Motory effects of perforating peripheral cell layers ofAmoeba proteus

Summary Perforation of peripheral cell layers ofA. proteus in any place provokes immediate endoplasm efflux, what supports the view that the hydrostatic pressure is higher in the cell interior than outside. The local effusion of endoplasm results in the reversal of flow in formerly advancing pseudopodia, in agreement with the pressure gradient theories of protoplasmic streaming. Amoebae with destroyed frontal zones squeeze all their endoplasm out through the breach, what disproves the frontal contraction hypothesis of amoeboid movement, but supports the concept of a general contraction of cell cortex.Study supported by the Research Project II.1 of the Polish Academy of Science.     

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.     

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.     

Hydrostatic pressure mimics gravitational pressure in characean cells

Summary Hydrostatic pressure applied to one end of a horizontalChara cell induces a polarity of cytoplasmic streaming, thus mimicking the effect of gravity. A positive hydrostatic pressure induces a more rapid streaming away from the applied pressure and a slower streaming toward the applied pressure. In contrast, a negative pressure induces a more rapid streaming toward and a slower streaming away from the applied pressure. Both the hydrostatic pressure-induced and gravity-induced polarity of cytoplasmic streaming respond identically to cell ligation, UV microbeam irradiation, external Ca²⁺ concentrations, osmotic pressure, neutral red, TEA Cl^–, and the Ca²⁺ channel blockers nifedipine and LaCl₃. In addition, hydrostatic pressure applied to the bottom of a vertically-oriented cell can abolish and even reverse the gravity-induced polarity of cytoplasmic streaming. These data indicate that both gravity and hydrostatic pressure act at the same point of the signal transduction chain leading to the induction of a polarity of cytoplasmic streaming and support the hypothesis that characean cells respond to gravity by sensing a gravity-induced pressure differential between the cell ends.     

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.     

Entamoeba motility: dynamics of cytoplasmic streaming, locomotion and translocation of surface-bound particles, and organization of the actin cytoskeleton in Entamoeba invadens.

The dynamics of cytoplasmic streaming, retrograde translocation of externally bound particles and locomotion by Entamoeba invadens were compared. Locomoting amoebae were monopodial, exhibited fountain flow cytoplasmic streaming and translocated externally bound erythrocytes to the rear of cells. The rates of rearward flow of peripheral cytoplasmic vacuoles and of the externally bound particles were equal to the rate of cell forward locomotion. Rhodamine-phalloidin staining revealed a distinct cortical polymerized actin cytoskelton. This was least evident about the periphery of the advancing pseudopod, increased in density toward the rear of the cell and was most concentrated in the uroid. A monoclonal anti-eucaryotic actin antibody, which recognized monomeric Entamoeba actin on immunoblots, stained trophozoites by indirect immunofluorescence throughout the cytoplasm, but not in the cortical regions stained by rhodamine-phalloidin. This and other evidence implied that the antibody recognized only unpolymerized actin in Entamoeba. We propose that locomotion, cytoplasmic streaming and translocation of externally bound particles are driven by a common actin-based mechanism in Entamoeba, possibly involving retrograde cortical actin flow and recycling.     

Entamoeba Motility: Dynamics of Cytoplasmic Streaming, Locomotion and Translocation of Surface-Bound Particles, and Organization of the Actin Cytoskeleton in Entamoeba invadens

ABSTRACT. The dynamics of cytoplasmic streaming, retrograde translocation of externally bound particles and locomotion by Entamoeba invadens were compared. Locomoting amoebae were monopodial, exhibited fountain flow cytoplasmic streaming and translocated externally bound erythrocytes to the rear of cells. The rates of rearward flow of peripheral cytoplasmic vacuoles and of the externally bound particles were equal to the rate of cell forward locomotion. Rhodamine-phalloidin staining revealed a distinct cortical polymerized actin cytoskeleton. This was least evident about the periphery of the advancing pseudopod, increased in density toward the rear of the cell and was most concentrated in the uroid. A monoclonal anti-eucaryotic actin antibody, which recognized monomeric Entamoeba actin on immunoblots, stained trophozoites by indirect immunofluorescence throughout the cytoplasm, but not in the cortical regions stained by rhodamine-phalloidin. This and other evidence implied that the antibody recognized only unpolymerized actin in Entamoeba . We propose that locomotion, cytoplasmic streaming and translocation of externally bound particles are driven by a common actin-based mechanism in Entamoeba , possibly involving retrograde cortical actin flow and recycling.     

