Active movement in vitro of bundle of microfilaments isolated from Nitella cell

Subcortical fibrils composed of bundles of F-actin filaments and endoplasmic filaments are responsible for endoplasmic streaming. It is reported here that these fibrils and filaments move actively in an artificial medium containing Mg-ATP and sucrose at neutral pH, when the medium was added to the cytoplasm squeezed out of the cell. The movement was observed by phase-contrast microscopy or dark-field microscopy and recorded on 16-mm film. Chains of chloroplasts linked by subcortical fibrils showed translational movement in the medium. Even after all chloroplasts and the endoplasm were washed away by perfusion with fresh medium, free fibrils and/or filaments (henceforth, referred to as fibers) not attached to chloroplasts continued travelling in the direction of the fiber orientation. Sometimes the fibers formed rings and rotated. Chloroplast chains and free fibers or rings continued moving for 5-30 min at about half the rate of the endoplasmic streaming in vivo. Calcium ion concentrations < 10(-7) M permitted movement to take place. Electron microscopy revealed that both fibers and rings were bundles of F-actin filaments that showed the same polarity after decoration with heavy meromyosin.     

Actin in living and fixed characean internodal cells: identification of a cortical array of fine actin strands and chloroplast actin rings

Summary We report on the novel features of the actin cytoskeleton and its development in characean internodal cells. Images obtained by confocal laser scanning microscopy after microinjection of living cells with fluorescent derivatives of F-actin-specific phallotoxins, and by modified immunofluorescence methods using fixed cells, were mutually confirmatory at all stages of internodal cell growth. The microinjection method allowed capture of 3-dimensional images of high quality even though photobleaching and apparent loss of the probes through degradation and uptake into the vacuole made it difficult to record phallotoxin-labelled actin over long periods of time. When injected at appropriate concentrations, phallotoxins affected neither the rate of cytoplasmic streaming nor the long-term viability of cells. Recently formed internodal cells have relatively disorganized actin bundles that become oriented in the subcortical cytoplasm approximately parallel to the newly established long axis and traverse the cell through transvacuolar strands. In older cells with central vacuoles not traversed by cytoplasmic strands, subcortical bundles are organized in parallel groups that associate closely with stationary chloroplasts, now in files. The parallel arrangement and continuity of actin bundles is maintained where they pass round nodal regions of the cell, even in the absence of chloroplast files. This study reports on two novel structural features of the characean internodal actin cytoskeleton: a distinct array of actin strands near the plasma membrane that is oriented transversely during cell growth and rings of actin around the chloroplasts bordering the neutral line, the zone that separates opposing flows of endoplasm.     

Wide-ranging effects of eight cytochalasins and latrunculin A and B on intracellular motility and actin filament reorganization in characean internodal cells

Numerous forms of cytochalasins have been identified and, although they share common biological activity, they may differ considerably in potency. We investigated the effects of cytochalasins A, B, C, D, E, H and J and dihydrocytochalasin B in an ideal experimental system for cell motility, the giant internodal cells of the characean alga Nitella pseudoflabellata. Cytochalasins D (60 microM) and H (30 microM) were found to be most suited for fast and reversible inhibition of actin-based motility, while cytochalasins A and E arrested streaming at lower concentrations but irreversibly. We observed no clear correlation between the ability of cytochalasins to inhibit motility and the actual disruption of the subcortical actin bundle tracks on which myosin-dependent motility occurs. Indeed, the actin bundles remained intact at the time of streaming cessation and disassembled only after one to several days' treatment. Even when applied at concentrations lower than that required to inhibit cytoplasmic streaming, all of the cytochalasins induced reorganization of the more labile cortical actin filaments into actin patches, swirling clusters or short rods. Latrunculins A and B arrested streaming only after disrupting the subcortical actin bundles, a process requiring relatively high concentrations (200 microM) and very long treatment periods of >1 d. Latrunculins, however, worked synergistically with cytochalasins. A 1 h treatment with 15 nM latrunculin A and 4 microM cytochalasin D induced reversible fragmentation of subcortical actin bundles and arrested cytoplasmic streaming. Our findings provide insights into the mechanisms by which cytochalasins and latrunculins interfere with characean actin to inhibit motility.     

