Myosin IIA and formin dependent mechanosensitivity of filopodia adhesion.

Filopodia, dynamic membrane protrusions driven by polymerization of an actin filament core, can adhere to the extracellular matrix and experience both external and cell-generated pulling forces. The role of such forces in filopodia adhesion is however insufficiently understood. Here, we study filopodia induced by overexpression of myosin X, typical for cancer cells. The lifetime of such filopodia positively correlates with the presence of myosin IIA filaments at the filopodia bases. Application of pulling forces to the filopodia tips through attached fibronectin-coated laser-trapped beads results in sustained growth of the filopodia. Pharmacological inhibition or knockdown of myosin IIA abolishes the filopodia adhesion to the beads. Formin inhibitor SMIFH2, which causes detachment of actin filaments from formin molecules, produces similar effect. Thus, centripetal force generated by myosin IIA filaments at the base of filopodium and transmitted to the tip through actin core in a formin-dependent fashion is required for filopodia adhesion.

A new dimension in retrograde flow: centripetal movement of engulfed particles.

Centripetal motion of surface-adherent particles is a classic experimental system for studying surface dynamics on a eukaryotic cell. To investigate bead migration over the entire cell surface, we have developed an experimental assay using multinuclear giant fibroblasts, which provide expanded length scales and an unambiguous frame of reference. Beads coated by adhesion ligands concanavalin A or fibronectin are placed in specific locations on the cell using optical tweezers, and their subsequent motion is tracked over time. The adhesion, as well as velocity and directionality of their movement, expose distinct regions of the cytoplasm and membrane. Beads placed on the peripheral lamella initiate centripetal motion, whereas beads placed on the central part of the cell attach to a stationary cortex and do not move. Careful examination by complementary three-dimensional methods shows that the motion of a bead placed on the cell periphery takes place after engulfment into the cytoplasm, whereas stationary beads, placed near the cell center, are not engulfed. These results demonstrate that centripetal motion of adhering particles may occur inside as well as outside the cell. Inhibition of actomyosin activity is used to explore requirements for engulfment and aspects of the bead movement. Centripetal movement of adherent particles seems to depend on mechanisms distinct from those driving overall cell contractility.

Focal contacts as mechanosensors: externally applied local mechanical force induces growth of focal contacts by an mDia1-dependent and ROCK-independent mechanism.

The transition of cell-matrix adhesions from the initial punctate focal complexes into the mature elongated form, known as focal contacts, requires GTPase Rho activity. In particular, activation of myosin II-driven contractility by a Rho target known as Rho-associated kinase (ROCK) was shown to be essential for focal contact formation. To dissect the mechanism of Rho-dependent induction of focal contacts and to elucidate the role of cell contractility, we applied mechanical force to vinculin-containing dot-like adhesions at the cell edge using a micropipette. Local centripetal pulling led to local assembly and elongation of these structures and to their development into streak-like focal contacts, as revealed by the dynamics of green fluorescent protein-tagged vinculin or paxillin and interference reflection microscopy. Inhibition of Rho activity by C3 transferase suppressed this force-induced focal contact formation. However, constitutively active mutants of another Rho target, the formin homology protein mDia1 (Watanabe, N., T. Kato, A. Fujita, T. Ishizaki, and S. Narumiya. 1999. Nat. Cell Biol. 1:136-143), were sufficient to restore force-induced focal contact formation in C3 transferase-treated cells. Force-induced formation of the focal contacts still occurred in cells subjected to myosin II and ROCK inhibition. Thus, as long as mDia1 is active, external tension force bypasses the requirement for ROCK-mediated myosin II contractility in the induction of focal contacts. Our experiments show that integrin-containing focal complexes behave as individual mechanosensors exhibiting directional assembly in response to local force.

p120 catenin affects cell motility via modulation of activity of Rho-family GTPases: a link between cell-cell contact formation and regulation of cell locomotion.