The contractile basis of amoeboid movement : IV. The viscoelasticity and contractility of amoeba cytoplasm in vivo

The viscoelasticity and contractility of amoeba cytoplasm has been studied in vivo and in vitro. A gradient of increasing viscoelasticity and contractility was identified in the endoplasm of intact cells from the uroid (tail) to the fountain zone (tip of advancing pseudopod). Anterior endoplasm, as well as all of the ectoplasm, contracted in response to the microinjection of a threshold calcium ion concentration (ca 7.0 × 10⁻⁷ M). In contrast, there were only delayed weak contractions in the uroid endoplasm upon the microinjection of a threshold calcium ion concentration. Contractions induced in the ectoplasm by microinjecting the contraction solution readily caused the endoplasm to stream. However, the endoplasm at the tips of the extending pseudopods were also contractile and transmitted applied tensions. Furthermore, the microinjection of subthreshold calcium ion concentrations caused the loss of distinct endoplasmic structure and the cessation of streaming in both the uroid and the anterior third of the cell. In addition, the relationship between contractility and cytoplasmic streaming was characterized in “relaxed” cytoplasm placed in a gradient of calcium ion concentration inside quartz capillaries. The results of these experiments demonstrated that the mechanochemical conversion of endoplasm to ectoplasm caused the cytoplasm to become more structured and contractile. Therefore, physiological contractions are possible during and after the conversion of endoplasm to ectoplasm.     

Relative motion inAmoeba proteus in respect to the adhesion sites

Summary The whole ectoplasmic layer of polytactic and heterotactic forms ofA. proteus behaves as self-contractile structure. Depending on the configuration of cell body and on the cell-to-substrate attachment conditions it continuously retracts from each distal cell projection toward its centre and/or from each free body end toward the actual adhesion sites. As in the monotactic forms, it leads to the withdrawal of the tail region behind the retraction center and may result in the fountain movement in front of it. In the long unattached pseudopodia of heterotactic forms the ectoplasm is retracted in the fountain form, with the velocity linearly increasing from the basis of pseudopodium up to its tip. In polytactic cells the fountain is often absent, if the advancing fronts immediately adhere to the substrate. When they develop in unattached condition, or are experimentally obliged to detach, the ectoplasmic cylinders of frontal pseudopodia are retracted backwards. On the substrates which do not offer firm points of support the cell periphery moves back as a whole,i.e., the principal ectoplasmic cylinder retracts together with the cylinders of lateral pseudopodia, and the direction and speed of movement in any spot is the resultant of forces produced by all other segments. The retraction of ectoplasmic gel layer is independent of the endoplasmic flow in such extent that a pseudopodium may be withdrawn as a whole in spite of the endoplasm streaming directed forwards in its interior. On the cell surface the particles attached by adhesion (glass rods) strictly follow the movements of the internal ectoplasmic structures, whereas the unattached particles flow forward in the direction of endoplasm streaming.Study supported by Research Project II. 1 of the Polish Academy of Science.     

AN ELECTRON MICROSCOPE STUDY OF VITALLY STAINED SINGLE CELLS IRRADIATED WITH A RUBY LASER MICROBEAM

An electron microscope study has been made of vitally stained single cells whose cytoplasm has been subjected to a localized ruby laser microbeam. Light and moderate laser absorption (the resultant of stain concentration and laser energy density) produced restricted selective damage of mitochondria in cells stained with Janus green B; heavy laser absorption resulted in mitochondrial damage, as well as in nonselective interaction with other cell structures. With four other basic vital stains, the polysomes, ergastoplasm, mitochondria and other organelles at the irradiated site were uniformly damaged. Unstained cells showed no morphological alterations. With light primary damage (that restricted to the irradiation site), no secondary effects of the incident radiation were observed. With moderate primary damage, however, secondary damage of the mitochondria in the unirradiated cell portions was produced, which was reversible within 4 hr after irradiation. Heavy primary lesions caused severe secondary alteration of all cell structures that was irreversible and cell death occurred within 2 hr. Surviving cells examined 24 hr after light and moderate irradiation could not be distinguished from unirradiated controls. The possible mechanisms involved in the production of laser-induced cellular alterations are discussed.     

