A hyaluronate binding protein transiently codistributes with p21 in cultured cell lines

Hyaluronate (HA) affects the migratory and adhesive properties of cells. HABP, one of the sites which bind HA, localizes in the ruffling lamellae of normal migrating fibroblasts. Similarly, p21 in K-ras oncogene-transformed cells appears enhanced in membrane ruffles. To investigate the possibility that p21 and HABP are functionally linked, their subcellular distribution in two K-ras-transformed lines was examined by double label immunofluorescence and correlated with motility. In both lines, the majority of cells were p21^k-ras and HABP positive at 24 h after subculture. However, immunofluorescence for HABP both decreased and relocated, from ruffles and cell processes to cell bodies, with time whereas the intensity and distribution of staining for p21 remained constant. In doubly positive cells, HABP and p21 colocalized in the ruffles at 24 h, but not at 72 h after subculture. The times after subculture at which changes in the immunofluorescent pattern of HABP occurred differed with cell type and correlated with their migratory rate. Thus, the migratory rate of KNRK cells, which was less than in the K-C3H-10T1/2 cells, correlated with both an earlier decrease in HABP and an earlier loss of codistribution between HABP and p21 compared to K-C3H-10T1/2 cells. Further evidence of a functional link between HABP and p21^k-ras was suggested by the ability of hyaluronic acid, which induces ruffling in K-C3H-10T1/2 cells, to promote the coassociation of p21^k-ras and HABP. These results demonstrate a transient codistribution of p21 and HABP, in ruffles, that is possibly related to migratory activity and/or cell-surface changes following subculture.     

A hyaluronan-binding protein shows a partial and temporally regulated codistribution with actin on locomoting chick heart fibroblasts

The ultrastructural distribution of a hyaluronan-binding protein (HABP) and its relationship to actin-containing microfilaments were studied with immunocytochemistry. Ultrastructural analysis localized HABP to the cell coat and demonstrated that it occurred largely in cell processes where the apical surfaces were immunopositive. The codistribution of HABP with actin-containing microfilaments in cell processes was demonstrated with double immunolabeling using monoclonal antibodies to actin and monospecific, polyclonal antibodies to HABP. Both the topological localization of HABP and its cytoskeletal coassociations were modulated by cells during different cellular phases. Thus, in cells exhibiting large lamellae and few actin fibrils, typical of rapidly locomoting cells, HABP codistributed primarily with the actin meshwork occurring in cell processes, although some codistribution between the two proteins occurred over the cell body. In cells containing prominent stress fibers and less obvious lamellae, HABP was absent in cell processes but, rather, was aligned primarily along actin fibrils occurring in the cell body. A functional association between HABP and the actin-containing cytoskeleton was suggested by the ability of cytochalasin D to coordinately alter the distribution of HABP and disrupt its coassociation with actin. As well, the addition of hyaluronan to monolayers increased the association of HABP with a Triton-insoluble cytoskeleton. The possible roles of HABP in cell motility and cytoskeletal organization are discussed.     

Hyaluronan and a cell-associated hyaluronan binding protein regulate the locomotion of ras-transformed cells

Hyaluronan (HA) and one of its cell binding sites, fibroblast hyaluronan binding protein (HABP), is shown to contribute to the regulation of 10T1/2 cell locomotion that contain an EJ-ras-metallothionein (MT-1) hybrid gene. Promotion of the ras-hybrid gene with zinc sulfate acutely stimulates, by 6-10-fold, cell locomotion. After 10 h, locomotion drops to two- to threefold above that of uninduced cells. Several observations indicate increased locomotion is partly regulated by HA. These include the ability of a peptide that specifically binds HA (HABR) to reduce locomotion, the ability of HA (0.001-0.1 micrograms/ml), added at 10-30 h after induction to stimulate locomotion back to the original, acute rate, and the ability of an mAb specific to a 56-kD fibroblast HABP to block locomotion. Further, both HA and HABP products are regulated by induction of the ras gene. The effect of exogenous HA is blocked by HABR, is dose-dependent and specific in that chondroitin sulfate or heparan have no significant effect. Stimulatory activity is retained by purified HA and lost upon digestion with Streptomyces hyaluronidase indicating that the activity of HA resides in its glycosaminoglycan chain. Uninduced cells are not affected by HA, HABR, or mAb and production of HA or HABP is not altered during the experimental period. These results suggest that ras-transformation activates an HA/HABP locomotory mechanism that forms part of an autocrine motility mechanism. Reliance of induced cells on HA/HABP for locomotion is transient and specific to the induced state.     

