Dynamics of the cytoskeleton in Amoeba proteus

Fluorescein-labeled muscle actin was microinjected into Amoeba proteus and followed during intracellular redistribution by means of the image-intensification technique. The fully polymerization-competent protein becomes part of the endogenous actomyosin system undergoing dynamic changes over time periods of several hours. Single-frame analysis of long-term sequences enabled the direct demonstration of both the contractile activities and morphological transformations of microfilaments in normally locomoting, immobilized and phagocytozing specimens. In normally locomoting cells the filament layer undergoes continuous changes in spatial distribution depending on the actual pattern of cytoplasmic streaming and cell shape. The highest degree of differentiation is always maintained in the intermediate region between the front and the uroid, thus indicating this segment of the cortex to be the most important site in generating motive force for pseudopodium formation and ameboid movement. In immobilized cells contracted by the application of ruthenium red or relaxed by different anesthetics, the filament layer forms a continuous thick sheath beneath the cell surface or becomes completely disintegrated. In phagocytozing cells the local polymerization of actin at the tip of pseudopodia forming the food-cup and around the nascent phagosome points to a significant participation of the actomyosin system in the process of capturing and constricting prey organisms. Although our results provide clear evidence for the overall importance of motive force generation according to the hydraulic pressure theory, some motile phenomena exist in Amoeba proteus that cannot exclusively be explained by this mechanism.     

Dynamics of the cytoskeleton in Amoeba proteus. III. Influence of microinjected antibodies on the organization and function of the microfilament system

Affinity-purified antibodies against actin, myosin, alpha-actinin and vinculin cross-reacted with corresponding proteins from Amoeba proteus in immunoblotting experiments. Antibody staining of cells fixed during locomotion revealed different distribution patterns with a local concentration of anti-actin in the intermediate and of anti-myosin in the uroid region. Anti-alpha-actinin labeled a thin layer at the internal face of the plasma membrane, whereas anti-vinculin was distinctly concentrated at the base of advancing pseudopodia. Microinjection of different control solutions or antibodies against actin, myosin and alpha-actinin neither influenced the normal morphology and motile activity of amoebae nor changed the cellular distribution pattern of complementary antigens. However, antibodies against vinculin disorganized controlled locomotion and altered the spatial morphology of the microfilament system as well as the localization of the vinculin antigen thus pointing to a function of this protein in adhesion and locomotion of A. proteus. The results of the present paper show similarities to observations on mammalian tissue culture cells.     

Spatial organization and fine structure of the cortical filament layer in normal locomoting Amoeba proteus

Summary The fine structural organization of a cortical filament layer in normal locomoting Amoeba proteus was demonstrated using improved fixation and embedding techniques. Best results were obtained after application of PIPES-buffered glutaraldehyde in connection with substances known to prevent the depolymerization of F-actin, followed by careful dehydration and freeze-substitution.The filament layer is continuous along the entire surface; it exhibits a varying thickness depending on the cell polarity, measuring several nm in advancing regions and 0.5–1 m in retracting ones. Two different types of filaments are responsible for the construction of the layer: randomly distributed thin (actin) filaments forming an unordered meshwork beneath the plasma membrane, and thick (myosin) filaments mostly restricted to the uroid region in close association with F-actin.The cortical filament layer generates the motive force for amoeboid movement by contraction at posterior cell regions and induces a pressure flow that continues between the uroid with a high hydrostatic pressure and advancing pseudopodia with a low one. The local destabilization of the cell surface as a precondition for the formation of pseudopodia is enabled by the detachment of the cortical filament layer from the plasma membrane. This results in morphological changes by the active separation of peripheral hyaloplasmic and central granuloplasmic regions.     

Suction pressure can induce uncoupling of the plasma membrane from cortical actin

We tested the hypothesis that a pressure difference can cause blebbing associated with uncoupling of the plasma membrane from the cortical actin, a phenomenon found earlier in locomoting blebbing Walker carcinosarcoma cells. Untreated, initially spherical Walker carcinosarcoma cells were exposed to suction pressure by partial aspiration into micropipettes. The suction pressure required to induce blebbing was in the range of 0.9-3 cm H2O, i.e., somewhat lower than the increase in intracellular pressure measured before formation of protrusions in Amoeba proteus (Yanai et al., Cell Motil. Cytoskeleton 33, 22-29, 1996). The response was temperature-dependent, blebbing occurring more frequently at 37 degrees C than at room temperature. Blebbing was associated with formation of cytoplasmic actin layers, restriction rings and/or of gaps in the plasma membrane-associated cortical actin. The results support the view that blebbing associated with uncoupling of cortical actin and plasma membrane as observed in locomoting cells can be caused by a pressure gradient.     