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.     

THE CONTRACTILE BASIS OF AMOEBOID MOVEMENT : I. The Chemical Control of Motility in Isolated Cytoplasm

Cytoplasm has been isolated from single amoeba (Chaos carolinensis) in physiological solutions similar to rigor, contraction, and relaxation solutions designed to control the contractile state of vertebrate striated muscle. Contractions of the isolated cytoplasm are elicited by free calcium ion concentrations above ca. 7.0 x 10^-7 M. Amoeba cytoplasmic contractility has been cycled repeatedly through stabilized (rigor), contracted, and relaxed states by manipulating the exogenous free calcium and ATP concentrations. The transition from stabilized state to relaxed state was characterized by a loss of viscoelasticity which was monitored as changes in the capacity of the cytoplasm to exhibit strain birefringence when stretched. When the stabilized cytoplasm was stretched, birefringent fibrils were observed. Thin sections of those fibrils showed thick (150–250 Å) and thin (70 Å) filaments aligned parallel to the long axis of fibrils visible with the light microscope. Negatively stained cytoplasm treated with relaxation solution showed dissociated thick and thin filaments morphologically identical with myosin aggregates and purified actin, respectively, from vertebrate striated muscle. In the presence of threshold buffered free calcium, ATP, and magnesium ions, controlled localized contractions caused membrane-less pseudopodia to extend into the solution from the cytoplasmic mass. These experiments shed new light on the contractile basis of cytoplasmic streaming and pseudopod extension, the chemical control of contractility in the amoeba cytoplasm, the site of application of the motive force for amoeboid movement, and the nature of the rheological transformations associated with the circulation of cytoplasm in intact amoeba.     

Cytoplasmic streaming inParamecium

Summary Certain species ofParamecium demonstrate rotational cytoplasmic streaming, in which most cytoplasmic particles and organelles flow along permanent route, in a constant direction. By means of novel methods of immobilization, observation and recording, some dynamic properties of cytoplasmic streaming have been described. It was found that the velocity profiles of coaxial layers of cytoplasm have a (parabolic) paraboidal shape and the mean output of cytoplasm flow in different examined zones of streaming is constant. As the consequence of randomly distributed elementary propulsion units within the cytoplasm, particles, which serve as markers of movement, exhibit movements of a saltatory nature; this form of movement is seen inParamecium streaming only in cases of error due to polarization of the saltating particles. Interaction of actin filaments and myosin is likely to occur under specific conditions in microcompartments of cytoplasm where local solations are generated eventually leading to contractions which might propagate on gelated neighbouring areas. Places of elementary contractions are scattered. Therefore the motile effect appears as streaming. Rotational cytoplasmic streaming inParamecium may serve as a convenient model for the study of the dynamics and function of cytoplasmic motility.     

Blebbing of Dictyostelium cells in response to chemoattractant

Stimulation of Dictyostelium cells with a high uniform concentration of the chemoattractant cyclic-AMP induces a series of morphological changes, including cell rounding and subsequent extension of pseudopodia in random directions. Here we report that cyclic-AMP also elicits blebs and analyse their mechanism of formation. The surface area and volume of cells remain constant during blebbing indicating that blebs form by the redistribution of cytoplasm and plasma membrane rather than the exocytosis of internal membrane coupled to a swelling of the cell. Blebbing occurs immediately after a rapid rise and fall in submembraneous F-actin, but the blebs themselves contain little F-actin as they expand. A mutant with a partially inactivated Arp2/3 complex has a greatly reduced rise in F-actin content, yet shows a large increase in blebbing. This suggests that bleb formation is not enhanced by the preceding actin dynamics, but is actually inhibited by them. In contrast, cells that lack myosin-II completely fail to bleb. We conclude that bleb expansion is likely to be driven by hydrostatic pressure produced by cortical contraction involving myosin-II. As blebs are induced by chemoattractant, we speculate that hydrostatic pressure is one of the forces driving pseudopod extension during movement up a gradient of cyclic-AMP.     