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     

Identification of a birefringent structure which appears and disappears in accordance with the shuttle streaming inPhysarum plasmodia

Summary R-HMM (rhodamine-heavy meromyosin) stained the birefringent fibrous structure which appears and disappears cyclically in parallel with the periodic shuttle streaming in the plasmodium ofPhysarum polycephalum. In addition, 0.6 M KI readily made the birefringent fibrils fade away. These results clearly show that the birefringent fibrils are composed of actin filaments and prove the possibility of actin filaments to alter in the aggregation state during the cyclic production of the motive force responsible for the cytoplasmic streaming.     

Cytochalasin Rearranges Cortical Actin of the Alga Nitella into Short, Stable Rods

The cortical cytoplasm of the alga Nitella contains reticulateactin that does not survive perfusion fixation with glutaraldehydeunless prestabilized with the cross-linker 3-maleimidobenzoyl-N-hydroxysuccinimidester (MBS). Cytochalasin D remodels thiscortical actin into short rods which are more stable, survivingaldehyde fixation without MBS pre-treatment. The overall alignmentof these actin rods correlates with that of cortical microtubules(transverse in young cells, random in old cells) but probablydoes not involve one-to-one correspondence. The time course,dose dependence and reversibility of these structural changesbroadly resemble those for streaming inhibition by cytochalasinbut the cortical actin responds to concentrations that do notslow streaming. Because the structural changes concern the corticaland not the subcortical actin, they seem unlikely to directlyinhibit streaming. Formation of cortical rods is not a responseto streaming inhibition per se since it does not occur whentwo other inhibitors of streaming (2,4-dinitrophenol (DNP) andNethyl maleimide (NEM)) are used. NEM, however, resembles MBSin stabilizing the reticulate form of cortical actin even thoughit cannot cross link. ¹Address from July 1995; Department of Biology, Faculty of Science,Osaka University, Machikaneyama 1-1, Tayonaka, Osaka, 560 Japan.     

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).     

Myosin and Ca2+-sensitive streaming in the alga Chara: detection of two polypeptides reacting with a monoclonal anti-myosin and their localization in the streaming endoplasm

A monoclonal antibody to the heavy chain of myosin from mouse 3T3 cells was used to detect and localize related proteins in the green alga Chara. Proteins of 200,000 and 110,000 Mr reacted on immunoblots of proteins precipitated rapidly with trichloroacetic acid to minimize proteolysis. Immunofluorescence of whole cells localized these proteins to organelles of the streaming endoplasm, to a system of endoplasmic strands and to the subcortical actin bundles. Except that fewer endoplasmic strands and organelles were found and the strands were tangled, the localization pattern was similar in cells rapidly perfused to remove the bulk of the streaming endoplasm. Actin was confined almost entirely to the system of subcortical actin bundles in both whole and perfused cells. Myosin that was associated with the tangled endoplasmic strands but not that associated with the organelles or actin bundles was removed by concentrations of Ca2+ inhibiting ATP-dependent streaming in perfused cells. ATP extracted both organelles and endoplasmic strands but left a continuous pattern of myosin immunostaining along the actin bundles. The findings are discussed in relation to the possible existence of two forms of myosin and of separate mechanisms moving the bulk endoplasm and individual organelles.     

Fluorescence studies on modes of cytochalasin B and phallotoxin action on cytoplasmic streaming in Chara

Various investigations have suggested that cytoplasmic streaming in characean algae is driven by interaction between subcortical actin bundles and endoplasmic myosin. To further test this hypothesis, we have perfused cytotoxic actin-binding drugs and fluorescent actin labels into the cytoplasm of streaming Chara cells. Confirming earlier work, we find that cytochalasin B (CB) reversibly inhibits streaming. In direct contrast to earlier investigators, who have found phalloidin to be a potent inhibitor of movement in amoeba, slime mold, and fibroblastic cells, we find that phalloidin does not inhibit streaming in Chara but does modify the inhibitory effect of CB. Use of two fluorescent actin probes, fluorescein, isothiocyanate-heavy meromyosin (FITC-HMM) and nitrobenzoxadiazole-phallacidin (NBD-Ph), has permitted visualization of the effects of CB and phalloidin on the actin bundles. FITC-HMM labeling in perfused but nonstreaming cells has revealed a previously unobserved alteration of the actin bundles by CB. Phalloidin alone does not perceptibly alter the actin bundles but does block the alteration by CB if applied as a pretreatment, NBD-Ph perfused into the cytoplasm of streaming cells stains actin bundles without inhibiting streaming. NBD-Ph staining of actin bundles is not initially observed in cells inhibited by CB but does appear simultaneously with the recovery of streaming as CB leaks from the cells. The observations reported here are consistent with the established effects of phallotoxins and CB on actin in vitro and support the hypothesis that streaming is generated by actin-myosin interactions.     