The molecular basis for contact inhibition of cell locomotion is still largely unknown. Cadherins, the major receptors mediating cell-cell adhesion, associate in the cytoplasm with armadillo family proteins, including beta- and gamma-catenin and p120 catenin (p120ctn). E-cadherin-mediated contact formation was shown to inhibit cellular motility. We examine whether p120ctn may have a role in this regulation. We show here that overexpression of p120ctn in fibroblasts and epithelial cells induces pronounced changes in cell shape, motility and adhesion to the extracellular matrix. p120ctn-transfected cells display increased filopodial/lamellipodial activity, decreased contractility and focal adhesion formation, and augmented migratory ability. These effects of p120ctn are mediated by small GTPases of the Rho family. Direct assessment of the activity of these GTPases in cells expressing a 5-fold higher level of p120ctn as compared to non-transfected control cells revealed significant augmentation of Cdc42 and Rac activity. Moreover, co-transfection of p120ctn with dominant-negative Cdc42 and Rac, or constitutively active Rho suppressed morphological effects of p120ctn. Confocal immunofluorescence visualization of the distribution of endogenous p120ctn in dense cultures showed that formation of cadherin-mediated cell-cell contacts is accompanied by sequestering of p120ctn to the junction regions. In sparse cultures p120ctn is distributed over the cytoplasm. Co-transfection with an excess of E-cadherin leads to sequestration of exogenous p120ctn to cell-cell junctions or to small cadherin-containing vesicles, and abolishes p120ctn effects on cell morphology. Thus, p120ctn may couple the formation and disruption of cadherin-mediated contacts with regulation of cell motility by triggering pathway(s) affecting Rho family GTPases.

Cadherin-mediated regulation of microtubule dynamics.

Epithelial polarization and neuronal outgrowth require the assembly of microtubule arrays that are not associated with centrosomes. As these processes generally involve contact interactions mediated by cadherins, we investigated the potential role of cadherin signalling in the stabilization of non-centrosomal microtubules. Here we show that expression of cadherins in centrosome-free cytoplasts increases levels of microtubule polymer and changes the behaviour of microtubules from treadmilling to dynamic instability. This effect is not a result of cadherin expression per se but depends on the formation of cell-cell contacts. The effect of cell-cell contacts is mimicked by application of beads coated with stimulatory anti-cadherin antibody and is suppressed by overexpression of the cytoplasmic cadherin tail. We therefore propose that cadherins initiate a signalling pathway that alters microtubule organization by stabilizing microtubule ends.

Molecular requirements for the effect of neuregulin on cell spreading, motility and colony organization.

Neuregulin can trigger morphogenetic signals in cells both in vivo and in culture through the activation of receptors from the ErbB family. We have ectopically expressed various ErbB-receptors in 32D myeloid cells lacking endogenous ErbB-proteins, and in CHO cells, which express only ErbB-2. We show here that activation of ErbB-3/ErbB-2 heterodimeric receptors triggers PI3-kinase-dependent lamellipodia formation and spreading, while individual ErbB-receptor homodimers as well as ErbB-3/ErbB-1 heterodimers are much less effective. CHO cells expressing ErB-3/ErbB-2 together with N-cadherin, an adhesion receptor, form epithelioid colonies. Neuregulin activates cell motility leading to transition of these colonies into ring-shaped multicellular arrays, similar to those induced by neuregulin in epithelial cells of different types (Chausovsky et al., 1998). This process requires both PI3-kinase and MAP kinase kinase activity and depends on coordinated changes in the actin- and microtubule-based cytoskeleton. Transactivation of ErbB-2 is not sufficient for the activation of cell motility and ring formation, and the C-terminal domain of ErbB-3 bearing the docking sites for the p85 subunit of PI3-kinase is essential for these morphogenetic effects. Thus, ErbB-3 in conjunction with ErbB-2 mediates, via its C-terminal domain, cytoskeletal and adhesion alterations which activate cell spreading and motility, leading to the formation of complex structures such as multicellular rings. Oncogene (2000) 19, 878 - 888.

Disruption of microtubules in living cells by tyrphostin AG-1714.

Tyrphostin AG-1714 and several related molecules with the general structure of nitro-benzene malononitrile (BMN) disrupt microtubules in a large variety of cultured cells. This process can be inhibited by the stabilization of microtubules with taxol or by pretreatment of the cells with pervanadate, which inhibits tyrosine phosphatases and increases the overall levels of phosphotyrosine in cells. Unlike other microtubule-disrupting drugs such as nocodazole or colchicine, tyrphostin AG-1714 does not interfere with microtubule polymerization or stability in vitro, suggesting that the effect of this tyrphostin on microtubules is indirect. These results imply an involvement of protein tyrosine phosphorylation in the regulation of overall microtubule dynamics. Tyrphostins of AG-1714 type could thus be powerful tools for the identification of such microtubule regulatory pathways.

Autoregulation of actin synthesis requires the 3'-UTR of actin mRNA and protects cells from actin overproduction.