Overexpression of hyaluronan-binding protein 1 (HABP1/p32/gC1qR) in HepG2 cells leads to increased hyaluronan synthesis and cell proliferation by up-regulation of cyclin D1 in AKT-dependent pathway

Overexpression of the mature form of hyaluronan-binding protein 1 (HABP1/gC1qR/p32), a ubiquitous multifunctional protein involved in cellular signaling, in normal murine fibroblast cells leads to enhanced generation of reactive oxygen species (ROS), mitochondrial dysfunction, and ultimately apoptosis with the release of cytochrome c. In the present study, human liver cancer cell line HepG2, having high intracellular antioxidant levels was chosen for stable overexpression of HABP1. The stable transformant of HepG2, overexpressing HABP1 does not lead to ROS generation, cellular stress, and apoptosis, rather it induced enhanced cell growth and proliferation over longer periods. Phenotypic changes in the stable transformant were associated with the increased "HA pool," formation of the "HA cable" structure, up-regulation of HA synthase-2, and CD44, a receptor for HA. Enhanced cell survival was further supported by activation of MAP kinase and AKT-mediated cell survival pathways, which leads to an increase in CYCLIN D1 promoter activity. Compared with its parent counterpart HepG2, the stable transformant showed enhanced tumorigenicity as evident by its sustained growth in low serum conditions, formation of the HA cable structure, increased anchorage-independent growth, and cell-cell adhesion. This study suggests that overexpression of HABP1 in HepG2 cells leads to enhanced cell survival and tumorigenicity by activating HA-mediated cell survival pathways.     

Identification and regulation of a molecular module for bleb-based cell motility

Single-cell migration is a key process in development, homeostasis, and disease. Nevertheless, the control over basic cellular mechanisms directing cells into motile behavior in?vivo is largely unknown. Here, we report on the identification of a minimal set of parameters the regulation of which confers proper morphology and cell motility. Zebrafish primordial germ cells rendered immotile by knockdown of Dead end, a negative regulator of miRNA function, were used as a platform for identifying processes restoring motility. We have defined myosin contractility, cell adhesion, and cortex properties as factors whose proper regulation is sufficient for restoring cell migration of this cell type. Tight control over the level of these cellular features, achieved through a balance between miRNA-430 function and the action of the RNA-binding protein Dead end, effectively transforms immotile primordial germ cells into polarized cells that actively migrate relative to cells in their environment.     

Changes in cholesterol levels in the plasma membrane modulate cell signaling and regulate cell adhesion and migration on fibronectin

The number and distribution of lipid molecules, including cholesterol in particular, in the plasma membrane, may play a key role in regulating several physiological processes in cells. We investigated the role of membrane cholesterol in regulating cell shape, adhesion and motility. The acute depletion of cholesterol from the plasma membrane of cells that were well spread and motile on fibronectin caused the rounding of these cells and decreased their adhesion to and motility on fibronectin. These modifications were less pronounced in cells plated on laminin, vitronectin or plastic, indicating that cholesterol-mediated changes in adhesion and motility are more specific for adhesion mediated by fibronectin-specific integrins, such as alpha5beta1. These changes were accompanied by remodeling of the actin cytoskeleton, the spatial reorganization of paxillin in the membrane, and changes to the dynamics of alpha5 integrin and paxillin-rich focal adhesions. Levels of tyrosine phosphorylation at position 576/577 of FAK and Erk1/Erk2 MAP-kinase activity levels were both lower in cholesterol-depleted than in control cells. These levels normalized only on fibronectin when cholesterol was reincorporated into the cell membrane. Thus, membrane cholesterol content has a specific effect on certain signaling pathways specifically involved in regulating cell motility on fibronectin and organization of the actin cytoskeleton.     