Movement of surface markers along the pinocytotic pseudopodia ofAmoeba proteus

Summary The movement of latex beads over pinocytotic pseudopodia produced byAmoeba proteus was recorded in the presence of 117.65 mM EGTA as an inducer of pinocytosis. The results show that all particles flow in the direction of pseudopodial growth, with a slightly higher velocity than the advancing frontal edge. This means that markers are removed from the base of a pinocytotic pseudopodium and gradually approach the pseudopodium tip. Two particles on the surface of the same pseudopodium can move at the same rate or differ slightly in the velocity of their forward flow. A bead can move even if another blocks the channel orifice. Retrograde particle movement has never been observed. Whether all latex spheres bound to pinocytotic pseudopodia flow with the laterally mobile plasma membrane fraction, which slides over submembranous contractile layer, or whether the whole cortical complex, the actin network and the plasma membrane, move together towards the invagination site is discussed.     

Morphology of <Emphasis Type="Italic">Mastigamoeba aspera</Emphasis> schulze, 1875 (Archamoebae,Pelobiontida)

The morphology of Mastigamoeba aspera, a typical species of the genus Mastigamoeba Schulze, 1875, was studied at the optical and electron microscopy level. During movement, M. aspera has an oval or pyriformic shape, with the motile flagella being located at the anterior end of mononuclear forms. In the process of movement, the mastigamoeba surface forms numerous conical or finger-shaped hyaline pseudopodia, whereas thel caudal cell end is usually transformed into a bulboid uroid. In M. aspera micropopulations, there are noted both mononuclear cells with flagella and multinuclear flagella-free individuals. The M. aspera plasma membrane has at its outer surface a hypertrophied glycocalix layer inhabited by numerous rod-shaped bacteria-ectobionts. The M. aspera nucleus is of vesicular type, with a large central spherical nucleolus. The flagellar apparatus is closely connected morphologically with the M. aspera nucleus. The basal flagella part is represented by a single kinetosome, from which radial microtubules and a lateral rootlet pass out into the cytoplasm. At the base of the kinetosome, there is located a compact center of organization of microtubules (COMT), in which there are immersed bases of the nuclear cone microtubules participating in formation of karyomastigont. The structure of the flagella axoneme corresponds to the formula 9(2)+2. The main volume of the M. aspera cytoplasm is occupied with digestive vacuoles. In addition, the cells contain numerous light-reflecting granules, as well as glycogen granules. Mitochondria, dictyosomes of the Golgi apparatus, and microbodies in the M. aspera cell cytoplasm are not revealed.     

Synchronization and signal transmission in protoplasmic strands of Physarum

The importance of endoplasmic streaming in the synchronization of contraction activites in plasmodial strands of Physarum was investigated under experimental conditions allowing simultaneous observation of the endoplasmic flow in the middle part of a strand mounted as a trapeze and the measurement of isometric contraction activities of the arms of the trapeze, as well as of the activities of the strand portion connecting the arms. The correlation of longitudinal and radial contraction activities in different regions of a trapeze was examined. Whereas the arms and the middle part of a trapeze contract synchronously in a longitudinal direction (in-phase behaviour), an antiphase correlation appeared when comparing the longitudinal contraction activity of the arms and the radial activity of the middle part. This result is interpreted to mean that the middle part is able to perform isotonic contractions which induce radial dilatation of the strands. No clear-cut correlation between longitudinal and radial activities could be found when measuring simultaneously both activities in one and the same arm of a trapeze by combining tensiometry and cinematography. Protoplasmic shuttle streaming within a strand mounted as a trapeze is found to run regularly out of one arm through the middle part into the other arm, and vice versa. There is no correlation between the time points of streaming reversal and a certain stage of contraction cycles as presented by the contraction curves of the arms. However, there is a good correlation between the points of streaming reversal and the phase deviations of the longitudinal contraction activities of the arms. The importance of these phase deviations for the control of streaming reversal, i.e., for the generation of hydrostatic pressure differences in a system working with phase synchrony, is discussed. The role of endoplasmic streaming as a pacemaker for synchronization phenomena of contraction activities is stressed. The possibility is discussed that shuttle streaming of endoplasm acts as a mechanical coupling within the regulation phenomena resulting in spatial monorhythmicity.Partly presented at the Cell Motility workshop, 8^th European Muscle Conference, Heidelberg 17.–20. September 1979     