Monomeric (G) actin was shown to be involved in inhibiting its own synthesis by an autoregulatory mechanism that includes enhanced degradation of the actin mRNA [Bershadsky et al., 1995; Lyubimova et al., 1997]. We show that the 3'-untranslated region (3'-UTR) of beta-actin mRNA, but not its 5'-untranslated region, is important for this regulation. The level of full-length beta-actin mRNA in cells was reduced when actin filaments were depolymerized by treatment with latrunculin A and elevated when actin polymerization was induced by jasplakinolide. By contrast, the level of actin mRNA lacking the 3'-UTR remained unchanged when these drugs modulated the dynamics of actin assembly in the cell. Moreover, the transfection of cells with a construct encoding the autoregulation-deficient form of beta-actin mRNA led to very high levels of actin expression compared with transfection with the control actin construct and was accompanied by characteristic changes in cell morphology and the structure of the actin cytoskeleton. These results suggest that the autoregulatory mechanism working via the 3'-UTR of actin mRNA is involved in controlling the maintenance of a defined pool of actin monomers that could be necessary for the proper organization of the microfilament system and the cytoskeleton-mediated signaling.

Caldesmon inhibits nonmuscle cell contractility and interferes with the formation of focal adhesions.

Caldesmon is known to inhibit the ATPase activity of actomyosin in a Ca(2+)-calmodulin-regulated manner. Although a nonmuscle isoform of caldesmon is widely expressed, its functional role has not yet been elucidated. We studied the effects of nonmuscle caldesmon on cellular contractility, actin cytoskeletal organization, and the formation of focal adhesions in fibroblasts. Transient transfection of nonmuscle caldesmon prevents myosin II-dependent cell contractility and induces a decrease in the number and size of tyrosine-phosphorylated focal adhesions. Expression of caldesmon interferes with Rho A-V14-mediated formation of focal adhesions and stress fibers as well as with formation of focal adhesions induced by microtubule disruption. This inhibitory effect depends on the actin- and myosin-binding regions of caldesmon, because a truncated variant lacking both of these regions is inactive. The effects of caldesmon are blocked by the ionophore A23187, thapsigargin, and membrane depolarization, presumably because of the ability of Ca(2+)-calmodulin or Ca(2+)-S100 proteins to antagonize the inhibitory function of caldesmon on actomyosin contraction. These results indicate a role for nonmuscle caldesmon in the physiological regulation of actomyosin contractility and adhesion-dependent signaling and further demonstrate the involvement of contractility in focal adhesion formation.

Microtubule involvement in regulating cell contractility and adhesion-dependent signalling: a possible mechanism for polarization of cell motility.

The dynamic shape of an isolated cell results from an interplay between protrusion, adhesion and contraction activities. These are most closely associated with the actin cytoskeleton. In many cell types, microtubules have been shown to be involved in the development of morphological polarity required for directional migration. This suggests a role for the microtubule system in regulating both the actin cytoskeleton and the formation of cell-substrate adhesions. The most prominent role of microtubules in the cell is in transport of vesicles and organelles. Disruption of the microtubules, on the other hand, leads to a significant increase in actomyosin-driven contractility. This suggests the involvement of microtubules in the control of forces produced by the cell against the points at which it contacts the substrate or extracellular matrix. We show that microtubule disruption also activates an adhesion-dependent signal transduction cascade and promotes the formation of focal adhesions and associated actin microfilament bundles. Using overexpression of caldesmon, a regulatory protein which inhibits the interaction between actin and myosin, we show that these effects of microtubule disruption depend on the activation of contractility. Formation of focal adhesions induced by the small GTPase Rho is also blocked by the caldesmon inhibition of contractility. We infer that there is a step in the adhesion-dependent signalling pathway that requires mechanical tension applied to cell-substrate contacts. Although the experimental data are based on complete microtubule disruption, we suggest that a similar effect occurs locally following depolymerization of individual microtubules. We speculate that the interplay among microtubule dynamics, actomyosin contractility and adhesion-dependent signalling can produce a mechanism for the determination of cell polarity and direction of migration. In essence, microtubule depolymerization would create a local increase in contractile force, testing and promoting the maturation of nearby cell-substrate adhesions.

Latrunculin-A increases outflow facility in the monkey.