Possible role of the 34-kilodalton hyaluronic acid-binding protein in visceral Leishmaniasis.

Leishmania donovani, the causative organism of human visceral leishmaniasis, invades host macrophages through its interaction with the cell surface molecules of target cells. The presence of a cell surface protein (Mr 34 kDa) having specific affinity toward hyaluronan (HA), a major extracellular matrix component, has been previously reported in macrophage cell lines. In order to identify the possible role of this HA-binding protein (HABP) in leishmaniasis, initially we demonstrated its overexpression in spleen, liver, macrophages, and serum of hamsters infected with L. donovani. We further observed higher levels of HABP in the macrophage cell line J774.G8 upon infection with L. donovani. Finally, we observed a significant increase in the level of HABP in the serum of patients with kala-azar. In order to understand its functional role in leishmaniasis, we report here a significant inhibition of cellular phosphorylation of HABP in hamster macrophages infected with L. donovani. Interestingly, the 34-kDa HABP was shown to bind with 2 proteins of promastigotes as well as amastigotes of L. donovani (with molecular masses of 55 kDa and 30 kDa respectively), suggesting a possible role for HABP in adhesion during the interaction of promastigotes and macrophages.     

Hyaluronan and the hyaluronan receptor RHAMM promote focal adhesion turnover and transient tyrosine kinase activity

The molecular mechanisms whereby hyaluronan (HA) stimulates cell motility was investigated in a C-H-ras transformed 10T 1/2 fibroblast cell line (C3). A significant (p < 0.001) stimulation of C3 cell motility with HA (10 ng/ml) was accompanied by an increase in protein tyrosine phosphorylation as detected by anti-phosphotyrosine antibodies using immunoblot analysis and immunofluorescence staining of cells. Tyrosine phosphorylation of several proteins was found to be both rapid and transient with phosphorylation occurring within 1 min of HA addition and dissipating below control levels 10-15 min later. These responses were also elicited by an antibody generated against a peptide sequence within the HA receptor RHAMM. Treatment of cells with tyrosine kinase inhibitors (genistein, 10 micrograms/ml or herbimycin A, 0.5 micrograms/ml) or microinjection of anti-phosphotyrosine antibodies inhibited the transient protein tyrosine phosphorylation in response to HA as well as prevented HA stimulation of cell motility. To determine a link between HA-stimulated tyrosine phosphorylation and the resulting cell locomotion, cytoskeletal reorganization was examined in C3 cells plated on fibronectin and treated with HA or anti-RHAMM antibody. These agents caused a rapid assembly and disassembly of focal adhesions as revealed by immunofluorescent localization of vinculin. The time course with which HA and antibody induced focal adhesion turnover exactly paralleled the induction of transient protein tyrosine phosphorylation. In addition, phosphotyrosine staining colocalized with vinculin within structures in the lamellapodia of these cells. Notably, the focal adhesion kinase, pp125FAK, was rapidly phosphorylated and dephosphorylated after HA stimulation. These results suggest that HA stimulates locomotion via a rapid and transient protein tyrosine kinase signaling event mediated by RHAMM. They also provide a possible molecular basis for focal adhesion turnover, a process that is critical for cell locomotion.     

Increased Hyaluronan Levels in HABP1/p32/gC1qR Overexpressing HepG2 Cells Inhibit Autophagic Vacuolation Regulating Tumor Potency