Actin dynamics in Amoeba proteus motility

Summary. We studied the distribution of the endogenous Arp2/3 complex in Amoeba proteus and visualised the ratio of filamentous (F-actin) to total actin in living cells. The presented results show that in the highly motile Amoeba proteus, Arp2/3 complex-dependent actin polymerisation is involved in the formation of the branching network of the contractile layer, adhesive structures, and perinuclear cytoskeleton. The aggregation of the Arp2/3 complex in the cortical network, with the exception of the uroid and advancing fronts, and the spatial orientation of microfilaments at the leading edge suggest that actin polymerisation in this area is not sufficient to provide the driving force for membrane displacement. The examined proteins were enriched in the pinocytotic pseudopodia and the perinuclear cytoskeleton in pinocytotic amoebae. In migrating amoebae, the course of changes in F-actin concentration corresponded with the distribution of tension in the cell cortex. The maximum level of F-actin in migrating amoebae was observed in the middle-posterior region and in the front of retracting pseudopodia. Arp2/3 complex-dependent actin polymerisation did not seem to influence F-actin concentration. The strongly condensed state of the microfilament system could be attributed to strong isometric contraction of the cortical layer accompanied by its retraction from distal cell regions. Isotonic contraction was limited to the uroid. Correspondence and reprints: Department of Molecular and Cellular Neurobiology, Nencki Institute of Experimental Biology, Polish Academy of Sciences, ulica Pasteura 3, 02-093 Warszawa, Poland.     

Localised depletion of polymerised actin at the front of Walker carcinosarcoma cells increases the speed of locomotion

Spontaneously migrating Walker carcinosarcoma cells usually form lamellipodia at the front. Combined treatment with 10(-5)M colchicine and 10(-7)M latrunculin A produces large defects in the cortical F-actin layer at the leading front and suppresses lamellipodia. However, the cortical actin layer at the rear is intact and shows myosin IIA accumulation. These cells, showing no or little detectable cortical F-actin at the front and no morphologically recognisable protrusions, migrate faster than control cells with lamellipodia and an intact cortical actin layer. This documents that the cortical actin layer or actin-powered force generation at the front is redundant for locomotion. Colchicine and latrunculin A have synergistic effects in compromising the cortical layer at the front and in increasing the speed of locomotion, but antagonistic effects on the relative amount of F-actin per cell. Colchicine but not latrunculin A, can increase the proportion of polarised and locomoting cells under appropriate conditions. Locomotion and polarity of cells treated with latrunculin A and colchicine is inhibited at latrunculin A concentrations >10(-7)M, by the myosin inhibitor BDM or the ROCK inhibitor Y-27632. Colchicine and Y-27632 have antagonistic effects on polarity and the speed of locomoting cells. The data show that locomotion of metazoan cells, which normally form lamellipodia, can be driven by actomyosin contraction behind the front (cell body, uropod). They are best compatible with a cortical contraction/frontal expansion model, but they are not compatible with models implying that actin polymerisation or actomyosin contraction at the front drive locomotion of the cells studied.     

Characterization of Amoeba proteus myosin VI immunoanalog

Amoeba proteus, the highly motile free-living unicellular organism, has been widely used as a model to study cell motility. However, molecular mechanisms underlying its unique locomotion and intracellular actin-based-only trafficking remain poorly understood. A search for myosin motors responsible for vesicular transport in these giant cells resulted in detection of 130-kDa protein interacting with several polyclonal antibodies against different tail regions of human and chicken myosin VI. This protein was binding to actin in the ATP-dependent manner, and immunoprecipitated with anti-myosin VI antibodies. In order to characterize its possible functions in vivo, its cellular distribution and colocalization with actin filaments and dynamin II during migration and pinocytosis were examined. In migrating amoebae, myosin VI immunoanalog localized to vesicular structures, particularly within the perinuclear and sub-plasma membrane areas, and colocalized with dynamin II immunoanalog and actin filaments. The colocalization was even more evident in pinocytotic cells as proteins concentrated within pinocytotic pseudopodia. Moreover, dynamin II and myosin VI immunoanalogs cosedimented with actin filaments, and were found on the same isolated vesicles. Blocking endogenous myosin VI immunoanalog with anti-myosin VI antibodies inhibited the rate of pseudopodia protrusion (about 19% decrease) and uroidal retraction (about 28% decrease) but did not affect cell morphology and the manner of cell migration. Treatment with anti-human dynamin II antibodies led to changes in directionality of amebae migration and affected the rate of only uroidal translocation (about 30% inhibition). These results indicate that myosin VI immunoanalog is expressed in protist Amoeba proteus and may be involved in vesicle translocation and cell locomotion.     