Actin-organelle interaction: association with chloroplast in arabidopsis leaf mesophyll cells.

The role of the cytoskeleton in the regulation of chloroplast motility and positioning has been investigated by studying: (1) structural relationship of actin microfilaments, microtubules, and chloroplasts in cryofixed and freeze-substituted leaf cells of Arabidopsis; and (2) the effects of anti-actin (Latrunculin B; LAT-B) and anti-microtubule (Oryzalin) drugs on intracellular distribution of chloroplasts. Immunolabeling of leaf cells with two plant-actin specific antibodies, which react equivalently with all the expressed Arabidopsis actins, revealed two arrangements of actin microfilaments: longitudinal arrays of thick actin bundles and randomly oriented thin actin filaments that extended from the bundles. Chloroplasts were either aligned along the actin bundles or closely associated with the fine filaments. Baskets of actin microfilaments were also observed around the chloroplasts. The leaf cells labeled with an anti-tubulin antibody showed dense transverse arrays of cortical microtubules that exhibited no apparent association with chloroplasts. The application of LAT-B severely disrupted actin filaments and their association with chloroplasts. In addition, LAT-B induced aberrant aggregation of chloroplasts in the mesophyll and bundle sheath cells. Double labeling of LAT-B treated cells with anti-actin and anti-tubulin antibodies revealed that the microtubules in these cells were unaffected. Moreover, depolymerization of microtubules with Oryzalin did not affect the distribution of chloroplasts. These results provide evidence for the involvement of actin, but not tubulin, in the movement and positioning of chloroplasts in leaf cells. We propose that using motor molecules, some chloroplasts migrate along the actin cables directly, while others are pulled along the cables by the fine actin filaments. The baskets of microfilaments may anchor the chloroplasts during streaming and allow control over proper three-dimensional orientation to light.     

Effects of exogenous proteins on cytoplasmic streaming in perfused Chara cells

Cytoplasmic streaming in characean algae is thought to be generated by interaction between subcortical actin bundles and endoplasmic myosin. Most of the existing evidence supporting this hypothesis is of a structural rather than functional nature. To obtain evidence bearing on the possible function of actin and myosin in streaming, we used perfusion techniques to introduce a number of contractile and related proteins into the cytoplasm of streaming Chara cells. Exogenous actin added at concentrations as low as 0.1 mg/ml is a potent inhibitor of streaming. Deoxyribonuclease I (DNase I), an inhibitor of amoeboid movement and fast axonal transport, does not inhibit streaming in Chara. Fluorescein-DNase I stains stress cables and microfilaments in mammalian cells but does not bind to Chara actin bundles, thus suggesting that the lack of effect on streaming is due to a surprising lack of DNase I affinity for Chara actin bundles. Heavy meromyosin (HMM) does not inhibit streaming, but fluorescein-HMM (FL-HMM), having a partially disabled EDTA ATPase, does. Quantitative fluorescence micrography provides evidence that inhibition of streaming by FL-HMM may be due to a tendency for FL-HMM to remain bound to Chara actin bundles even in the presence of MgATP. Perfusion with various control proteins, including tubulin, ovalbumin, bovine serum albumin, and irrelevant antibodies, does not inhibit streaming. These results support the hypothesis that actin and myosin function to generate cytoplasmic streaming in Chara.     