Tumor growth and development is influenced by its microenvironment. A major extracellular matrix molecule involved in cancer progression is hyaluronan (HA). Hyaluronan and expression of a number of hyaladherin family proteins are dramatically increased in many cancer malignancies. One such hyaladherin, hyaluronan-binding protein 1 (HABP1/p32/gC1qR) has been considered to be a biomarker for tumor progression. Interestingly, overexpression of HABP1 in fibroblast has been shown to increase autophagy via generation of excess reactive oxygen species (ROS) and depletion of HA leading to apoptosis. Cancerous cells are often found to exhibit decreased rate of proteolysis/autophagy in comparison to their normal counterparts. To determine if HABP1 levels alter tumorigenicity of cancerous cells, HepR21, the stable transfectant overexpressing HABP1 in HepG2 cell line was derived. HepR21 has been shown to have increased proliferation rate than HepG2, intracellular HA cable formation and enhanced tumor potency without any significant alteration of intracellular ROS. In this paper we have observed that HepR21 cells containing higher endogenous HA levels, have downregulated expression of the autophagic marker, MAP-LC3, consistent with unaltered levels of endogenous ROS. In fact, HepR21 cells seem to have significant resistance to exogenous ROS stimuli and glutathione depletion. HepR21 cells were also found to be more resilient to nutrient starvation in comparison to its parent cell line. Decline in intracellular HA levels and HA cables in HepR21 cells upon treatment with HAS inhibitor (4-MU), induced a surge in ROS levels leading to increased expression of MAP-LC3 and tumor suppressors Beclin 1 and PTEN. This suggests the importance of HABP1 induced HA cable formation in enhancing tumor potency by maintaining the oxidant levels and subsequent autophagic vacuolation.     

Golgi localization and dynamics of hyaluronan binding protein 1 （HABP1／p32／C1QBP） during the cell cycle

Hyaluronan binding protein 1 (HABP1) is a negatively charged multifunctional mammalian protein with a unique structural fold. Despite the fact that HABP1 possesses mitochondrial localization signal, it has also been localized to other cellular compartments. Using indirect immunofluorescence, we examined the sub-cellular localization of HABP1 and its dynamics during mitosis. We wanted to determine whether it distributes in any distinctive manner after mitoticnuclear envelope disassembly or is dispersed randomly throughout the cell. Our results reveal the golgi localization of HABP1 and demonstrate its complete dispersion throughout the cell during mitosis. This distinctive distribution pattern of HABP1 during mitosis resembles its ligand hyaluronan, suggesting that in concert with each other the two molecules play critical roles in this dynamic process.     

Vascular smooth muscle cell phenotypic modulation in culture is associated with reorganisation of contractile and cytoskeletal proteins.

Smooth muscle cells (SMC) exhibit a functional plasticity, modulating from the mature phenotype in which the primary function is contraction, to a less differentiated state with increased capacities for motility, protein synthesis, and proliferation. The present study determined, using Western analysis, double-label immunofluorescence and confocal microscopy, whether changes in phenotypic expression of rabbit aortic SMC in culture could be correlated with alterations in expression and distribution of structural proteins. "Contractile" state SMC (days 1 and 3 of primary culture) showed distinct sorting of proteins into subcellular domains, consistent with the theory that the SMC structural machinery is compartmentalised within the cell. Proteins specialised for contraction (alpha-SM actin, SM-MHC, and calponin) were highly expressed in these cells and concentrated in the upper central region of the cell. Vimentin was confined to the body of the cell, providing support for the contractile apparatus but not co-localising with it. In line with its role in cell attachment and motility, beta-NM actin was localised to the cell periphery and basal cortex. The dense body protein alpha-actinin was concentrated at the cell periphery, possibly stabilising both contractile and motile apparatus. Vinculin-containing focal adhesions were well developed, indicating the cells' strong adhesion to substrate. In "synthetic" state SMC (passages 2-3 of culture), there was decreased expression of contractile and adhesion (vinculin) proteins with a concomitant increase in cytoskeletal proteins (beta-non-muscle [NM] actin and vimentin). These quantitative changes in structural proteins were associated with dramatic changes in their distribution. The distinct compartmentalisation of structural proteins observed in "contractile" state SMC was no longer obvious, with proteins more evenly distributed throughout the cytoplasm to accommodate altered cell function. Thus, SMC phenotypic modulation involves not only quantitative changes in contractile and cytoskeletal proteins, but also reorganisation of these proteins. Since the cytoskeleton acts as a spatial regulator of intracellular signalling, reorganisation of the cytoskeleton may lead to realignment of signalling molecules, which, in turn, may mediate the changes in function associated with SMC phenotypic modulation.     

