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.     

Protease-sensitive anchoring of microfilament bundles provides tracks for cytoplasmic streaming inVallisneria

Summary In mesophyll cells of the aquatic angiospermVallisneria gigantea Graebner, the endoplasm streams rotationally along the cell walls normal to the leaf surface in situ. Bundles of microfilaments anchored in the ectoplasm serve as tracks for the cytoplasmic streaming. In single mesophyll cells isolated by enzymatic digestion, hypertonic treatment induces abnormal streaming concomitant with plasmolysis, specifically at one or both of the shorter sides of an approximate rectangle. The disorderly arrangement of microfilaments in such cells has been confirmed by fluorescence microscopy of cells stained with FITC-phalloidin. While inhibitors of proteases added to the enzyme solution used for isolation of cells suppress the disturbance of rotational streaming, exogenously applied protease promotes it. The results suggest that bundles of microfilaments in the ectoplasm are stabilized by protease-sensitive factor(s) in the presence of the cell wall.     

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.     

Cytoplasmic streaming in giant algal cells: A historical survey of experimental approaches

Various methods have been used to study cytoplasmic streaming in giant algal cells during the past three decades. Simple techniques can be used with characean internodal cells to modify the cell constitution in various ways to gain insight into the mechanism of cytoplasmic streaming. Another method involves isolatingin vitro a huge drop of uninjured endoplasm, to examine its physical and dynamic properties. The motive force responsible for streaming has been measured by three different techniques with similar results. Subcortical fibrils consisting of bundles of F-actin with the same polarity are indispensable for streaming. Differential treatment of the endoplasm and ectoplasm has shown that putative characean myosin is localized in the endoplasm. Studies of the roles of ATP, Mg²⁺, Ca²⁺, H⁺ etc. in the streaming have been conducted by cellular perfusion, which allows removal of the tonoplast, or by techniques permeabilizing the protoplasmic membrane. A slow version of the movement can even be artificially reproduced by combining characean actinin situ and exogenous myosin in the presence of Mg-ATP. The findings thus far obtained support the hypothesis that cytoplasmic streaming in characean cells is caused by an active shearing force produced by interaction of the actin filament bundles on the cortex with myosin in the endoplasm.     

Cytoplasmic streaming in internodal cells ofNitella under centrifugal acceleration: a study done with a newly constructed centrifuge microscope

Summary We constructed a new centrifuge microscope of the stroboscopic type, with which the cytoplasmic streaming inNitella internodal cells under centrifugal acceleration was studied. Under moderate centrifugal acceleration (ca. 50–100×g), the direction of cytoplasmic streaming in an internodal cell ofNitella is parallel to the direction of the subcortical fibrils. The speed of endoplasm flowing contiguous to the subcortical fibrils is neither accelerated nor retarded by moderate centrifugal acceleration. The endoplasmic flow, however, stops suddenly following an electrical stimulus. The endoplasm contiguous to the subcortical fibrils is immobilized transiently at the time of streaming cessation induced by an electrical stimulus under centrifugal acceleration at 50–100×g, even at 900×g. It is suggested that transitory cross bridges between the immobilized endoplasm and the subcortical fibrils are formed at the time of streaming cessation. The bulk endoplasm flows as a whole in the direction parallel to that of the subcortical fibrils and stops promptly upon electrical stimulation. Soon after the stoppage the bulk endoplasm starts to flow passively in the direction parallel to that of the centrifugal acceleration as a result of the centrifugal force.Abbreviations APW artificial pond water - CMS centrifuge microscope     

Cortical organellar complexes,their structure,formation, and bearing upon cell shape in a ciliate,Dileptus

