Comparison of the regional distribution of calspectin (nonerythroid spectrin or fodrin), alpha-actinin, vinculin nonerythroid protein 4.1, and calpactin in normal and avian sarcoma virus- or Rous sarcoma virus-induced transformed cells

Changes in the Balance between Caldesmon Regulated by p21-activated Kinases and the Arp2/3 Complex Govern Podosome Formation

Podosomes are dynamic cell adhesion structures that degrade the extracellular matrix, permitting extracellular matrix remodeling. Accumulating evidence suggests that actin and its associated proteins play a crucial role in podosome dynamics. Caldesmon is localized to the podosomes, and its expression is down-regulated in transformed and cancer cells. Here we studied the regulatory mode of caldesmon in podosome formation in Rous sarcoma virus-transformed fibroblasts. Exogenous expression analyses revealed that caldesmon represses podosome formation triggered by the N-WASP-Arp2/3 pathway. Conversely, depletion of caldesmon by RNA interference induces numerous small-sized podosomes with high dynamics. Caldesmon competes with the Arp2/3 complex for actin binding and thereby inhibits podosome formation. p21-activated kinases (PAK)1 and 2 are also repressors of podosome formation via phosphorylation of caldesmon. Consequently, phosphorylation of caldesmon by PAK1/2 enhances this regulatory mode of caldesmon. Taken together, we conclude that in Rous sarcoma virus-transformed cells, changes in the balance between PAK1/2-regulated caldesmon and the Arp2/3 complex govern the formation of podosomes.

PAK1 induces podosome formation in A7r5 vascular smooth muscle cells in a PAK-interacting exchange factor-dependent manner

Remodeling of the vascular smooth muscle cytoskeleton is essential for cell motility involved in the development of diseases such as arteriosclerosis and restenosis. The p21-activated kinase (PAK), which is an effector of the Rho GTPases Rac and Cdc42, has been shown to be involved in cytoskeletal remodeling and cell motility. We show herein that expression of cytoskeletally active constructs of PAK1 is able to induce the formation of dynamic, podosome-like F-actin columns in the A7r5 vascular smooth muscle cell line. Most of these actin columns appear at the junctions between stress fibers and focal adhesions and contain several known podosomal protein markers, such as cortactin, Arp2/3, α-actinin, and vinculin. The kinase activity of PAK plays a role in the regulation of the turnover rates of these actin columns but is not essential for their formation. The ability of PAK to interact with the PAK-interacting exchange factor (PIX) but not with Rac or Cdc42, however, is required for the formation of the actin columns as well as for the translocation of PIX and G protein-coupled receptor kinase-interacting protein (GIT) to focal adhesions adjacent to the actin columns. These findings suggest that interaction between PAK and PIX, as well as the recruitment of PIX and GIT to focal adhesions, plays an important role in the formation of actin columns that resemble podosomes induced by phorbol ester in vascular smooth muscle cells.

Phenotype-dependent expression of alpha-smooth muscle actin in visceral smooth muscle cells

Alpha-Smooth muscle actin is one of the molecular markers for a phenotype of vascular smooth muscle cells, because the actin is a major isoform expressed in vascular smooth muscle cells and its expression is upregulated during differentiation. Here, we first demonstrate that the phenotype-dependent expression of this actin in visceral smooth muscles is quite opposite to that in vascular smooth muscles. This actin isoform is not expressed in adult chicken visceral smooth muscles including gizzard, trachea, and intestine except for the inner layer of intestinal muscle layers, whereas its expression is clearly detected in these visceral smooth muscles at early stages of the embryo (10-day-old embryo) and is developmentally downregulated. In cultured gizzard smooth muscle cells maintaining a differentiated phenotype, alpha-smooth muscle actin is not detected while its expression dramatically increases during serum-induced dedifferentiation. Promoter analysis reveals that a sequence (-238 to -219) in the promoter region of this actin gene acts as a novel negative cis-element. In conclusion, the phenotype-dependent expression of alpha-smooth muscle actin would be regulated by the sum of the cooperative contributions of the negative element and well-characterized positive elements, purine-rich motif, and CArG boxes and their respective transacting factors.