Inhibition of bFGF/EGF-dependent endothelial cell proliferation by the hyaluronan-binding protease from human plasma

Recently we identified a plasma serine protease with a high affinity to glycosaminoglycans like heparin or hyaluronic acid, termed hyaluronan-binding protease (HABP). Since glycosaminoglycans are found on cell surfaces and in the extracellular matrix a physiological role of this plasma protease in a pericellular environment was postulated. Here we studied the influence of HABP on the regulation of endothelial cell growth. We found that HABP efficiently prevented the basic fibroblast growth factor/epidermal growth factor (bFGF/EGF)-dependent proliferation of human umbilical vein endothelial cells. Proteolytic cleavage of adhesion molecules was found to be involved, but was not solely responsible for the anti-proliferative activity. Pre-treatment of growth factor-supplemented cell culture medium with HABP indicated that no direct contact between the active protease and cells was required for growth inhibition. In vitro studies revealed a growth factor-directed activity of HABP, resulting in complexation and partial hydrolysis and, thus, inactivation of basic fibroblast growth factor, a potent mitogen for endothelial cells. Heparin and heparan sulfate fully protected bFGF from complexation and cleavage by HABP, although these glycosaminoglycans are known to enhance the proteolytic activity of HABP. This finding suggested that free circulating bFGF rather than bFGF bound to heparan sulfate proteoglycans would be a physiologic substrate. In conclusion, down-regulation of bFGF-dependent endothelial cell growth represents an important mechanism through which HABP could control cell growth in physiologic or pathologic processes like angiogenesis, wound healing or tumor development.     

Changes in the phosphorylation and distribution of vinculin during nerve growth factor induced neurite outgrowth

The mechanism of neurite initiation and elongation was studied using nerve growth factor (NGF) treatment of PC12 cells. The distribution of focal adhesion sites and of the cytoskeletal protein vinculin was determined in large, fused, multinucleated PC12 cells. In the absence of NGF, focal adhesion sites as seen by interference reflection microscopy were restricted to the cell periphery in a regular distribution. Vinculin assemblies (foci), observed by indirect immunofluorescence microscopy using affinity purified anti-vinculin antibodies, were restricted to the cell periphery at focal adhesion sites. Within 4 hr after NGF treatment of the cells, the distribution of both vinculin and focal adhesion sites began to change. Focal adhesion sites became restricted to discrete protruding portions of the cell periphery. Larger, brighter vinculin foci appeared at the tips of the cell margin extensions, concomitant with the loss of foci at locations between the protrusions. As neurites elongated focal adhesion sites and vinculin foci remained with the tips of the growth cone extensions. Both focal adhesion sites and vinculin foci were rarely seen in the perikarya of cells with elongating neurites, and these were always confined to extended portions of the cell body margin. Occasionally, vinculin foci could be seen at the proximal portion of the neurite, at bending elbows, and at discrete expansions along the length. By immunoprecipitation of vinculin from 32P-labeled cells, vinculin phosphorylation was found to be increased within 1 hr of NGF treatment. The role of vinculin phosphorylation and assembly in the formation and directional elongation of neuritic processes in response to NGF is discussed.     

p120 Catenin is required for growth factor-dependent cell motility and scattering in epithelial cells

Cadherin-mediated cell-cell adhesion is dynamically modulated during epithelial-mesenchymal transition triggered by activation of receptor tyrosine kinases (RTK) in epithelial cells. Several cadherin-binding proteins have been identified that control cell-cell adhesion. However, the mechanisms by which intercellular adhesion and cell motility are coregulated are still unknown. Here, we delineate a hitherto uncharted cooperation between RTKs, RhoA GTPase, and p120 catenin in instructing a motile behavior to epithelial cells. We found that expression of an N-terminus-deleted p120 catenin in a variety of epithelial cell types, including primary keratinocytes, effectively competes for endogenous p120 at cadherin binding sites and abrogates EGF-stimulated cell motility as well as HGF-induced cell scattering. The deleted mutant also inhibits the PI3K-dependent RhoA activation ensuing receptor activation. Conversely, we also show that the ectopic expression of full-length p120 in epithelial cells promotes cytoskeletal changes, stimulates cell motility, and activates RhoA. Both motogenic response to p120 and RhoA activation require coactivation of signaling downstream of RTKs as they are suppressed by ablation of the Ras/PI3K pathway. These studies demonstrate that p120 catenin is a necessary target of RTKs in regulating cell motility and help define a novel pathway leading to RhoA activation, which may contribute to the early steps of metastatic invasion.     

