extracellular-matrix components. In the present study, we used cytochemical and electron-microscopic methods to study the organization of the cytoskeleton in primary cultures of adult rat and human arterial SMCs. Freshly isolated cells were all in contractile phenotype and stained intensely with NBD-phallacidin, a fluorescent marker for F-actin. Diffuse, positive staining was also obtained using indirect-immunofluorescence microscopy with antibodies against tubulin and vimentin, which are subunit proteins of microtubules and intermediate filaments, respectively. Fine structurally, the cytoplasm of these cells was mainly filled with microfilament bundles coalescing in dense bodies. After a few hours in culture, the SMCs attached to the substrate and started to extend processes in various directions. These stained with antibodies to tubulin and vimentin, but not with NBD-phallacidin. Within 1-3 days of culture, the cells spread out on the substrate and developed a system of actin-containing stress fibre bundles spanning their entire length, as well as a radiating system of microtubules and vimentin filaments, originating in the juxtanuclear region. Fine structurally, these changes corresponded to a marked decrease in the number of microfilaments, an increase in the number of microtubules and intermediate filaments, and the formation of an extensive rough endoplasmic reticulum and a large Golgi complex. The morphological transformation of the cells was accompanied by the coordinated activation of DNA, RNA and protein synthesis.     

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.     

Rho expression and activation in vascular smooth muscle cells

Phenotypic modulation of smooth muscle cells (SMC) involves dramatic changes in expression and organization of contractile and cytoskeletal proteins, but little is known of how this process is regulated. The present study used a cell culture model to investigate the possible involvement of RhoA, a known regulator of the actin cytoskeleton. In rabbit aortic SMC seeded into primary culture at moderate density, Rho activation was high at two functionally distinct time-points, first as cells modulated to the "synthetic" phenotype, and again upon confluence and return to the "contractile" phenotype. Rho expression increased with time, such that maximal expression occurred upon return to the contractile state. Transient transfection of synthetic state cells with constitutively active RhoA (Val14RhoA) caused a reduction in cell size and reorganization of cytoskeletal proteins to resemble that of the contractile phenotype. Actin and myosin filaments were tightly packed and highly organised while vimentin localised to the perinuclear region; focal adhesions were enlarged and concentrated at the cell periphery. Conversely, inhibition of endogenous Rho by C3 exoenzyme resulted in complete loss of contractile filaments without affecting vimentin distribution; focal adhesions were reduced in size and number. Treatment of synthetic state SMC with known regulators of SMC phenotype, heparin and thrombin, caused a modest increase in Rho activation. Long-term confluence and serum deprivation induced cells to return to a more contractile phenotype and this was augmented by heparin and thrombin. The results implicate RhoA for a role in regulating SMC phenotype and further show that activation of Rho by heparin and thrombin correlates with the ability of these factors to promote the contractile phenotype.     

Regulation of vascular smooth muscle cells by micropatterning

Vascular smooth muscle cells (SMCs) undergo morphological and phenotypic changes when cultured in vitro. To investigate whether SMC morphology regulates SMC functions, bovine aortic SMCs were grown on micropatterned collagen strips (50-, 30-, and 20-microm wide). The cell shape index and proliferation rate of SMCs on 30- and 20-microm strips were significantly lower than those on non-patterned collagen (control), and the spreading area was decreased only for cells patterned on the 20-microm strips, suggesting that SMC proliferation is dependent on cell shape index. The formation of actin stress fibers and the expression of alpha-actin were decreased in SMCs on the 20- and 30-microm collagen strips. SMCs cultured on micropatterned biomaterial poly-(D,L-lactide-co-glycolide) (PLGA) with 30-microm wide grooves also showed lower proliferation rate and less stress fibers than SMCs on non-patterned PLGA. Our findings suggest that micropatterned matrix proteins and topography can be used to control SMC morphology and that elongated cell morphology decreases SMC proliferation but is not sufficient to promote contractile phenotype.     