PURPOSE: To determine the effect of Latrunculin (LAT)-A, a macrolide that binds to G-actin, which leads to the disassembly of actin filaments, on shape, junctions, and the cytoskeleton of cultured bovine aortic endothelial cells (BAECs) and on outflow facility in living monkeys. METHODS: Latrunculin-A dose-time-response relationships in BAECs were determined by immunofluorescence and phase contrast light microscopy, facility by two-level constant pressure anterior chamber perfusion. RESULTS: In BAECs, LAT-A caused dose- and incubation time- dependent destruction of actin bundles, cell separation, and cell loss. Cell-cell adhesions were more sensitive than focal contacts. Recovery was also dose- and time-dependent. In monkeys, exchange intracameral infusion and topical application of LAT-A induced dose- and time-dependent several-fold facility increases. The facility increase was completely reversed within several hours after drug removal. However, for at least 24 hours after a single topical LAT-A dose, perfusion with drug-free solution caused an accelerated increase in facility beyond that attributed to normal resistance washout. CONCLUSIONS: Pharmacological disorganization of the actin cytoskeleton in the trabecular meshwork by specific actin inhibitors like LAT-A may be a useful antiglaucoma strategy.

Morphogenetic effects of neuregulin (neu differentiation factor) in cultured epithelial cells.

Neuregulin, or neu differentiation factor, induces cell proliferation or differentiation through interaction with members of the ErbB family of receptor tyrosine kinases. We report that neuregulin can also induce profound morphogenic responses in cultured epithelial cells of different origins. These effects include scattering of small epithelial islands and rearrangement of larger cell islands into ordered ring-shaped arrays with internal lumens. The ring-forming cells are interconnected by cadherin- and beta-catenin-containing adherens junctions. In confluent cultures, neuregulin treatment induces formation of circular lumenlike gaps in the monolayer. Both cell scattering and ring formation are accompanied by a marked increase in cell motility that is independent of hepatocyte growth factor/scatter factor and its receptor (c-Met). Affinity-labeling experiments implied that a combination of ErbB-2 with ErbB-3 mediates the morphogenic signal of neuregulin in gastric cells. Indeed, a similar morphogenic effect could be reconstituted in nonresponsive cells by coexpression of ErbB-2 and -3. We conclude that a heterodimer between the kinase-defective neuregulin receptor, ErbB-3, and the coreceptor, ErbB-2, mediates the morphogenetic action of neuregulin.

Autoregulation of actin synthesis responds to monomeric actin levels.

Regulation of the assembly and expression of actin is of major importance in diverse cellular functions such as motility and adhesion and in defining cellular and tissue architecture. These biological processes are controlled by changing the balance between polymerized (F) and soluble (G) actin. Previous studies have indicated the existence of an autoregulatory pathway that links the state of assembly and expression of actin, resulting in the reduction of actin synthesis after actin filaments are depolymerized. We have employed the marine toxins swinholide A and latrunculin A, both disrupting the organization of the actin-cytoskeleton, to determine whether this autoregulatory response is activated by a decrease in the level of polymerized actin or by an increase in monomeric actin concentrations in the cell. We showed that in cells treated with swinholide A the level of filamentous actin is decreased, and using a reversible cross-linking reagent, we found that actin dimers are formed. Latrunculin A also disassembled actin filaments, but produced monomeric actin, followed by a reduction in actin and vinculin expression, while swinholide A treatment elevated the synthesis of these proteins. In cells treated with both latrunculin A and swinholide A, dimeric actin was formed, and actin and vinculin synthesis were higher than in control cells. These results suggest that the substrate that confers an autoregulated reduction in actin expression is monomeric actin, and when its level is decreased by dimeric actin formation, actin synthesis is increased.

The role of sphingolipids in the maintenance of fibroblast morphology. The inhibition of protrusional activity, cell spreading, and cytokinesis induced by fumonisin B1 can be reversed by ganglioside GM3.