Summary Ciliary complexes termed the kinetids, contain fibres of several kinds attached to the proximal end of a basal body. One of these fibres, the long microtubular fibre running in the endoplasm ofDileptus, is of special interest for this study. The fibres when attached to oral kinetids are orientated towards the cell posterior, and are numerous in the proboscis endoplasm. The fibres anchored at locomotor kinetids are orientated towards the cell anterior and penetrate the endoplasm of the tail. The endoplasm of both proboscis and tail appears transparent when viewed in the light microscope, and is deprived of many organelles: nuclei, lipid droplets, and food vacuoles. During regeneration proboscis and tail reconstitution is simultaneous, with an increase in transparency and in the density of microtubular fibres within the regenerating region. In posterior fragments ofDileptus which contain locomotor kinetids only, oral kinetids form as an offspring of locomotor ones. During differentiation of oral structures oral kinetids rotate until their endoplasmic fibres point posteriorly. It is this rotation that supplies the cell with a posteriorly directed set of endoplasmic fibres. The possibility that the translocation of endoplasmic organelles along the microtubular fibres may be one of mechanisms in shaping cells is discussed. Since the direction of endoplasmic translocation depends upon fibre orientation, the MTOCs which govern this orientation are likely candidates to be bearers of information concerning cell shape inDileptus.     

Electron Microscopy of the Ectoplasm and the Proboscis in Didinium nasutum

SYNOPSIS. A morphological study on the ectoplasm and the proboscis in the ciliate Didinium nasutum , has been performed by means of an electron microscope. The ectoplasm and the endoplasm of Didinium are separated by a fibrous layer. In addition to the ciliary apparatus and the filament system, the ectoplasm is characterized by having ectoplasmic vacuoles enclosing cross-striated bodies and by having small rods surrounding the ciliary basal body.
The filament system is composed of 4 types of tubular filaments: primary filaments originating from the basal body, secondary ones coursing longitudinally along the cell periphery, tertiary ones going down in cylindrical arrays from the periphery of the proboscis into the endoplasm, and finally kinetosomal ones from the base of the basal body into the endoplasm through the newly found pore of the fibrous layer.
The fine morphology of the trichites in the proboscis is elucidated three-dimensionally and illustrated schematically. Moreover, the correlation among the small rod, ectoplasmic vacuole and trichite is discussed.     

Structural basis of cytoplasmic streaming in Characean internodal cells. A hydrodynamic analysis

Summary Hydrodynamic equations were derived which relate the velocity profile of endoplasmic streaming with the motive force generated by active sliding of endoplasmic organelles in Characean internodal cells, under two implicit assumptions that (1) the sliding velocity of putative organelles is comparable to the streaming velocity of endoplasm, and (2) subcortical endoplasm is far less viscous than bulk endoplasm.The equations were extended so as to calculate the velocity profile in flattened or perfused internodal cells. Calculated profiles were basically consistent with reported patterns of streaming under these conditions.Utilizing published data, we deduce some hydrodynamic parameters of streaming, and predict the dimensions of putative organelles expected to drive entire cytoplasm. A revision for published values of the motive force of streaming is proposed.Hydrodynamic analyses made earlier on the spherical organelles are repeated. The results show that the organelles may generate streaming, depending on the configurationin vivo of fine filaments protruding from the body of the organelles.     

Relative motion inAmoeba proteus in respect to the adhesion sites. I. Behavior of monotactic forms and the mechanism of fountain phenomenon

Summary The unbranched ectoplasmic cylinder of monotacticA. proteus is always retracted toward the cell-substrate attachment sites. The retraction velocity increases from the adhesion sites toward any free distal body end in a linear way, which indicates the uniform contractility of the whole cylinder. Therefore, in the cells frontally attached all the ectoplasm moves forward, and in those adhering by the tail the whole ectoplasmic tube moves backward producing the full fountain phenomenon. With cell attachment at the middle body regions, which is most typical for normal locomotion, the whole ectoplasm is centripetally retracted from both body poles toward the adhesion zone, producing then the tail retraction in the posterior and incomplete fountain in the anterior body part. In unattached amoebae the whole peripheral tube is retracted toward its geometrical centre which coincides with its posterior closed end, producing therefore also a full fountain. It is generalized that the fountain arises always between an unattached front and the nearest attachment point behind its manifestation zone. The photographic records of movement and longitudinal velocity profiles of ectoplasmic retraction are identical on both sides of the attachment points, suggesting the same mechanism for the fountain movement as for the tail withdrawal. It is concluded therefore that not the axial endoplasmic arm of the fountain is active, but its peripheral arm built of the ectoplasm.All elements complicating the cell contour, as the constriction rings and ephemeral lateral pseudopodia, do not change their position in respect to the ectoplasmic material, but move together with it in respect to the substrate, i.e., the cytoskeleton moves as a whole. Loose glass rods attached by adhesion to cell surface also precisely follow the cytoskeleton movements, being transported toward the main locomotory adhesion zone established on the firm substrate, although the cell membrane as such behaves differently. It suggests a direct connection between the adhesion sites and the cytoskeleton.Study supported by Research Project II. 1 of the Polish Academy of Science.I dedicate this paper to the memory of Reginald J. Goldacre, deceased in December 1983, who twenty years ago introduced me to the study of amoebae.     