Phenotype-dependent response of cultured aortic smooth muscle to serum mitogens

Smooth muscle cells from the aortic media of adult pigs and monkeys have been grown in primary culture by plating cells enzymatically dissociated from the intact aorta. During the first 6 d these cells are in the "contractile" phenotype. That is, they contract slowly in response to angiotensin II and their cytoplasm is filled with both thick and thin myofilaments. In this state they do not incorporate [3H]thymidine into DNA or proliferate in response to normolipemic or hyperlipemic whole blood serum (WBS). After 7 d in culture the cells undergo a spontaneous modulation of phenotype to a "synthetic" state where they cannot be stimulated to contract and their cytoplasm is filled with organelles usually associated with synthesis of secretory protein. Thick myosin-containing filaments can no longer be demonstrated. When challenged with normolipemic or hyperlipemic WBS the cells incorporate [3H]thymidine into DNA and undergo logarithmic growth. It is suggested that when smooth muscle is the contractile phenotype (as normally exists for most cells in the aortic media of adult animals) it does not divide when challenged with serum mitogens but can undergo a change of phenotype to a synthetic state in which division can be stimulated.     

Alterations in chondrocyte cytoskeletal architecture during phenotypic modulation by retinoic acid and dihydrocytochalasin B-induced reexpression

The differentiated phenotype of rabbit articular chondrocytes was modulated in primary culture by treatment with 1 microgram/ml retinoic acid (RA) and reexpressed in secondary culture by treatment with the microfilament-disruptive drug dihydrocytochalasin B (DHCB) in the absence of RA. Because the effective dose of DHCB (3 microM) did not elicit detectable cell rounding or retraction, the nature and extent of microfilament modification responsible for induction of reexpression was evaluated. The network of microfilament stress fibers detected with rhodamine-labeled phalloidin in primary control chondrocytes was altered by RA to a "cobblestone" pattern of circularly oriented fibers at the cell periphery. Subsequent treatment with DHCB resulted in rapid changes in this pattern before overt reexpression. Stress fibers decreased in number and were reoriented. Parallel arrays of long fibers that traversed the cell were evident, in addition to fiber fragments and focal condensations of staining. Immunofluorescent staining of intermediate filaments revealed a marked decrease in complexity and intensity during RA treatment but no change during reexpression. An extended microtubular architecture was present throughout the study. These results clearly identify microfilaments as the principal affected cytoskeletal element and demonstrate that their modification, rather than complete disruption, is sufficient for reexpression. The specificity of DHCB and the reorientation of these filaments before reexpression of the differentiated phenotype suggests a causative role in the mechanism of reexpression.     

Uterine smooth muscle cells in primary culture

Summary Smooth muscle cells (SMC) were enzymatically isolated from the myometrium of adult rat and human uteri and grown in primary culture. Cell fine structure and cytoskeletal organization were followed by transmission electron microscopy and cytochemical demonstration of actin filaments, microtubules and intermediate filaments, and initiation of DNA synthesis was investigated by thymidine autoradiography. During the first few days in culture the cells spread out on the substrate and went through a morphological transformation including loss of myofilaments followed by formation of an extensive rough endoplasmic reticulum and a large Golgi complex. Actin filaments aggregated in stress fibers spanning the entire length of the cells and microtubules and intermediate filaments formed a radiating system originating in the juxtanuclear region. In vivo, the SMC contained intermediate filaments reactive for desmin, but as early as the first day of culture expressed vimentin as well. For five days at least, all cells remained positive for both proteins, but the staining for desmin decreased while that for vimentin increased. This structural modification was accompanied by initiation of DNA synthesis, with a peak on day 3 (45–55% labeled nuclei). Subconfluent, growth-arrested primary cultures responded weakly to purified platelet-derived growth factor and serum, and in secondary cultures no response to the mitogenic stimulation was obtained. The observations indicate that uterine SMC cultivated in vitro undergo a transformation from contractile to synthetic phenotype, similar to the transformation described previously for arterial SMC under the same conditions. The proliferative potential of the uterine cells is, however, markedly lower. The findings support the notions that the transition into synthetic phenotype is a necessary but not sufficient requirement for initiation of DNA synthesis in SMC and that visceral and vascular SMC represent separate differentiation pathways.     