Previous studies demonstrated that inhibition of sphingolipid synthesis by the mycotoxin fumonisin B1 (FB1) disrupts axonal growth in cultured hippocampal neurons (Harel, R., and Futerman, A. H. (1993) J. Biol. Chem. 268, 14476-14481) by affecting the formation or stabilization of axonal branches (Schwarz, A., Rapaport, E., Hirschberg, K., and Futerman, A.H. (1995) J. Biol. Chem. 270, 10990-10998). We now demonstrate that long term incubation with FB1 affects fibroblast morphology and proliferation. Incubation of Swiss 3T3 cells with FB1 resulted in a decrease in synthesis of ganglioside GM3, the major glycosphingolipid in 3T3 fibroblasts and of sphingomyelin. The projected cell area of FB1-treated cells was approximately 45% less than control cells. FB1 had no affect on the organization of microtubules or intermediate filaments, but fewer actin-rich stress fibers were observed, and there was a loss of actin-rich lamellipodia at the leading edge. Three other processes involving the actin cytoskeleton, cytokinesis, microvilli formation, and the formation of long processes induced by protein kinase inhibitors, were all disrupted by FB1. All the effects of FB1 on cell morphology could be reversed by addition of ganglioside GM3 even in the presence of FB1, whereas the bioactive intermediates, sphinganine, sphingosine, and ceramide, were without effect. Finally, FB1 blocked cell proliferation and DNA synthesis in a reversible manner, although ganglioside GM3 could not reverse the effects of FB1 on cell proliferation. Together, these data suggest that ongoing sphingolipid synthesis is required for the assembly of both new membrane and of the underlying cytoskeleton.

The state of actin assembly regulates actin and vinculin expression by a feedback loop.

Actin filaments are major determinants of cell shape, motility and adhesion, which control important biological processes including embryonic development and wound healing. These processes are associated with changes in actin assembly, which is regulated by controlling the balance between polymerized and non-polymerized actin. To maintain a significant pool of non-polymerized actin, mechanism(s) linking actin synthesis to its state of polymerization were proposed. We have studied this relationship between actin synthesis and organization by modulating actin assembly using different drugs. Unassembled actin was increased in 3T3 cells using either the Clostridium botulinum C2 toxin, which ADP-ribosylates actin, or by latrunculin A, a Red Sea sponge product, which binds monomeric actin. The synthesis of actin was dramatically reduced in these cells owing to a concomitant decrease in actin RNA level. Similar results were obtained with HeLa cells grown in both monolayer and in suspension, suggesting that cell shape changes associated with drug treatment are not the primary cause for the effect on actin synthesis. In contrast, the scrape-loading of 3T3 cells with phalloidin, a stabilizer of polymerized actin that increased the level of assembled actin, resulted in elevated actin synthesis and RNA content. The expression of vinculin, a major component of adhesion plaques and cell-cell junctions, which is involved in actin-membrane associations, was altered in parallel with that of actin in cells treated with these drugs. The decrease in actin RNA resulted from destabilization of actin mRNA in cells where unassembled actin level was elevated. This is suggested by the unchanged transcription of actin in isolated nuclei from drug-treated cells, and by demonstrating that actin mRNA was degraded faster in cells after C2 toxin treatment than in control cells. This feedback control mechanism is mainly confined to the cytoplasm, as it remained active in enucleated cells. The results suggest the existence of an autoregulatory pathway for the expression of actin and other microfilament-associated proteins which is linked to the state of actin polymerization in the cell.

Swinholide A is a microfilament disrupting marine toxin that stabilizes actin dimers and severs actin filaments.

Swinholide A, isolated from the marien sponge Theonella swinhoei, is a 44-carbon ring dimeric dilactone macrolide with a 2-fold axis of symmetry. Recent studies have elucidated its unusual structure and shown that it has potent cytotoxic activity. We now report that swinholide A disrupts the actin cytoskeleton of cells grown in culture, sequesters actin dimers in vitro in both polymerizing and non-polymerizing buffers with a binding stoichiometry of one swinholide A molecule per actin dimer, and rapidly severs F-actin in vitro with high cooperativity. These unique properties are sufficient to explain the cytotoxicity of swinholide A. They also suggest that swinholide A might be a model for studies of the mechanism of action of F-actin severing proteins and be therapeutically useful in conditions where filamentous actin contributes to pathologically high viscosities.

Transverse pattern of microfilament bundles induced in epitheliocytes by cylindrical substrata.

Cylindrical culture substrata are known to induced longitudinal orientation of polarized fibroblasts and corresponding alignment of actin microfilament bundles in these cells. We studied microfilament bundle distribution in two cell types, fibroblasts and epitheliocytes, spread on two kinds of anisotropic substrata, quartz glass cylinders with a diameter 32 microns and narrow (25-40 microns wide) flat glass adhesive strips with non-adhesive borders. Rat embryo and human diploid fibroblasts, as expected, formed predominantly longitudinally aligned bundles on both substrata. In contrast, transverse bundles on cylinders and randomly oriented bundles on flat strips were formed in IAR-2 and MDCK epithelial cells. We interpret these data as showing that the epitheliocyte attempts to override the guiding influence of anisotropic substrata. The microfilament bundle pattern on cylinders depends on the integrity of the microtubules. Colcemid-induced microtubule depolymerization caused formation of longitudinal as well as transverse bundles both in fibroblasts and epitheliocytes, thus diminishing the differences in microfilament bundle patterns in two cell types. These results show that microtubules control the cell-type-specific distribution of microfilament bundles both in polarized fibroblasts and in discoid epitheliocytes. However, the results of this control are opposite: microtubules enhance cell polarization in fibroblasts, but prevent it in epithelial cells.