Eosinophilic granule cells in Carassius auratus scale epidermis

Eosinophilic granule cells (EGCs) were characterized in Carassius auratus scale epidermis in situ and in explants. Live EGCs were readily identified by the presence of numerous large cytoplasmic granules observed with DIC microscopy. Histochemical staining with toluidine blue and alcian blue yielded granule metachromasia and pale blue granules, respectively, both consistent with mammalian mast cell staining. However, EGCs also share some features with mammalian basophils as neutral red dye was selectively incorporated into EGC granules. EGCs within scale epidermis were actively motile, displaying average speeds of 16 μm/min and maximum speeds of greater than 40 μm/min and showing morphological plasticity during migration. The predominant motile phenotype was elongate with a well‐developed leading lamella, while a broader body motile morphology was observed to a lesser extent. A trailing, relatively unchanged uropod was associated with every motile EGC and invariably contained one or a few granules. A rounded EGC shape without a leading‐edge or trailing uropod was also observed and was generally associated with static cells. Individual cells readily switched between the three major shapes during motility; static cells could abruptly develop a polarized morphology, and actively motile cells switched between elongate and broad‐bodied shapes or the static, rounded shape.     

Presenilin 1 expression on the cell surface in motile polarized cells

Most cases of early-onset familial Alzheimer’s disease are caused by mutations in the presenilin 1 gene. Nonetheless, the function of presenilin 1 are not yet completely understood. It was shown that endogenous presenilin 1, as well as the adhesion protein CD44, is concentrated on the surface of lamellipodia of polarized T cells (Jurkat cells) after adhesion to a collagen matrix. This phenomenon was not observed for another surface protein of T cells, T cell receptor, which is not involved in cell adhesion processes. In cultures of primary mouse cortical neurons, presenilin 1 was concentrated on the surface of the growth cone and at neurite contact sites. The concentration of presenilin 1 on the surface of structures that determine cell motility and intercellular contacts suggests that presenilin 1 plays an important role in cell adhesion in motile polarized cells.     

PKC-induced stiffening of hyaluronan/CD44 linkage; local force measurements on glioma cells

Interaction of cells with hyaluronan (HA) rich extracellular matrix involves the membrane receptor CD44. HA-CD44 interactions are particularly important in the development of glioma pathogenesis for its implication in tumor cells spreading. Highly motile states rely on the spaciotemporal regulation of HA-CD44 interactions occurring in specific cytoskeletal-supported membrane organization such as microvilli or the leading edge observed in migrating cell. We used AFM-based force measurement to probe the HA-CD44 interaction at localized regions at the surface of living glioma cells expressing high level of the CD44 standard isoform. We show that unstimulated cells interact with HA over their entire surfaces and are highly deformable when force is exerted on individual HA molecules bound to membrane CD44 receptors. Conversely, in PKC-activated cells the probed interactions are concentrated at the leading edge of the cells with reduced membrane deformability. Taken together, our results show that PKC-enhanced motility in glioma cells is associated with a redistribution of CD44 receptors at the leading edges concomitant with a stiffer anchoring of CD44 to the cell surface involving the actin cytoskeleton.     