A cytochalasin-sensitive actin filament meshwork is a prerequisite for local wound wall deposition inNitella internodal cells

Summary Reorganization of the actin cytoskeleton following cell wall puncturing of characean internodal cells was studied by immunofluorescence and confocal laser scanning microscopy. Injury locally destroyed the parallel subcortical actin filament bundles and cortical actin strands that are characteristic of unwounded regions. At wounds, a delicate three-dimensional interlaced structure of actin strands, with meshes up to 5 m wide, formed by de novo assembly of isolated filaments and by the elongation of residual subcortical actin bundles and cortical actin strands. The actin meshwork persisted for up to 2 h, corresponding to the duration of intense wound wall secretion. Actin filament bundles continuous with the subcortical bundles outside the wound then regenerated, their parallel alignment probably assisted by endoplasmic flow. Cytochalasin D concentrations that arrested cytoplasmic streaming completely inhibited the formation of the actin meshwork, wound wall deposition and recovery of actin bundles. Concentrations that only reduced streaming velocity delayed meshwork formation and wound walls were thinner than in controls. The actual amount of F-actin within the meshwork, however, was clearly greater in the presence of low cytochalasin concentrations. In late stages of recovery, the actin bundles became very thick and intervening spaces became wider thereby forming a conspicuous, three-dimensional lattice that was continuous with interwebbing subcortical bundles and cortical actin around the periphery of the wound. Our experiments suggest that actin meshwork formation is a prerequisite for plasma membrane-directed transport of vesicles involved in wounding-induced exocytosis in characean internodes. Stabilization of the meshwork by subinhibitory concentrations of cytochalasin D is probably caused by actinbinding properties of the drug that either induce bundling or impede function of associated proteins.Abbreviations AFW artificial fresh water - BSA bovine serum albumin - CLSM confocal laser scanning microscope (microscopy) - DIC differential interference contrast - DMSO dimethyl sulfoxide - FITC fluorescein isothiocyanate - MBS m-maleimidobenzoyl N-hydroxy-succinimide ester - PBS phosphate-buffered saline - SCAB subcortical actin bundle     

Actin-microtubule interactions in the algaNitella: analysis of the mechanism by which microtubule depolymerization potentiates cytochalasin's effects on streaming

Summary In the characean algaNitella, depolymerization of microtubules potentiates the inhibitory effects of cytochalasins on cytoplasmic streaming. Microtubule depolymerization lowers the cytochalasin B and D concentrations required to inhibit streaming, accelerates inhibition and delays streaming recovery. Because microtubule depolymerization does not significantly alter³H-cytochalasin B uptake and release, elevated intracellular cytochalasin concentrations are not the basis for potentiation. Instead, microtubule depolymerization causes actin to become more sensitive to cytochalasin. This increased sensitivity of actin is unlikely to be due to direct stabilization of actin by microtubules, however, because very few microtubules colocalize with the subcortical actin bundles that generate streaming. Furthermore, microtubule reassembly, but not recovery of former transverse alignment, is sufficient for restoring the normal cellular responses to cytochalasin D. We hypothesize that either tubulin or microtubule-associated proteins, released when microtubules depolymerize, interact with the actin cytoskeleton and sensitize it to cytochalasin.Abbreviations APW artificial pond water - Ca_c cytoplasraic free calcium concentration - DMSO dimethyl sulfoxide - MT microtubule-minus - MT+ microtubule-plus.     

Hydrodynamic models of viscous coupling between motile myosin and endoplasm in characean algae

Cytoplasmic streaming in characean algae is thought to be driven by interaction between stationary subcortical actin bundles and motile endoplasmic myosin. Implicit in this mechanism is a requirement for some form of coupling to transfer motive force from the moving myosin to the endoplasm. Three models of viscous coupling between myosin and endoplasm are presented here, and the hydrodynamic feasibility of each model is analyzed. The results show that individual myosinlike molecules moving along the actin bundles at reasonable velocities cannot exert enough viscous pull on the endoplasm to account for the observed streaming. Attachment of myosin to small spherical organelles improves viscous coupling to the endoplasm, but results for this model show that streaming can be generated only if the myosin-spheres move along the actin bundles in a virtual solid line at about twice the streaming velocity. In the third model, myosin is incorporated into a fibrous or membranous network or gel extending into the endoplasm. This network is pulled forward as the attached myosin slides along the actin bundles. Using network dimensions estimated from published micrographs of characean endoplasm, the results show that this system can easily generate the observed cytoplasmic streaming.     