Molecular interactions in the submembrane plaque of cell-cell and cell-matrix adhesions.

Adhesion of cells to their neighbors or to the extracellular matrix has multiple effects on cell shape, dynamics and fate. The most obvious and direct one is the assembly of single cells into ordered multicellular tissues and organs. This process requires specific transmembrane adhesion molecules which mediate the binding to the external surface, cytoskeletal filaments which attach to the cytoplasmic faces of the adhesion site, and a submembrane plaque which interconnects the two. The co-assembly of these junctional domains is essential for the formation of stable cell adhesions with the proper mechanical properties. In addition, adhesive interactions have prominent, global consequences on cell behavior and fate, affecting such processes as differentiation, growth and survival. To gain insight into the molecular basis for both the local and global effects of adhesive interactions, we have chosen to focus on one specific junctional domain, the submembrane plaque of microfilament-bound adhesions, namely cell-cell and cell-matrix adherens junctions. Based on both biochemical and morphological evidence we would like to propose that the junctional plaque plays a key role in mediating and regulating transmembrane junctional interactions and adhesion-dependent signaling. It offers multiple modes of linkage between the cytoskeleton and the membrane, and its assembly can be controlled at either the biosynthetic or posttranslational levels. Furthermore, recent data demonstrate that the submembrane plaque is involved in the transduction of transmembrane signals. We will show that this structure is the residence of an array of signaling enzymes (mostly kinases), that its structure and composition may be affected by activation of various signaling systems, and that adhesion itself may activate specific signal transduction pathways.

Disruption of the Golgi apparatus by brefeldin A blocks cell polarization and inhibits directed cell migration.

The role of the Golgi apparatus in the motile activity of fibroblasts was examined with brefeldin A (BFA), which disrupts the Golgi apparatus in a variety of cells. Upon incubation with BFA, Swiss mouse 3T3 fibroblasts lost their typical polarized morphology, in which the leading edge is characterized by intensive lamellipodia formation. BFA affected cell asymmetry as demonstrated by a decrease in the morphometric indices, dispersion, and elongation. After BFA treatment, cells showed little protrusional activity and did not form a dense actin network at the leading edge, and consequently the rate of cell migration into an experimental wound was significantly reduced. In addition, BFA prevented an increase in pseudopodial activity and prevented the formation of long processes induced by phorbol 12-myristate 13-acetate. The effects of BFA on cell shape and protrusional activity were quantitatively similar to those observed with the microtubule-disrupting agent nocodazole, although BFA had no effect on microtubule integrity. These results suggest that the integrity of both the Golgi apparatus and microtubules is necessary for the generation and maintenance of fibroblast asymmetry, which is a prerequisite for directed cell migration.

Cytoskeletal involvement in the modulation of cell-cell junctions by the protein kinase inhibitor H-7.

The protein kinase inhibitor H-7 has been shown to block junction dissociation induced by low extracellular calcium in Madin Darby canine kidney epithelial cells (S. Citi, J. Cell Biol. (1992) 117, 169-178). To understand the basis of this effect, we have examined how H-7 affects the organization of junctions and the actin cytoskeleton in different types of epithelial cells in culture. Immunofluorescence microscopy showed that H-7 confers Ca2+ independence on cultured epithelial lens cells, which lack tight junctions and desmosomes but have microfilament-associated adherens junctions. In these cells, H-7 did not protect N-cadherin from trypsin digestion at low extracellular calcium, suggesting that H-7 does not stabilize the 'active' cadherin conformation. In cultured Madin Darby canine kidney cells, H-7 partially prevented the fall in transepithelial resistance induced by cytochalasin D, either alone or in conjunction with calcium chelators. Double-immunofluorescence microscopy showed that H-7 inhibits both the fragmentation of labeling for the tight junction protein cingulin and the condensation of actin into cytoplasmic foci induced by cytochalasin D. Taken together, these observations indicate that H-7 inhibits junction dissociation by affecting the contractility of the adherens junction-associated microfilaments following treatment with calcium chelators or cytochalasin D.