Possible involvement of protein phosphorylation in the regulation of cytoplasmic organization and streaming in root hair cells as revealed by a protein phosphatase inhibitor, calyculin A

Summary The effects of a protein phosphatase inhibitor, calyculin A (CA), on cytoplasmic streaming and cytoplasmic organization were examined in root hair cells ofLimnobium stoloniferum. CA at concentrations higher than 50 nM inhibited cytoplasmic streaming and also induced remarkable morphological changes in the cytoplasm. The transvacuolar strands, in which actin filament bundles were oriented parallel to the long axis, disappeared and spherical cytoplasmic bodies emerged in the CA-treated cells. In these spherical bodies, actin filaments were present and the spherical bodies were connected to each other by thin strands of actin filaments. Upon CA removal, transvacuolar strands, in which actin filament bundles were aligned, and cytoplasmic streaming reappeared. A nonselective inhibitor for protein kinases, K-252a, delayed the inhibitory effect of CA on cytoplasmic streaming and suppressed the CA-induced formation of the spherical bodies. From these results, it is suggested that phosphatases sensitive to CA regulate cytoplasmic streaming and are involved in the organization of the cytoplasm in root hair cells.Abbreviations APW artificial pond water - CA calyculin A     

Rotational streaming in fiber cells and its role in translocation

All visible protoplasmic streaming in sections of various plant stems was reversibly stopped by 2,4-dinitrophenol (DNP). Sections contained epidermal, cortical, and fiber cell types. Cells treated with DNP retained their semipermeability as evidenced by their plasmolysis in sucrose solutions. Washing out the DNP resulted in the rapid resumption of protoplasmic streaming in all 3 cell types. Both the rate of movement of sodium fluorescein and the shape of the advancing dye front were greatly altered by DNP treatment. Dye transport was decreased in the fibers and little affected in cortical cells. The results suggest that rotational streaming accelerates the translocation of soluble substances in fiber cells.     

Variation in velocity of cytoplasmic streaming and gravity effect in characean internodal cells measured by laser-Doppler-velocimetry

Summary Velocities of cytoplasmic streaming were measured in internodal cells ofNitella flexilis L. andChara corallina Klein ex Willd. by laser-Doppler-velocimetry to investigate the possibility of non-statolith-based perception of gravity. This was recently proposed, based on a report of gravity-dependent polarity of cytoplasmic streaming. Our measurements revealed large spatial and temporal variation in streaming velocity within a cell, independent of the position of the cell with respect to the direction of gravity. In 58% of the horizontally positioned cells the velocities of acropetal and basipetal streaming, measured at opposite locations in the cell, differed significantly. In 45% of these, basipetal streaming was faster than acropetal streaming. In 60% of the vertically positioned cells however the difference was significant, downward streaming was faster in only 61% of these. When cell positions were changed from vertical to horizontal and vice versa the cells reacted variably. A significant difference between velocities in one direction, before and after the change, was observed in approx. 70% of the measurements, but the velocity was faster in the downward direction, as the second position, in only 70% of the significantly different. The ratio of basipetal to acropetal streaming velocities at opposite locations of a cell was quite variable within groups of cells with a particular orientation (horizontal, normal vertical, inverted vertical). On average, however, the ratio was close to 1.00 in the horizontal position and approx. 1.03 in the normal vertical position (basipetal streaming directed downwards), which indicates a small direct effect of gravity on streaming velocity. Individual cells, however, showed an increased, as well as a decreased, ratio when moved from the horizontal to the vertical position. No discernible effect of media (either Ca^{2 +}-buffered medium or 1.2% agar in distilled water) on the streaming velocities was observed. The above mentioned phenomenon of graviperception is not supported by our data.Abbreviations g gravitational acceleration (9.81 m/s²) - LDV laser-Doppler-velocimetry - VR velocity ratio Dedicated to Professor Peter Sitte on the occasion of his 65th birthday     

The mechanism of cytoplasmic streaming in characean algal cells: sliding of endoplasmic reticulum along actin filaments

Electron microscopy of directly frozen giant cells of characean algae shows a continuous, tridimensional network of anastomosing tubes and cisternae of rough endoplasmic reticulum which pervade the streaming region of their cytoplasm. Portions of this endoplasmic reticulum contact the parallel bundles of actin filaments at the interface with the stationary cortical cytoplasm. Mitochondria, glycosomes, and other small cytoplasmic organelles enmeshed in the endoplasmic reticulum network display Brownian motion while streaming. The binding and sliding of endoplasmic reticulum membranes along actin cables can also be directly visualized after the cytoplasm of these cells is dissociated in a buffer containing ATP. The shear forces produced at the interface with the dissociated actin cables move large aggregates of endoplasmic reticulum and other organelles. The combination of fast-freezing electron microscopy and video microscopy of living cells and dissociated cytoplasm demonstrates that the cytoplasmic streaming depends on endoplasmic reticulum membranes sliding along the stationary actin cables. Thus, the continuous network of endoplasmic reticulum provides a means of exerting motive forces on cytoplasm deep inside the cell distant from the cortical actin cables where the motive force is generated.     