Fluorescence Microscopic Study of Microorganisms Treated with Chaotropic Agents

The yeasts Saccharomyces cerevisiae and Pichia pastoris and the bacteria Micrococcus luteus, Bacillus subtilis, and Anaerobacter polyendosporus have been treated with the chaotropic agents guanidine hydrochloride and guanidine thiocyanate and certain detergents and studied using fluorescence microscopy. Studies with the use of fluorochromes that can selectively stain nucleic acids (diamidino-2-phenylindole (DAPI), propidium iodide, and acridine orange) show that treatment of the bacterial and yeast cells at 37°C for 3–5 h induces a release of DNA from the cytoplasm and its accumulation in the cellular zone, known as ectoplasm, located between the cell wall and the remainder of the cytoplasm (called endoplasm) in the form of one or several large granules. After treating the cells with the chaotropic agents at 100°C for 5–6 min, the DNA is diffusively distributed over the ectoplasm. The fluorochromes used do not allow the detection of RNA. These findings are in agreement with previous data obtained from electron microscopic study of thin cell sections. After 33 PCR cycles, a considerable portion of DNA leaves the cells; as a result, they show a low level of diffusive fluorescence when stained with DAPI. When endospores of B. subtilis are treated with the chaotropic agents, they become highly permeable to the fluorochromes. Fluorescence microscopic study of such endospores shows that they contain DNA in the central part of their cores.__________Translated from Mikrobiologiya, Vol. 74, No. 4, 2005, pp. 505–510.Original Russian Text Copyright © 2005 by Duda, Danilevich, Akimov, Suzina, Dmitriev, Shorokhova.     

Localization of actin messenger RNA during early ascidian development

The spatial distribution of RNA sequences during early development of the ascidian, Styela plicata, was determined by in situ hybridization with poly(U) and cloned DNA probes. Styela eggs and embryos contain three colored cytoplasmic regions of specific morphogenetic fates, the ectoplasm, endoplasm, and myoplasm. These cytoplasmic regions participate in ooplasmic segregation after fertilization and are distributed to different cell lineages during early embryogenesis. n situ hybridization with poly(U) suggests that poly(A)+RNA is unevenly distributed in eggs and embryos, with about 45% in the ectoplasm, 50% in the endoplasm, and only 5% in the myoplasm. In situ hybridization with a histone DNA probe showed that histone RNA sequences were not localized in eggs or embryos and distributed between the three cytoplasmic regions according to their volumes. In situ hybridization with an actin DNA probe showed actin RNA was localized in the myoplasm and ectoplasm of eggs and embryos with about 45% present in the myoplasm, 40% in the ectoplasm, and only 15% in the endoplasm. These results suggest that a large proportion of the egg actin mRNA is localized in the myoplasm, participates in ooplasmic segregation after fertilization, and is differentially distributed to the mesodermal cell lineages during embryogenesis. Analysis of the translation products of egg mRNA suggests that the localized mRNA codes for a cytoplasmic actin isoform.     