Actin-binding protein, drebrin, accumulates in submembranous regions in parallel with neuronal differentiation

Drebrins are developmentally regulated actin-binding proteins. In this study, we analyzed subcellular distribution of drebrin E in neuroblastoma cells (SH-SY5Y) in culture, especially in terms of its relationship to actin filaments. In undifferentiated cells, drebrin E was scattered as flocculus small dots along the stress fibers and also accumulated at adhesion plaques. In parallel with the neuronal differentiation following retinoic acid treatment, drebrin E was accumulated, accompanying filamentous (F) actin, in the submembranous cortical cytoplasm. Similar submembranous localization of drebrins was observed in primary cultured neurons. In the presence of drebrin E F-actin was more stable against cytochalasin D than F-actin lacking drebrin E. These results suggest that drebrin E plays a role in neuronal morphological differentiation by changing its subcellular localization with stabilized F-actin.

Actin-based cytoskeleton in growth cone activity

A growing tip of neurite, the neuronal growth cone, is a highly motile and adhesive form of cytoarchitecture. The growth cone plays vital roles for navigation, elongation and maintenance of neurites. One major constituent of growth cones, regulated by the intracellular Ca2+ signal, is the actin-based cytoskeleton. In this article, I have summarized four types of Ca(2+)-dependent regulation of the actin-based cytoskeleton in growth cones: gelsolin-actin, myosin II-actin microfilament, myosin II-actin, and Ca(2+)-sensitive alpha-actinin-actin systems. The four examples of Ca(2+)-dependent regulation described here may be involved in growth cone motility. The actin-based membrane skeleton forming a meshwork beneath the cytoplasmic surface of the growth cone membrane is also important for adhesion of growth cones to recognize cue molecules. The actin-based membrane skeleton participates in this recognition process and the adhesion-dependent signal transduction in association with receptors for cell adhesion molecules.

Morphological and biochemical analyses of contractile proteins (actin, myosin, caldesmon and tropomyosin) in normal and transformed cells

The expression and intracellular distribution of four contractile proteins (actin, myosin, caldesmon and tropomyosin) in normal fibroblasts and their transformed counterparts by Rous or avian sarcoma virus were compared. By analyzing the isoformal expression of actin, caldesmon and tropomyosin using two-dimensional gel electrophoresis, only tropomyosin showed significant alteration in its isoformal expression accompanied by transformation. Morphological study revealed that in normal cells, myosin, caldesmon and tropomyosin were distributed periodically along stress fibers, but were excluded from focal adhesions (adhesion plaques), at which stress fibers terminate. By contrast, the contractile proteins were concentrated within the protrusions of the ventral cell surface of transformed cells, which are cell-adhesive structures with high motility (podosomes). Regional analysis indicated that the contractile proteins do not show diffuse distribution within podosomes. Myosin, some caldesmon and tropomyosin in association with F-actin were localized in the region surrounding the core domains of podosomes. A major part of the caldesmon was, however, located in the core domain with short F-actin bundles. In order to compare the stability and the molecular organization of stress fibers with that of the short F-actin bundles within podosomes, the dorsal plasma membranes of the cells were removed by lysis and squirting. Then, the ruptured cells were treated with various buffers containing high salt, ATP or Ca2+/calmodulin. Myosin, caldesmon and tropomyosin were strongly associated with stress fibers of the ruptured normal fibroblasts even in a buffer containing high salt or Ca2+/calmodulin. On the other hand, myosin and tropomyosin within podosomes were easily extracted by lysis and squirting. And, the remaining caldesmon in podosomes was separated from the short F-actin bundles with high salt or Ca2+/calmodulin buffer. The present findings suggest that the high motility of podosomes from transformed cells is based on the actomyosin system, and that the stable adherence of focal adhesions of normal cells is due to a lack of this system. The accumulation of contractile proteins and their dynamic association within podosomes might be the cause of the short half-life of the structure. In relation to its localization in the core domain of podosomes without myosin and tropomyosin, the function of caldesmon has been discussed.

Biochemical identification of alpha-fodrin and protein 4.1 in human keratinocytes

The mature erythrocyte has a cytoskeleton of less complexity than that of nucleated cells and has been elucidated in greater detail. Two of its major components are the heterodimeric protein spectrin and protein 4.1. We report here our isolation from human keratinocytes of immunoreactive forms of both protein 4.1 and of alpha-fodrin, the extra-erythrocytic form of alpha-spectrin. These keratinocyte proteins are approximately 125 kD and 240 kD in size, respectively. We also have isolated clones containing alpha-fodrin and protein 4.1 sequences from a human keratinocyte cDNA library. These sequences confirm the active transcription in keratinocytes of the alpha-fodrin and protein 4.1 genes. Both alpha-fodrin and protein 4.1 mRNA are detectable by Northern blot analysis in human keratinocytes, where their abundance appears not to be regulated by calcium concentration in the medium.