Microtubule disassembly enhances reversible cytochalasin-dependent disruption of actin bundles in characean internodes

Summary Parallel bundles of actin filaments at the cortex-endoplasm interface provide tracks for myosin-generated cytoplasmic streaming in characean internodes. These bundles resist disassembly or structural modification when exposed to 10 μM cytochalasin D (CD) even though this concentration of CD rapidly (within minutes) but reversibly arrests streaming. Unexpectedly, we discovered that prolonged treatment with lower concentrations of CD could partially disassemble the subcortical actin bundles. Actin bundles became discontinuous following one- to several-day treatment with concentrations (6 μM) that reduced but did not arrest streaming, and the residual fragments mostly remained parallel to the chloroplast files. When microtubules were concurrently disassembled with tubulin-specific drugs, however, low CD concentrations (2.5–3 μM) completely arrested bulk streaming, disrupted the largely 2-dimensional actin bundle array and caused the formation of a coarse, thick-meshed actin network that extended from the cortex to the endoplasm. Despite such massive reconstruction, drug removal enabled cells to recover continuous parallel bundles and streaming. Recovery was possible if both or just one of the drugs were removed. In recovered cells, the streaming pattern frequently redeveloped in new directions that did not follow the chloroplast files, and later, chloroplast files readjusted to the new polarity established by the actin bundles. This first report on the complete and reversible disassembly of characean actin bundles provides new insights into the mechanism of actin bundle assembly and organization and supports the idea of indirect interactions between actin filaments and microtubules.     

Actin-endoplasmic reticulum complexes inDrosera

In epidermal cells ofDrosera tentacles that have been preserved for ultrastructural analysis through high pressure freeze fixation and freeze substitution we describe the frequent occurrence of microfilament (MF)-endoplasmic reticulum (ER) complexes. These are found throughout the cytoplasm where they are observed in close association with the plasmalemma (PL), the tonoplast, nuclei, mitochondria, chloroplasts, and microbodies. The MF component of the complexes is identified as actin based on immunogold labelling with actin antibodies. The actin-ER complexes are prominent in the cortical cytoplasm. In this region a network of predominantly tubular ER occupies an intermediary position in which it associates closely with both the PL and the actin MFs. We suggest that the ER, especially those elements adjacent to the PL in the cortical cytoplasm, stabilizes the actin MFs and provides the necessary anchor against which the forces for cytoplasmic streaming are generated.Abbreviations CF chemical fixation - ER endoplasmic reticulum - FS freeze substitution - HPF high pressure freezing - MF microfilaments - MT microtubules - PL plasmalemma     

THE CHANGING PATTERN OF BIREFRINGENCE IN PLASMODIA OF THE SLIME MOLD, PHYSARUM POLYCEPHALUM

Plasmodia of the acellular slime mold, Physarum polycephalum, reveal a complex and changing pattern of birefringence when examined with a sensitive polarizing microscope. Positively birefringent fibrils are found throughout the ectoplasmic region of the plasmodium. In the larger strands they may be oriented parallel to the strand axis, or arranged circularly or spirally along the periphery of endoplasmic channels. Some fibrils exist for only a few minutes, others for a longer period. Some, particularly the circular fibrils, undergo changes in birefringence as they undergo cyclic deformations. In the ramifying strand region and the advancing margin there is a tendency for fibrils of various sizes to become organized into mutually orthogonal arrays. In some plasmodia the channel wall material immediately adjacent to the endoplasm has been found to be birefringent. The sign of endoplasmic birefringence is negative, and its magnitude is apparently constant over the streaming cycle. The pattern of plasmodial birefringence and its changes during the shuttle streaming cycle of Physarum are considered in the light of several models designed to explain either cytoplasmic streaming alone or the entire gamut of plasmodial motions. The results of this and other recent physical studies suggest that both streaming and the various other motions of the plasmodium may very likely be explained in terms of coordinated contractions taking place in the fibrils which are rendered visible in polarized light.     