Fluorescence microscopic study of the microorganisms treated with chaotropic agents

The yeasts Saccharomyces cerevisiae and Pichia pastoris and the bacteria Micrococcus luteus, Bacillus subtilis, and Anaerobacter polyendosporus have been treated with the chaotropic agents guanidine hydrochloride and guanidine thiocyanate and certain detergents and studied using fluorescence microscopy. Studies with the use of fluorochromes that can selectively stain nucleic acids (diamidino-2-phenylindole (DAPI), propidium iodide, and acridine orange) show that treatment of the bacterial and yeast cells at 37 degrees C for 3-5 h induces a release of DNA from the cytoplasm and its accumulation in the cellular zone, known as ectoplasm, located between the cell wall and the remainder of the cytoplasm (called endoplasm) in the form of one or several large granules. After treating the cells with the chaotropic agents at 100 degrees C for 5-6 min, the DNA is diffusively distributed over the ectoplasm. The fluorochromes used do not allow the detection of RNA. These findings are in agreement with previous data obtained from electron microscopic study of thin cell sections. After 33 PCR cycles, a considerable portion of DNA leaves the cells; as a result, they show a low level of diffusive fluorescence when stained with DAPI. When endospores of B. subtilis are treated with the chaotropic agents, they become highly permeable to the fluorochromes. Fluorescence microscopic study of such endospores shows that they contain DNA in the central part of their cores.     

In vitro models of tail contraction and cytoplasmic streaming in amoeboid cells

We have developed a reconstituted gel-sol and contractile model system that mimics the structure and dynamics found at the ectoplasm/endoplasm interface in the tails of many amoeboid cells. We tested the role of gel-sol transformations of the actin-based cytoskeleton in the regulation of contraction and in the generation of endoplasm from ectoplasm. In a model system with fully phosphorylated myosin II, we demonstrated that either decreasing the actin filament length distribution or decreasing the extent of actin filament cross-linking initiated both a weakening of the gel strength and contraction. However, streaming of the solated gel components occurred only under conditions where the length distribution of actin was decreased, causing a self-destruct process of continued solation and contraction of the gel. These results offer significant support that gel strength plays an important role in the regulation of actin/myosin II-based contractions of the tail cortex in many amoeboid cells as defined by the solation-contraction coupling hypothesis (Taylor, D. L., and M. Fechheimer. 1982. Phil. Trans. Soc. Lond. B. 299:185-197). The competing processes of solation and contraction of the gel would appear to be mutually exclusive. However, it is the temporal-spatial balance of the rate and extent of two stages of solation, coupled to contraction, that can explain the conversion of gelled ectoplasm in the tail to a solated endoplasm within the same small volume, generation of a force for the retraction of tails, maintenance of cell polarity, and creation of a positive hydrostatic pressure to push against the newly formed endoplasm. The mechanism of solation-contraction of cortical cytoplasm may be a general component of the normal movement of a variety of amoeboid cells and may also be a component of other contractile events such as cytokinesis.     

Differential treatment ofAcetabularia with cytochalasin B and N-Ethylmaleimide with special reference to their effects on cytoplasmic streaming

Summary Cytoplasmic streaming in the stalk ofAcetabularia, ryukyuensis at the vegetative stage was reversibly inhibited by cytochalasin B (cB) of 50 g/ml and irreversibly by N-Ethylmaleimide (NEM) above concentrations of 0.25 mM.After the endoplasm and the chloroplasts were pushed forward one end of the stalk by gentle centrifugation at about 500 × g for 3 minutes, numerous ectoplasmic striations remainedin situ in the stalk cortex. The striations ran in parallel with the longitudinal axis of the stalk at unequal intervals. The endoplasm streamed back only along these striations.By combining centrifugation and a double chamber technique, the endoplasm and the cortex of the stalk were treated separately with CB or NEM. CB treatment of the cortex arrested streaming; when treatment was restricted to the endoplasm, streaming continued at an normal rate. NEM treatment restricted to the cortex permitted normal streaming rates. Treatment restricted to the moving endoplasm inhibited streaming.These results suggest that microfilaments and a moiety, possibly myosin, play an active role in the streaming. Microfilaments must reside in the cortex, especially in the ectoplasmic striations, while the putative myosin must reside in the moving endoplasm.     

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     

Myxosoma pendula n. sp. (Protozoa,Myxosporida) from the Creek Chub Semotilus atromaculatus*

SYNOPSIS. A new species, Myxosoma pendula, was found surrounded by tissue fluid with granulocytes in pedunculated cysts formed from the mucous membrane of the gill arches of Semotilus atromaculatus collected in the Kewaunee River in Wisconsin. This species has a spherical vegetative stage with 2-layered ectoplasm composed of an outer homogeneous layer and an inner layer with canaliculi, and avoid spores that differentiate in the central area of the endoplasm.     