Changes in osteopontin mRNA expression during phenotypic transition of rabbit arterial smooth muscle cells

 Transition from a contractile to a synthetic phenotype appears to be an early key event during the development of intimal thickening after arterial wall injury. We examined the expression of osteopontin mRNA, proliferation, and phenotypic properties of smooth muscle cells (SMCs) in rabbit neointima after balloon denudation and in primary culture. A strong osteopontin mRNA signal was detected in the thickened intima 1 week after balloon denudation and in the surface layer of the intima 2 weeks after balloon denudation. Ki-67 immunohistochemistry showed that osteopontin mRNA expression increased when SMCs entered the proliferating phase in the intima. Rabbit arterial SMCs on type I collagen after 1 day of primary culture with growth factors, as well as freshly isolated cells, were in the G₀ phase (contractile phenotype) and did not express osteopontin mRNA. After 3 days of culture, most cells entered the G_1B phase (synthetic phenotype) and expressed osteopontin mRNA. In the absence of growth factors, most cells transferred to the G_1A phase (intermediate phenotype) after 3 and 7 days, but did not express osteopontin mRNA. Our findings indicate that the osteopontin gene provides a marker that can be used to distinguish the phenotypic properties of vascular SMCs. Accepted: 22 November 1996     

Reorganization of structural proteins in vascular smooth muscle cells grown in collagen gel and basement membrane matrices (Matrigel): a comparison with their in situ counterparts

When smooth muscle cells are enzyme-dispersed from tissues they lose their original filament architecture and extracellular matrix surrounds. They then reorganize their structural proteins to accommodate a 2-D growth environment when seeded onto culture dishes. The aim of the present study was to determine the expression and reorganization of the structural proteins in rabbit aortic smooth muscle cells seeded into 3-D collagen gel and Matrigel (a basement membrane matrix). It was shown that smooth muscle cells seeded in both gels gradually reorganize their structural proteins into an architecture similar to that of their in vivo counterparts. At the same time, a gradual decrease in levels of smooth muscle-specific contractile proteins (mainly smooth muscle myosin heavy chain-2) and an increase in beta-nonmuscle actin occur, independent of both cell growth and extracellular matrix components. Thus, smooth muscle cells in 3-D extracellular matrix culture and in vivo have a similar filament architecture in which the contractile proteins such as actin, myosin, and alpha-actinin are organized into longitudinally arranged "myofibrils" and the vimentin-containing intermediate filaments form a meshed cytoskeletal network. However, the myofibrils reorganized in vitro contain less smooth muscle-specific and more nonmuscle contractile proteins.     

Integrin-type fibronectin receptors of rat arterial smooth muscle cells: isolation, partial characterization and role in cytoskeletal organization and control of differentiated properties

The spreading of freshly isolated rat arterial smooth muscle cells (SMCs) on a substrate of fibronectin (FN) is associated with marked changes in fine structure and function of the cells, collectively referred to as a modulation from a contractile to a synthetic phenotype. Recent studies have indicated that this process is mediated via an interaction between the minimal cell-attachment sequence of FN (RGDS) and cell surface receptors. Here, we report the isolation of such receptors by sequential chromatography on affinity columns of wheat germ agglutinin (WGA) and a 105-kDa cell-binding fragment of FN (105-kDa fragment). The receptor was composed of two proteins with electrophoretic mobilities in SDS-polyacrylamide gels of 160 and 115 kDa under nonreducing conditions and 150 and 130 kDa under reducing conditions. Immunoprecipitation of surface-labeled cells with a rabbit antiserum against the beta chain of the rat hepatocyte FN receptor similarly yielded two proteins of 160 and 115 kDa. In metabolically labeled cells an additional component of 105 kDa was precipitated, presumably representing a precursor of the 115-kDa protein. Immunocytochemical studies demonstrated that SMCs grown on laminin formed FN fibrils and actin filament bundles in close alignment with cell surface receptors after a few days of culture. In cells seeded on the 105-kDa fragment, the receptors were already arranged in parallel with actin filaments on the first day of culture. Later on, the cells secreted FN and laid down FN fibrils along the receptors on the cell surface and the actin filament bundles in the cytoplasm. Taken together, the findings indicate that arterial SMCs are equipped with FN receptors that belong to the integrin family of proteins and consists of alpha (160-kDa) and beta (115-kDa) subunits. The receptor complexes apparently play an important role in determining the differentiated characteristics of the cells, possibly by mediating a linkage between the extracellular matrix and the cytoskeleton.     