Microtubules at wound sites of Nitella internodal cells passively co-align with actin bundles when exposed to hydrodynamic forces generated by cytoplasmic streaming

The organization of cortical microtubules at wound sites in Nitella pseudoflabellata(A. Br. & Nordst.) em. R.D.W. and N. flexilis(L.) Ag. internodal cells was examined in relation to the regeneration of actin filament bundles in order to identify the mechanisms by which microtubules are oriented. Actin bundle regrowth occurs prior to that of microtubules, so it was considered possible that microtubule alignment is actin-dependent, perhaps mediated by cross-linking proteins. In all types of wounds investigated, subcortical actin bundles regenerated parallel to the direction of cytoplasmic streaming. Microtubule orientation patterns, however, varied according to the nature of wound formation and the type of wound wall eventually produced. In chloroplast-free windows induced by blue light irradiation, microtubule orientation varied according to the size of the window. Microtubules were randomized in 10- to 30-μm-wide windows where exposure to cytoplasmic flow is minimal, but were aligned more or less parallel to regenerated actin bundles in 80- to 100-μm-wide windows. Where co-alignment between microtubules and actin bundles was obvious after fluorescence labelling, electron micrographs revealed that microtubules and actin bundles were too widely spaced to account for any cross-linkages. Furthermore, treatments that inhibited or reduced cytoplasmic streaming without altering the direction of actin bundles caused randomization of microtubules previously oriented in the streaming direction, even in the presence of taxol. When evenly flat wound walls were induced by 10⁻⁴ M chlortetracycline, microtubules were co-aligned with nearby actin bundles at the surface of the wound wall. At wounds induced by treatment with 5 × 10⁻² M CaCl₂, however, microtubules were randomly oriented and preferentially located in the narrow clefts between the wound-wall protuberances, up to several micrometers away from the actin bundles near the wound-wall tips. These results indicate that microtubules regenerated in wounds are merely co-aligned with actin filament bundles because they are passively aligned by the hydrodynamic forces created by cytoplasmic flow. Received: 4 August 1998 / Accepted: 30 January 1999     

Dynamic aspects of the contractile system in Physarum plasmodium. III. Cyclic contraction-relaxation of the plasmodial fragment in accordance with the generation-degeneration of cytoplasmic actomyosin fibrils

Plasmodial fragments of Physarum polycephalum, excised from anterior regions of a thin-spread plasmodium, contracted-relaxed cyclicly with a period of 3-5 min. The area of the fragments decreased approximately 10% during contraction. In most cases, there was little endoplasmic streaming which indicates that contractions were synchronized throughout the fragment. By both polarized light and fluorescence microscopy, the organization and distribution of the cytoplasmic actomyosin fibrils in the fragments changed in synchrony with the contraction cycle. The fibrils formed during the contraction phase, and finally became a highly organized framework consisting of a three-dimensional network of numerous fibrils with many converging points (the nodes). During relaxation, the fibrils degenerated and disappeared almost completely, though some very weak fibrils remained near the nodes and the periphery. The results obtained by fluorometry of the fragments, stained with rhodamine-phalloidin, suggested that the G-F transformation of actin is not the main underlying process of the fibrillar formation.     

Immobilisation of organelles and actin bundles in the cortical cytoplasm of the alga Chara corallina Klein ex. Wild

The mechanism by which sub-cortical actin bundles and membranous organelles are immobilised in the cortical cytoplasm of the alga Chara was studied by perfusing cells with a solution containing 1% Triton X-100. Light and scanning electron microscopy and the release of starch grains and chlorophyll-protein complexes indicated that the detergent extensively solubilised the chloroplasts. However, the sub-cortical actin bundles remained in situ even though they were originally separated from the plasma membrane by the chloroplasts. A fibrous layer between chloroplasts and plasma membrane became readily visible after detergent extraction of the cells and could be released by low-ionic-strength ethylenediaminetetraacetic acid, thioglycollate and trypsin. The same treatments applied to cells not subject to detergent extraction released the membrane-bound organelles and actin bundles and no fibrous meshwork was visible on subsequent extraction with Triton. It is, therefore, concluded that a detergent-insoluble cortical cytoskeleton exists and contributes to the immobility of the actin and cortical organelles in the cells.Abbreviation EDTA ethylenediaminetetraacetic acid