Visualization and measurement of calcium transients in Amoeba proteus by fura-2 fluorescence

A fura-2 microspectrofluorimeter was used to visualize and measure intracellular calcium transients in normal locomoting and experimentally treated Amoeba proteus. The results show that subcellular heterogeneities of cytosolic free calcium, [Ca2+]i, correlate in time and distribution with characteristic patterns of protoplasmic streaming and ameboid movement. In detail, calcium ions have a dual effect by regulating both the contractile activities of the actomyosin cortex and the rheological properties of the cytoplasmic matrix. A high resting [Ca2+]i of 1.5 to 2.0 x 10(-7) M in the uroid region or in retracting pseudopodia is associated with the transformation of rigid ectoplasmic gel into fluid endoplasmic sol, and a low [Ca2+]i of 10(-9) to 10(-8) M in the front region or in extending pseudopodia with the re-transformation of endoplasmic sol into ectoplasmic gel. Locally increased peripheral [Ca2+]i accumulations higher than 10(-7) M are also observed at places where the actomyosin cortex is known to generate motive force by contraction, i.e., in the intermediate region of orthotactic amebas or in large pseudopodia of polytactic cells. External application of 30 mM KCl abolishes the intracellular Ca2+ gradient such that [Ca2+]i attains a uniform distribution and a maximum concentration of 2 x 10(-7) M; as a consequence, cells can show a transient loss of their locomotor activity and polarity by undergoing spherulation and total contraction. On the other hand, high external Ca2+ concentrations in the range of 100 mM stabilize the bipolar cellular organization, enhance the movement velocity and induce the propagation of Ca2+ waves repeatedly running from the uroid to the front region. The significance of external ions for signal transmission and the control of dynamic activities as well as the origin and fate of calcium participating in the observed transients are discussed.     

Effects of the actin-binding protein DNAase I on cytoplasmic streaming and ultrastructure of Amoeba proteus

Microinjection of DNAase I, which is known to form a specific complex with G-actin, induces characteristic changes in cytoplasmic streaming, locomotion and morphology of the contractile apparatus of A. proteus. Light microscopical studies show pronounced streaming originating from the uroid and/or the retracting pseudopods, which ceases 10--15 min after injection of DNAase I, at a time when ultrasctructural studies show that the actin filament system is very much reduced. These results suggest that a controlled reversible equilibrium between soluble and polymerized forms of actin is a necessary requirement for amoeboid movement. The topographic distribution of contractile filaments beneath the plasma membrane visualized by correlated light- and electron microscopy of DNAase I-injected cells establishes the importance of the membrane-bound filamentous layer for three major aspects of streaming: (1) Streaming originates by local contractions of a cell membrane-associated filament layer at the uroid and/or retracting pseudopods, creating a pressure flow. (2) This flow continues beneath the membrane, which is stabilized by filaments in the lateral regions between the posterior end, with a high hydrostatic pressure, and the anterior end, with a low hydrostatic pressure. (3) Pseudopods or extending areas are created by a local destabilization of the cell periphery caused by the separation of the filamentous layer from the plasma membrane.     

Spatial distribution of cortical proteins in cells of epithelial sheets

Summary In the differentiated pigmented epithelial cells of the retina (RPE) of chick embryos cytoskeletal proteins are found in polygonal rings located in the cell cortex. Within the cortical rings of the RPE cells vinculin and spectrin occupy a characteristic position closest to the plasma membrane; actin is found farther away, while tropomyosin and myosin are located farthest from the plasma membrane. The differences in the distribution of these proteins might reflect the functional specialization of different parts of the cortical ring required to develop and transmit tension from individual cells throughout the entire epithelial sheet.     