Involvement of the membrane cytoskeletal proteins and the src gene product in growth cone adhesion and movement

The neuronal growth cone is a highly motile and adhesive structure, leading to maintain and promote neurite outgrowth. Using immunocytochemical and biochemical techniques, we investigated the regional distribution of the membrane cytoskeletal proteins, such as alpha-actinin, calspectin (nonerythroid spectrin or fodrin) and actin, and the proto-oncogene product, pp60c-src, in the growth cone. During a course of this study, the two types of alpha-actinin, having Ca2(+)-sensitive and -insensitive actin-binding abilities, were identified. These three membrane cytoskeletal proteins and pp60c-src showed discrete differential distributions coinciding with the different functions of the growth cone substractures. Ca2(+)-sensitive alpha-actinin, calspectin and pp60c-src were observed to localize in the growth cone body and the distal portion of neurites, which are the adhesive sites of growth cone and neurite. By contrast, Ca2(+)-sensitive alpha-actinin and actin were densely concentrated in the filopodia. These results suggest that Ca2(+)-insensitive alpha-actinin, calspectin and pp60c-src may be involved in adhesiveness of growth cone, and Ca2(+)-sensitive alpha-actinin and actin in Ca2(+)-dependent filopodial movement. Furthermore, we will discuss the functional and structural similarities between the growth cone and the motile contact which is also the adhesive site of motile, transformed and cancer cells.

Conformational change and localization of calpactin I complex involved in exocytosis as revealed by quick-freeze, deep-etch electron microscopy and immunocytochemistry

Calpactin I complex, a calcium-dependent phospholipid-binding protein, promotes aggregation of chromaffin vesicles at physiological micromolar calcium ion levels. Calpactin I complex was found to be a globular molecule with a diameter of 10.7 +/- 1.7 (SD) nm on mica. When liposomes were aggregated by calpactin, quick-freeze, deep-etching revealed fine thin strands (6.5 +/- 1.9 [SD] nm long) cross-linking opposing membranes in addition to the globules on the surface of liposomes. Similar fine strands were also observed between aggregated chromaffin vesicles when they were mixed with calpactin in the presence of Ca2+ ion. In cultured chromaffin cells, similar cross-linking short strands (6-10 nm) were found between chromaffin vesicles and the plasma membrane after stimulation with acetylcholine. Plasma membranes also revealed numerous globular structures approximately 10 nm in diameter on their cytoplasmic surface. Immunoelectron microscopy on frozen ultrathin sections showed that calpactin I was closely associated with the inner face of the plasma membranes and was especially conspicuous between plasma membranes and adjacent vesicles in chromaffin cells. These in vivo and in vitro data strongly suggest that calpactin I complex changes its conformation to cross-link vesicles and the plasma membrane after stimulation of cultured chromaffin cells.

Alpha-actinins, calspectin (brain spectrin or fodrin), and actin participate in adhesion and movement of growth cones

We have used biochemical and immunocytochemical techniques to investigate the possible involvement of membrane cytoskeletal elements such as alpha-actinin, calspectin (brain spectrin or fodrin), and actin in growth cone activities. During NGF-induced differentiation of PC12 cells, alpha-actinin increased in association with neurite outgrowth and was predominantly distributed throughout the entire growth cone and the distal portion of neurites. Filopodial movements were sensitive to Ca2+ flux. Two types of alpha-actinin, with Ca2(+)-sensitive and -insensitive actin binding abilities, were identified in the differentiated cells. Ca2(+)-sensitive alpha-actinin and actin filaments were concentrated in filopodia. The Ca2(+)-insensitive protein was distributed from the body of the growth cone to the distal portion of neurites, corresponding to the substratum-adhesive sites. The location of calspectin in growth cones was similar to that of the Ca2(+)-insensitive alpha-actinin. These results are consistent with the hypothesis that Ca2(+)-sensitive alpha-actinin and actin filaments are involved in Ca2(+)-dependent filopodial movement and Ca2(+)-insensitive alpha-actinin and calspectin are associated with adhesion of growth cones.