Inhibition of the calcium-dependent tyrosine kinase (CADTK) blocks monocyte spreading and motility

Freshly isolated peripheral blood monocytes lack focal adhesion kinase (p125(FAK)) but activate a second member of this kinase family, calcium-dependent tyrosine kinase (CADTK; also known as Pyk2/CAKbeta/RAFTK/FAK2), upon adhesion or stimulation with chemokines. To study the role of CADTK in monocyte adherence and motility, we performed immunocytochemical localization that showed CADTK at the leading edge and ruffling lamellipodial structures in freshly isolated, adhered human monocytes. We next introduced CADTK/CAKbeta-related non-kinase (CRNK), the C-terminal noncatalytic domain of CADTK, into monocytes by electroporation and showed that it inhibited CADTK autophosphorylation. Introduction of the fusion protein glutathione S-transferase (GST)-CRNK also reduced (i) cell spreading, as reflected in a reduced cell area 30 min after adhesion, (ii) adhesion-induced phosphotyrosine increases and redistribution into lamellipodia, and (iii) adhesion-induced extracellular signal-regulated protein kinase (ERK) activation. In control experiments, introduction of GST or GST-C3 transferase (an inhibitor of RhoA GTPase activity) by electroporation did not affect these parameters. Monocytes adhered in the presence of autologous serum were highly motile even after introduction of GST (83% motile cells). However, only 26% of monocytes with introduced GST-CRNK were motile. In contrast, GST-CRNK-treated monocytes were fully capable of phagocytosis and adhesion-induced cytokine gene induction, suggesting that CADTK is not involved in these cellular activities and that GST-CRNK introduction does not inhibit global monocyte functions. These results suggest that CADTK is crucial for the in vitro monocyte cytoskeletal reorganization necessary for cell motility and is likely to be required in vivo for recruitment to sites of inflammation.     

Modulators of endothelial cell filopodia

Filopodia are an important feature of actively motile cells, probing the pericellular environment for chemotactic factors and other molecular cues that enable and direct the movement of the cell. They also act as points of attachment to the extracellular matrix for the cell, generating tension that may act to pull the cell forward and/or stabilize the cell as it moves. Endothelial cell motility is a critical aspect of angiogenesis, but only a limited number of molecules have been identified as specific regulators of endothelial cell filopodia. Recent reports, however, provide evidence for the involvement of PECAM-1, an endothelial cell adhesion and signaling molecule, in the formation of endothelial cell filopodia. This commentary will focus on these studies and their suggestion that at least two PECAM-1-regulated pathways are involved in the processes that enable filopodial protrusions by endothelial cells. Developing a more complete understanding of the role of PECAM-1 in mediating various endothelial cell activities, such as the extension of filopodia, will be essential for exploiting the therapeutic potential of targeting PECAM-1.     

Cell shape and motility of oligodendrocytes cultured without neurons

Summary Oligodendrocytes, the myelin-forming cells of the central nervous system (CNS), were cultured from newborn rat brain and optic nerve to study how they differentiate in vitro in the absence of neurons. By use of galactocerebroside (GC) as a reference marker, the development of the cell phenotype was studied with video-enhanced differential interference contrast microscopy, immunofluorescence and electron microscopy. After a few days in culture, oligodendrocytes extend 5 to 10 main processes that are very rich in microtubules, but they did not stain with a monoclonal antibody reacting with all known classes of intermediate filaments. The number of processes can vary with the substrate on which the cells are grown; fewer processes form on laminin than on polylysine coated glass. Oligodendrocytes, in a fashion similar to that of neurons appear to keep their body immobile while the long processes grow. However, while neurons display motile activities mostly at the end of the cell processes called growth cones, the oligodendrocytes display motile, actin rich filopodia and lamellipodia along the entire length of all processes. The outgrowth of motile processes from oligodendrocytes sometimes occurs preferentially towards neighboring astrocytes. Oligodendrocyte processes display intense bidirectional movement of cytoplasmic organelles. Movement of surface components also occurs since GC molecules cross-linked by antibodies move from the processes towards the cell body. Thus, oligodendrocytes cultured without neurons develop on schedule a complex phenotype similar to their in vivo counterpart. In addition, their processes are capable of specific motile activities which may function in vivo to find the target axon and to transport myelin membrane components at the site of myelin assembly.Abbreviations (CNS) Central nervous system - (DIC) Differential interference contrast - (GC) Galactocerebroside - (GFA) protein Glial fibrillary acidic - (NSE) Neuron-specific enolase