A variant derived from rabbit aortic smooth muscle: phenotype modulation and restoration of smooth muscle characteristics in cells in culture

We examined the relationship between growth arrest of smooth muscle cells and structural changes in microfilament bundles, and also that between the structural changes and the actions of contractile agonist using a multipassagable variant cell line (SM-3) derived from rabbit aortic smooth muscle cells. The content of smooth muscle type alpha-actin increased with density-dependent growth arrest of the SM-3 cells, but was attenuated in the logarithmically growing cultures. As assessed cytochemically, the growth-arrested cells contained longitudinally oriented bundles of actin-containing microfilament and myosin-based filaments visualized with rhodamine-phalloidin and antibody against myosin light chain 20, respectively, whereas both actin- and myosin-containing structures in logarithmically growing cells showed slight, shortened, or diffused patterns. Electron microscopic examination of the growth-arrested cells revealed that the cells contained numerous and conspicuous microfilament bundles associated with many compact electron-dense bodies. In addition, pinocytotic vesicles were often found near the plasma membrane in the growth-arrested cells. SM-3 cells in the growth-arrested phase responded to prostaglandin F2 alpha (3-30 microM) and rat endothelin (0.1-1.0 microM) with a reversible contractile response, in association with monophosphorylation and/or diphosphorylation of the myosin light chain 20. However, the influence of the contractile agonists was greatly reduced during logarithmic growth. These results suggest that in the SM-3 cells in the growth-arrested phase, there is a restoration of the contractile architecture and the myosin light chain phosphorylation system. Thus, this SM-3 cell line is expected to serve as a useful model for examining biochemical and physiological phenomena of smooth muscle.     

Plasma fibronectin promotes modulation of arterial smooth-muscle cells from contractile to synthetic phenotype

Isolated arterial smooth-muscle cells (SMCs) cultured in medium containing whole blood serum or plasma-derived serum undergo modulation from a contractile to a synthetic phenotype. This process includes the loss of myofilaments and cessation of the ability to contract. Instead, an extensive rough endoplasmic reticulum and a large Golgi complex are formed and, if properly stimulated, the cells start to proliferate actively and to produce extracellular-matrix components. In vivo, a similar change in the differentiated properties of SMCs appears to be an early key event in atherogenesis. The purpose of the present investigation was to try to identify plasma components that promote the modulation of the smooth-muscle phenotype. SMCs were enzymatically isolated from rat aorta and cultured in a defined, serum-free medium. The phenotypic state of the cells was determined by transmission electron microscopy, and their growth status was followed by 3H-thymidine autoradiography and cell counting. Under these conditions, Cohn fractions I (fibrinogen) and V (albumin) were found to partially support cell attachment and transition from the contractile to the synthetic phenotype, whereas fractions II-III and IV (globulins) were inactive in this respect. Analysis on adsorptive columns of gelatin Sepharose 4B indicated that Cohn fraction I, but not fraction V, contained fibronectin, an adhesive protein that is present in plasma and binds to fibrinogen. When seeded on a substrate of plasma fibronectin, the cells attached with high efficiency and modulated into the synthetic phenotype at a rate similar to that observed in serum-containing medium. In the absence of exogenous mitogens, the structural transformation of the cells was not accompanied by a proliferative response.(ABSTRACT TRUNCATED AT 250 WORDS)     

Caveolae and cholesterol distribution in vascular smooth muscle cells of different phenotypes.