Bidirectional flow of endoplasm inPhysarum plasmodium under centrifugal acceleration

Summary The behavior of cytoplasmic streaming in plasmodial strand ofPhysarum polycephalum was studied under centrifugal acceleration using a centrifuge microscope of the stroboscopic type. Cytoplasmic streaming in the plasmodium was greatly affected by changes in the acceleration. The endoplasmic flow in the centrifugal direction was accelerated, while that in the centripetal was retarded, by centrifugal acceleration. The centrifugal acceleration required to stop the endoplasmic flow in the centripetal direction did not cause total cessation of streaming but always induced a bidirectional flow of endoplasm in one and the same strand. Each profile of velocity distribution of the bidirectional flow was both parabola with flattened apex. One possible cause of the bidirectional flow is discussed.Dedicated to Emeritus Professor Noburo Kamiya on the occasion of his 80th birthday     

Reversal of motory polarity ofAmoeba proteus by suction

Summary When a glass capillary is introduced into the posterior body region ofA. proteus and its orifice is maintained inside the flowing mass of endoplasm, an applied suction force invariably initiates the reversal of streaming direction. This initial effect depends as well on the negative pressure value as on the terminal diameter of the pipette. Further transformations of configuration of pseudopodia are due to mixed effects of the direct application of sucking force and of the active response of amoeba to the new situation. When the sucking pipettes are applied to the outer cell surface, probably only a fraction of the negative pressure may be transmitted to the cell interior. The portion of cell periphery exposed to negative pressure acting from outside is still capable to contract. As a result, when amoeba as a whole is progressively sucked into the capillary, it manifests a clear active escape behaviour.Study supported by the Research Project II. 1 of the Polish Academy of Science.     

Effect of supraoptimal temperatures on the function of the subcortical fibrils and an endoplasmic factor inNitella internodes

Summary The effect of supraoptimal temperatures onNitella cells was studied with special reference to the function of subcortical fibrils and an endoplasmic factor. Local heat-treatment (50 °C for 1 minute) of an internodal cell ofNitella disclosed that 1. the subcortical fibrils in the treated area remain normal, not affected by the treatment, 2. the subcortical fibrils alone produce no cytoplasmic streaming, 3. the endoplasm contains an extremely heat-labile factor which is indispensable for streaming, and 4. the stagnant endoplasm in the heat-treated area is neither coagulated nor gelated by heat.Preliminary reports appeared in Proc. 37th Annu. Meet. Bot. Soc. Jpn. P. 160 (1972, in Japanese) and in Abst. Annu. Meet. Jpn. Soc. Cell Biol. p. 57 (1975, in Japanese).     

An Anterior-Posterior Gradient of Refractive Index in the Ameba and Its Significance in Ameboid Movement

Sustained locomotion in Amoeba proteus and Amoeba dubia results in the establishment of a measureable gradient of refractive index along the anterior-posterior axis of the cell, provided thickness of the specimens is kept constant by even compression under a selected coverglass supported by quartz beams of uniform diameter. The tail region of the ameba develops a higher refractive index, indicative of from 6 to 40 per cent more organic matter (expressed as protein) there than present in the front. This gradient fades on cessation of movement. The average protein concentrations in the crystal-free tails and fronts of 15 A. proteus were 3.9 and 3.4 per cent, respectively. In individual experiments, the tail-front difference ranged from one to eight times the accuracy of the method. Since the gradient of refractive index was shown not to result from extraction of water from the tail by the contractile vacuole, it was interpreted as displacement of water toward the anterior part of the cell during movement. It is suggested that contraction of the ectoplasm drives forward a "tide" of syncretic fluid, the anterior border of which is visible as the hyaline cap, which contains less than 1 per cent protein. The movement of the granular endoplasm into the hyaline cap would then complete the cycle by imbibition of the fluid tide. The theoretical positions of Pantin and of Dellinger have been combined in the proposal that ameba cytoplasm consists of a network of a contractile phase which is able to expel (by syneresis) a highly mobile fluid phase. Some other possible interpretations are discussed.