Contractile basis of ameboid movement. VII. The distribution of fluorescently labeled actin in living amebas

The technique of molecular cytochemistry has been used to follow the distribution of fluorescently labeled actin in living Chaos carolinensis and Amoeba proteus during ameboid movement and various cellular processes. The distribution of 5-iodoacetamidofluorescein- labeled actin was compared with that of Lissamine rhodamine B sulfonyl chloride-labeled ovalbumin microinjected into the same cell and recorded with an image intensification microscope system. Actively motile cells demonstrated a rather uniform distribution of actin throughout most of the cytoplasm, except in the tail ectoplasm and in plasma gel sheets, where distinct actin structures were observed. In addition, actin-containing structures were induced in the cortex during wound healing, concanavalin A capping, pinocytosis, and contractions elicited by phalloidin injections. The formation of distinct fluorescent actin structures has been correlated with contractile activities.     

Phosphorylation of Amoeba G-actin and its effect on actin polymerization

Mass culture of Amoeba proteus enabled us to do biochemical studies on this organism. Actin and profilin were purified from Amoeba to examine actin phosphorylation and polymerization. The apparent molecular weight of Amoeba actin was 44,000, and its isoelectric point was 5.8. The apparent molecular weight of Amoeba profilin was 12,000, and its isoelectric point was 4.9. It reduced the rate of actin polymerization as reported in the cases of profilins from other organisms. A protein of Mr = 44,000 (44 K protein) was phosphorylated in a Ca2+-dependent manner in cell homogenate of Amoeba without being inhibited by calmodulin antagonists. Using the homogenate as a kinase, purified Amoeba G-actin could be phosphorylated in proportion to the amount of actin. However, neither Amoeba F-actin nor rabbit skeletal muscle G-actin was phosphorylated. The phosphorylation of Amoeba actin with a kinase partially purified from A. proteus increased with dilution of the actin concentration. When Amoeba profilin was added, more than 80% of the actin was phosphorylated. By viscometry, electron microscopy, and ultracentrifugation analysis it was demonstrated that Amoeba G-actin phosphorylated in the presence of profilin and kinase did not polymerize in this solution. High-performance liquid chromatography analysis showed that phosphorylated Amoeba actin remained in a monomeric state even under conditions favorable for actin polymerization.     

Redundancy of lamellipodia in locomoting Walker carcinosarcoma cells

Locomoting metazoan cells usually form lamellipodia at the leading front and it is widely accepted that lamellipodia are required for locomotion. In this case, suppression of lamellipodia must stop locomotion. However, the experiments show that lamellipodia are redundant for locomotion of Walker carcinosarcoma cells. Low latrunculin A concentrations (10(-7) M) transform polarised locomoting cells with lamellipodia into cells without morphologically recognisable protrusions showing an increased speed of locomotion and a reduced amount of cellular F-actin. Whereas untreated cells show a fairly linear distribution of F-actin along the plasma membrane, cells lacking morphologically recognizable protrusions at the front show modifications at the front consisting in an irregular distribution of F-actin with formation of small or large patches of F-actin alternating with small or large gaps in the F-actin layer. This is associated with a reduced resistance to deformation pressure at the front of the cell. High concentrations of latrunculin A (>10(-7) M) compromising contraction at the rear stop locomotion, suggesting that cortical contraction is important for locomotion to occur in these cells. The results are consistent with the view that actin polymerization is important for formation of lamellipodia but they are not compatible with the view that lamellipodia are essential for locomotion of Walker carcinosarcoma cells. A unifying hypothesis for the formation of different types of protrusions is proposed.     

Differences in cortical actin structure and dynamics document that different types of blebs are formed by distinct mechanisms

Bleb formation has been studied by specifically targeting major factors controlling this process, such as microtubule disassembly, local actin depolymerization, and increased pressure. At least two different types of blebs (types 1 and 2) formed by different mechanisms and possibly a third type (type 3) can be documented at the front of living polarized cells expressing green fluorescent protein-actin and/or in fixed and stained cells. Type 1 blebs (membrane/cortex dissociation blebs) formed by dissociation of the plasma membrane from cortical actin develop cytoplasmic actin layers associated with restriction rings. They can be induced by the microtubule-disassembling agent colchicine. Type 2 blebs (cortical actin disassembly blebs) form after disassembly of the cortical actin layer in the presence of latrunculin A. Restriction rings without a cytoplasmic actin layer occur in a transition zone between the intact cortical actin layer of the cell body and the compromised actin layer of the bleb. Evidence for a third type of bleb (type 3), showing an intact cortical actin layer but no cytoplasmic actin layer and no recognizable relationship between the actin cytoskeleton and the restriction ring, has been obtained by passive cell deformation in micropipettes, which increases pressure. Repolymerization of the cortical actin layer does not necessarily result in bleb retraction. Once formed, restriction rings do not narrow, suggesting that they result from isometric contraction. A simplified classification scheme has been developed to relate the type of bleb to specific signals or cell functions. Its application shows that spontaneously blebbing cells form almost exclusively type 1 blebs.     