Vascular smooth muscle cells (SMCs) grown in primary culture are converted from a contractile to a synthetic phenotype. This includes a marked morphological reorganization, with loss of myofilaments and formation of a large ER-Golgi complex. In addition, the number of cell surface caveolae is distinctly reduced and the handling of lipoprotein-derived cholesterol changed. Here we used filipin as a marker to study the distribution of cholesterol in SMCs by electron microscopy. In contractile cells, filipin-sterol complexes were preferentially found in caveolae and adjacent ER cisternae (present in both leaflets of the membranes). After exposure to LDL or cholesterol, labeling with filipin was increased both in membrane organelles and in the cytoplasm. In contrast, treatment with mevinolin (a cholesterol synthesis inhibitor) or beta-cyclodextrin (a molecule that extracts cholesterol from cells) decreased the reaction with filipin but did not affect the close relation between the ER and the cell surface. In synthetic cells, filipin-sterol complexes were diffusely spread in the plasma membrane and the strongest cytoplasmic reaction was noted in endosomes/lysosomes, both under normal conditions and after incubation with LDL or cholesterol. On the basis of the present findings, we propose a mechanism for direct exchange of cholesterol between the plasma membrane and the ER and more active in contractile than in synthetic SMCs.     

Characterization of intermediate filaments and their structural organization during epithelium formation in pigmented epithelial cells of the retina in vitro

Summary Retinal pigmented epithelial cells of chicken have circumferential microfilament bundles (CMBs) at the zonula adherens region. Isolated CMBs are polygons filled with a meshwork composed primarily of intermediate filaments; they show three major components of 200000, 55000, and 42000 daltons in SDS-gel electrophoresis. Here we have characterized the 55000-dalton protein immunochemically and ultrastructurally. Immunoblotting and immunofluorescence microscopy have shown that the 55000-dalton protein is an intermediate filament protein, vimentin.Vimentin filaments changed their distribution during differentiation of pigmented epithelial cells in culture. The protein in the elongated cells showed a fibroblast-type pattern of intermediate filaments. During epithelium formation, the filaments were uniformly distributed and formed a finer meshwork at the apical level. In pigmented epithelial cells that differentiated and matured in culture, vimentin and actin exhibited their characteristic behavior after treatment with colcemid. In the central to basal region of the cell, intermediate filaments formed thick perinuclear bundles. In the apical region, however, intermediate filaments changed in organization from a nonpolarized meshwork to a polarized bundle-like structure. Simultaneously, new actin bundles were formed, running parallel to the intermediate filaments. This suggests that there is some interaction between microfilaments and intermediate filaments in the apical region of these cells.     

Heterogeneous distribution of isoactins in cultured vascular smooth muscle cells does not reflect segregation of contractile and cytoskeletal domains.

We have previously demonstrated that alpha-smooth muscle (alpha-SM) actin is predominantly distributed in the central region and beta-non-muscle (beta-NM) actin in the periphery of cultured rabbit aortic smooth muscle cells (SMCs). To determine whether this reflects a special form of segregation of contractile and cytoskeletal components in SMCs, this study systematically investigated the distribution relationship of structural proteins using high-resolution confocal laser scanning fluorescent microscopy. Not only isoactins but also smooth muscle myosin heavy chain, alpha-actinin, vinculin, and vimentin were heterogeneously distributed in the cultured SMCs. The predominant distribution of beta-NM actin in the cell periphery was associated with densely distributed vinculin plaques and disrupted or striated myosin and alpha-actinin aggregates, which may reflect a process of stress fiber assembly during cell spreading and focal adhesion formation. The high-level labeling of alpha-SM actin in the central portion of stress fibers was related to continuous myosin and punctate alpha-actinin distribution, which may represent the maturation of the fibrillar structures. The findings also suggest that the stress fibers, in which actin and myosin filaments organize into sarcomere-like units with alpha-actinin-rich dense bodies analogous to Z-lines, are the contractile structures of cultured SMCs that link to the network of vimentin-containing intermediate filaments through the dense bodies and dense plaques.     