Dynamics of the contractile system in the pseudopodial tips of normally locomoting amoebae,demonstrated in vivo by video-enhancement

Summary Behaviour of the membrane and contractile system was directly recorded in the advancing and retracting frontal zones of spontaneously locomoting or stimulated amoebae. The advancing pseudopodial tips alternately slow down and accelerate. In the slowing phase the frontal hyaline caps are flat and compressed by countercontraction of the cortical actin network beneath the leading edge. At this stage the membrane-cytoskeleton complex splits: the detached contractile layer is retracted inwards, and the membrane lifted outwards. The fluid endoplasm fraction is filtered forward through the detached actin network. This results in a local hydrostatic pressure drop, immediately restores the forward flow of endoplasm and initiates the acceleration phase of the leading edge progression. The frontal membrane, temporarily disconnected from the cytoskeletal layer, is free to slide and extend forward, but the new submembrane contractile network is soon repolymerized. In this way, after making one step forward, the frontal zone recovers its former state, and the cycle is then repeated. The cortex disassembly-reassembly cycles at the leading edge are produced every 2 s, on average. Retraction of the frontal contractile layers is part of the general centripetal cortex flow observed during motor functions of amoebae and many other cells, and is therefore associated with various other backward movements observed within and on the surface of advancing frontal zones of amoebae. The backward movement of the contractile cortex is also responsible for the withdrawal of previously advancing pseudopodia, if the detachment of successive contractile sheets from the frontal membrane ceases. It was demonstrated that the action of attractants and repellents is based on the activation or inhibition, respectively, of rhythmic disassembly of the membrane-cytoskeleton complex at the leading edge.     

Dynamics of the cytoskeleton inAmoeba proteus: II. Influence of different agents on the spatial organization of microinjected fluorescein-labeled actin

Summary Iodoacetamido-fluorescein-(IAF)-labeled actin was microinjected into normal locomotingAmoeba proteus. Thereafter (30–60 minutes) changes in the cytoplasmic fluorescence distribution pattern and contractile activity were induced by internal and external chemical stimulation. Different agents such as phalloidin, procaine, 2.4-dinitrophenol (DNP), puromycin, ouabain and n-ethyl maleimide (NEM) interfere with the excitation-contraction mechanism involved in ordered pseudopodium formation during ameboid movement and cause various morphogenetic reactions based on actin polymerization-depolymerization cycles. Most frequent changes are (a) local condensation of IAF-actin and formation of a continuous IAF-actin layer at the cytoplasmic surface of the cell membrane and around the pulsating vacuole, (b) immobilization and hyalo-granuloplasm separation by combined contraction and detachment of the IAF-actin layer from the cell membrane, (c) organized and disorganized formation of pseudopodia by local contraction and disintegration of the IAF-actin layer, and (d) alterations in the rheological properties of the protoplasmic matrix by changes in the molecular state of soluble actin not incorporated into the cytoskeleton. The experimental approaches to the function of the actomyosin system in large amebas attainable by the method ofin vivo molecular cytochemistry are discussed in detail with respect to the participation of the cytoskeleton in motive force generation for cytoplasmic streaming and ameboid movement.     

PHASE CINEMICROGRAPHIC OBSERVATIONS ON CULTURED CELLS. II. MASS MOVEMENT OF CYTOPLASM IN EUPHORBIA MARGINATA

Mass movement is a form of streaming in which distinct quantities of cytoplasm flow as entities along a transvacuolar strand or cytoplasmic striations of the peripheral cytoplasm. An individual mass can move at variable velocities during a brief period of time or change its direction of flow. Two masses, when moving at different velocities in the same or different directions along a strand, can be observed to collide. This can occur repeatedly, resulting in the formation of a mass of considerable size. Many organelles can be observed to move at velocities differing from that of the mass; some can be observed to change directions during their movement. A mass may represent a dilation of one or more microstreams within the cytoplasm. Folding of the microstreams within a mass may explain the changes in the direction of movement observed for some organelles. Several levels of movement are associated with streaming, including those of the ground plasm, of the organelles, of the transvacuolar strands and of the cytoplasm masses. These, and possibly more subtle aspects of the streaming phenomenon, must be incorporated into any theory of streaming.