Is actin involved in the nuclear division in Amoeba proteus?

During semi-open mitosis of Amoeba proteus the nuclear envelope is not dispersed and nucleus divides by fission. The presence of actin layer close to nuclear envelope was demonstrated in interphase and telophase nuclei of that amoeba stained with rhodamine labelled phalloidin. In telophase, an accumulation of actin arises in the space between the future daughter nuclei. It appears to be comparable with the contractile ring of dividing cells. This suggests that actin associated with the nuclear envelope of Amoeba proteus may be involved in final separation of the daughter nuclei, forming a constriction ring at the middle of dividing nucleus.     

Identification of Novel Graded Polarity Actin Filament Bundles in Locomoting Heart Fibroblasts: Implications for the Generation of Motile Force

We have determined the structural organization and dynamic behavior of actin filaments in entire primary locomoting heart fibroblasts by S1 decoration, serial section EM, and photoactivation of fluorescence. As expected, actin filaments in the lamellipodium of these cells have uniform polarity with barbed ends facing forward. In the lamella, cell body, and tail there are two observable types of actin filament organization. A less abundant type is located on the inner surface of the plasma membrane and is composed of short, overlapping actin bundles (0.25–2.5 μm) that repeatedly alternate in polarity from uniform barbed ends forward to uniform pointed ends forward. This type of organization is similar to the organization we show for actin filament bundles (stress fibers) in nonlocomoting cells (PtK2 cells) and to the known organization of muscle sarcomeres. The more abundant type of actin filament organization in locomoting heart fibroblasts is mostly ventrally located and is composed of long, overlapping bundles (average 13 μm, but can reach up to about 30 μm) which span the length of the cell. This more abundant type has a novel graded polarity organization. In each actin bundle, polarity gradually changes along the length of the bundle. Actual actin filament polarity at any given point in the bundle is determined by position in the cell; the closer to the front of the cell the more barbed ends of actin filaments face forward.

By photoactivation marking in locomoting heart fibroblasts, as expected in the lamellipodium, actin filaments flow rearward with respect to substrate. In the lamella, all marked and observed actin filaments remain stationary with respect to substrate as the fibroblast locomotes. In the cell body of locomoting fibroblasts there are two dynamic populations of actin filaments: one remains stationary and the other moves forward with respect to substrate at the rate of the cell body.

This is the first time that the structural organization and dynamics of actin filaments have been determined in an entire locomoting cell. The organization, dynamics, and relative abundance of graded polarity actin filament bundles have important implications for the generation of motile force during primary heart fibroblast locomotion.

     

Interaction of a Dictyostelium member of the plastin/fimbrin family with actin filaments and actin-myosin complexes.

A protein purified from cytoskeletal fractions of Dictyostelium discoideum proved to be a member of the fimbrin/plastin family of actin-bundling proteins. Like other family members, this Ca(2+)-inhibited 67-kDa protein contains two EF hands followed by two actin-binding sites of the alpha-actinin/beta-spectrin type. Dd plastin interacted selectively with actin isoforms: it bound to D. discoideum actin and to beta/gamma-actin from bovine spleen but not to alpha-actin from rabbit skeletal muscle. Immunofluorescence labeling of growth phase cells showed accumulation of Dd plastin in cortical structures associated with cell surface extensions. In the elongated, streaming cells of the early aggregation stage, Dd plastin was enriched in the front regions. To examine how the bundled actin filaments behave in myosin II-driven motility, complexes of F-actin and Dd plastin were bound to immobilized heavy meromyosin, and motility was started by photoactivating caged ATP. Actin filaments were immediately propelled out of bundles or even larger aggregates and moved on the myosin as separate filaments. This result shows that myosin can disperse an actin network when it acts as a motor and sheds light on the dynamics of protein-protein interactions in the cortex of a motile cell where myosin II and Dd plastin are simultaneously present.     