Inhibitory role of reactive oxygen species in the differentiation of multipotent vascular stem cells into vascular smooth muscle cells in rats: a novel aspect of traditional culture of rat aortic smooth muscle cells

Proliferative or synthetic vascular smooth muscle cells (VSMCs) are widely accepted to be mainly derived from the dedifferentiation or phenotypic modulation of mature contractile VSMCs, i.e., a phenotype switch from a normally quiescent and contractile type into a proliferative or synthetic form. However, this theory has been challenged by recent evidence that synthetic VSMCs predominantly originate instead from media-derived multipotent vascular stem cells (MVSCs). To test these hypotheses further, we re-examine whether the conventional rat aortic SMC (RASMC) culture involves the VSMC differentiation of MVSCs or the dedifferentiation of mature VSMCs and the potential mechanism for controlling the synthetic phenotype of RASMCs. We enzymatically isolated RASMCs and cultured the cells in both a regular growth medium (RGM) and a stem cell growth medium (SCGM). Regardless of culture conditions, only a small portion of freshly isolated RASMCs attaches, survives and grows slowly during the first 7 days of primary culture, while expressing both SMC- and MVSC-specific markers. RGM-cultured cells undergo a process of synthetic SMC differentiation, whereas SCGM-cultured cells can be differentiated into not only synthetic SMCs but also other somatic cells. Notably, compared with the RGM-cultured differentiated RASMCs, the SCGM-cultured undifferentiated cells exhibit the phenotype of MVSCs and generate greater amounts of reactive oxygen species (ROS) that act as a negative regulator of differentiation into synthetic VSMCs. Knockdown of phospholipase A2, group 7 (Pla2g7) suppresses ROS formation in the MVSCs while enhancing SMC differentiation of MVSCs. These results suggest that cultured synthetic VSMCs can be derived from the SMC differentiation of MVSCs with ROS as a negative regulator.     

Characterization of vascular smooth muscle cell phenotype in long-term culture

Summary Studies of bovine carotid artery smooth muscle cells, during long-term in vitro subcultivation (up to 100 population doublings), have revealed phenotypic heterogeneity among cells, as characterized by differences in proliferative behavoir, cell morphology, and contractile-cytoskeletal protein profiles. In vivo, smooth muscle cells were spindle-shaped and expressed desmin and alpha-smooth muscle actin (50% of total actin) as their predominant cytoskeletal and contractile proteins. Within 24 h of culture, vimentin rather than desmin was the predominant intermediate filament protein, with little change in alpha-actin content. Upon initial subcultivation, all cells were flattened and fibroblastic in appearance with a concommitant fivefold reduction in alpha-actin content, whereas the beta and gamma nonmuscle actins predominated. In three out of four cell lines studied, fluctuations in proliferative activity were observed during the life span of the culture. These spontaneous fluctuations in proliferation were accompanied by coordinated changes in morphology and contractile-cytoskeletal protein profiles. During periods of enhanced proliferation a significant proportion of cells reverted to their original spindle-shaped morphology with a simultaneous increase in alpha-actin content (20 to 30% of total actin). These results suggest that in long-term culture smooth muscle cells undergo spontaneous modulations in cell phenotype and may serve as a useful model for studying the regulation of intracellular protein expression. This work was supported by grants from from National Institutes of Health, Bethesda, MD, to DMW (HL35684), JW (HL36412), and JM and RL (SCOR HL 14212).     

The effects of cytochalasin B on the cytoplasmic contractile network revealed by whole-cell transmission electron microscopy

The ultrastructure of the contractile response to cytochalasin B (CB) has been studied using whole-cell electron microscopy. The actin-containing contractile network rapidly condenses into numerous stellate microfilament foci (SMF). These SMF punctuate the cytoplasm, and are frequently associated with an extensive persistent cytoskeleton containing microtubules and intermediate filaments. This association of SMF and persistent cytoskeleton appears to mediate the arborized morphology induced by CB. Eventually SMF aggregate and migrate towards the nucleus. Concomitantly the cell surface is differentiated into clusters of miniblebs which migrate to the nucleus. SMF loss from the periphery resulted in respreading to a flattened angular morphology within which the nucleus was frequently displaced. The role of the actin network, and the mechanism of these CB-induced contractile alterations are discussed.