Actin filament organization in the fish keratocyte lamellipodium

From recent studies of locomoting fish keratocytes it was proposed that the dynamic turnover of actin filaments takes place by a nucleation- release mechanism, which predicts the existence of short (less than 0.5 microns) filaments throughout the lamellipodium (Theriot, J. A., and T. J. Mitchison. 1991. Nature (Lond.). 352:126-131). We have tested this model by investigating the structure of whole mount keratocyte cytoskeletons in the electron microscope and phalloidin-labeled cells, after various fixations, in the light microscope. Micrographs of negatively stained keratocyte cytoskeletons produced by Triton extraction showed that the actin filaments of the lamellipodium are organized to a first approximation in a two-dimensional orthogonal network with the filaments subtending an angle of around 45 degrees to the cell front. Actin filament fringes grown onto the front edge of keratocyte cytoskeletons by the addition of exogenous actin showed a uniform polarity when decorated with myosin subfragment-1, consistent with the fast growing ends of the actin filaments abutting the anterior edge. A steady drop in filament density was observed from the mid- region of the lamellipodium to the perinuclear zone and in images of the more posterior regions of lower filament density many of the actin filaments could be seen to be at least several microns in length. Quantitative analysis of the intensity distribution of fluorescent phalloidin staining across the lamellipodium revealed that the gradient of filament density as well as the absolute content of F-actin was dependent on the fixation method. In cells first fixed and then extracted with Triton, a steep gradient of phalloidin staining was observed from the front to the rear of the lamellipodium. With the protocol required to obtain the electron microscope images, namely Triton extraction followed by fixation, phalloidin staining was, significantly and preferentially reduced in the anterior part of the lamellipodium. This resulted in a lower gradient of filament density, consistent with that seen in the electron microscope, and indicated a loss of around 45% of the filamentous actin during Triton extraction. We conclude, first that the filament organization and length distribution does not support a nucleation release model, but is more consistent with a treadmilling-type mechanism of locomotion featuring actin filaments of graded length. Second, we suggest that two layers of filaments make up the lamellipodium; a lower, stabilized layer associated with the ventral membrane and an upper layer associated with the dorsal membrane that is composed of filaments of a shorter range of lengths than the lower layer and which is mainly lost in Triton.     

Fine structure and distribution of contractile layers inAmoeba proteus preincubated at high temperature

Summary Ultrastructural and immunocytochemical studies allow the localization and identification of a microfilament cortex in heat-shockedAmoeba proteus at different stages of recovery to room temperature. Immediately after heating the cortex is in close contact with the cytoplasmic face of the plasma membrane; however, during cooling it detaches from the membrane and shifts toward the cell centre thus separating a region of peripheral hyaloplasm from central granuloplasm. After polymerization of a new submembrane cortex several detachment and reformation cycles rhythmically repeated for 2–3 hours until a multitude of stratified layers has been formed in the hyaloplasm.Electron micrographs reveal that the cortical layer at the plasma membrane is merely composed of a network of actin filaments, whereas the retracted contractile layers in the hyaloplasm and at the granuloplasmic border contain both, thick and thin filaments often arranged in bundles. The heat-shock induced activities of the microfilament cortex are based on the highly contractile properties of this system in conjunction with controlled displacements in the equilibrium between F- and G-actin.     

Analysis of the Actin–Myosin II System in Fish Epidermal Keratocytes: Mechanism of Cell Body Translocation

While the protrusive event of cell locomotion is thought to be driven by actin polymerization, the mechanism of forward translocation of the cell body is unclear. To elucidate the mechanism of cell body translocation, we analyzed the supramolecular organization of the actin–myosin II system and the dynamics of myosin II in fish epidermal keratocytes. In lamellipodia, long actin filaments formed dense networks with numerous free ends in a brushlike manner near the leading edge. Shorter actin filaments often formed T junctions with longer filaments in the brushlike area, suggesting that new filaments could be nucleated at sides of preexisting filaments or linked to them immediately after nucleation. The polarity of actin filaments was almost uniform, with barbed ends forward throughout most of the lamellipodia but mixed in arc-shaped filament bundles at the lamellipodial/cell body boundary. Myosin II formed discrete clusters of bipolar minifilaments in lamellipodia that increased in size and density towards the cell body boundary and colocalized with actin in boundary bundles. Time-lapse observation demonstrated that myosin clusters appeared in the lamellipodia and remained stationary with respect to the substratum in locomoting cells, but they exhibited retrograde flow in cells tethered in epithelioid colonies. Consequently, both in locomoting and stationary cells, myosin clusters approached the cell body boundary, where they became compressed and aligned, resulting in the formation of boundary bundles. In locomoting cells, the compression was associated with forward displacement of myosin features. These data are not consistent with either sarcomeric or polarized transport mechanisms of cell body translocation. We propose that the forward translocation of the cell body and retrograde flow in the lamellipodia are both driven by contraction of an actin–myosin network in the lamellipodial/cell body transition zone.