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.     

Osmotic induction of fluid-phase endocytosis in onion epidermal cells

A transient plasmolysis/deplasmolysis (plasmolytic cycle) of onion epidermal cells has been shown to induce the formation of fluid-phase endocytic vesicles. Plasmolysis in the presence of the membrane-impermeant fluorescent probes Lucifer Yellow CH (LYCH) and Cascade Blue hydrazide resulted in the uptake of these probes by fluid-phase endocytosis. Following deplasmolysis, many of the dye-containing vesicles left their parietal positions within the cell and underwent vigorous streaming in the cytoplasm. Vesicles were observed to move within transvacuolar strands and their movements were recorded over several hours by video-microscopy. Within 2 h of deplasmolysis several of the larger endocytic vesicles had clustered around the nuclear membrane, apparently lodged in the narrow zone of cytoplams surrounding the nucleus. In further experiments LYCH was endocytically loaded into the cells during the first plasmolytic cycle and Cascade Blue subsequently loaded during a second plasmolytic cycle. This resulted in the introduction of two populations of endocytic vesicles into the cells, each containing a different probe. Both sets of vesicles underwent cytoplasmic streaming. The data are discussed in the light of previous observations of fluid-phase endocytosis in plant cells.     

Cyclic longitudinal fibrillar motion as a basis for steady rotational protoplasmic streaming

The simple rhythmic motion of protoplasm back and forth along microfilaments sited at the active boundary of the streaming layer of Nitellais conjectured as a possible mechanism for the motive force for protoplasmic streaming. A theoretical model is set up to illustrate the process and estimate appropriate values for time scales and velocities of such oscillations to mantain streaming velocities of the order of those measured in these cells.     

Reorganization of the cytoskeleton during Drosophila oogenesis: implications for axis specification and intercellular transport.

Inhibitor studies have implicated microtubules in at least three important developmental processes during Drosophila oogenesis: oocyte determination and growth during stages 1 through 6, positioning of the anterior determinant bicoid mRNA during stages 9 through 12, and ooplasmic streaming during stages 10b through 12. We have used fluorescence cytochemistry together with laser scanning confocal microscopy to identify distinct microtubule structures at each of the above three periods that are likely to be involved in these processes. During stages 1 through 7, maternal components synthesized in nurse cells are transported through cytoplasmic bridges to the oocyte. At this time, microtubules that appear to originate in the oocyte pass through these cytoplasmic bridges into the adjacent nurse cells; these microtubules are likely to serve as a polarized scaffold on which maternal RNAs and proteins are transported. During stages 7 and 8, microtubules in the oocyte cortex reorganize to form an anterior-to-posterior gradient, suggesting a role for microtubules in the localization of morphogenetic determinants. Finally, when ooplasmic streaming begins during stage 10 b, it is accompanied by the assembly of subsurface microtubule arrays that spiral around the oocyte; these arrays disassemble as the oocyte matures and streaming stops. During ooplasmic streaming, many vesicles are closely associated with the subsurface microtubules, suggesting that streaming is driven by vesicle translocation along microtubules. We believe that actin plays a secondary role in each of these morphogenetic events, based on our parallel studies of actin organization during each of the above stages of oogenesis.     

The significance of Ca2+ in the morphogenesis of Micrasterias studied with EGTA,verapamil, LaCl3 and calcium ionophore A 23187

The significance of Ca²⁺ in the morphogenesis of Micrasterias torreyi Bail. cells (grown in calcium-containing medium) was studied using the calcium chelating agent EGTA, the Ca²⁺ influx inhibitors verapamil and LaCl₃, and the calcium ionophore A 23187. In the experiments where the first three were used, it was possible to find a rather concise concentration area within which the growth and development of dividing cells were prevented, but where the cells remained alive and were capable of continuing their differentiation when moved into fresh medium. Cytoplasmic streaming and especially the cortical streaming system inside the cells was also disturbed or prevented during the action of these drugs. Higher concentrations caused the bursting of the treated cells, and even very low concentrations were able to inhibit the division of interphase cells. Ionophore A 23187 slowed down or prevented development, but, unlike the other drugs, accelerated the streamings and stimulated the division rhythm of interphase cells. The results support the hypothesis that Ca²⁺ influx through the plasma membrane affects and guides, during cell growth and development, the fusion of dictyosome vesicles, containing cell wall material, with the plasma membrane. They also indicate the importance of cortical cytoplasmic streamings in growth and differentiation, as well as the idea that the streaming is supported by actin microfilaments.     

Arabidopsis Formin3 Directs the Formation of Actin Cables and Polarized Growth in Pollen Tubes

Cytoplasmic actin cables are the most prominent actin structures in plant cells, but the molecular mechanism underlying their formation is unknown. The function of these actin cables, which are proposed to modulate cytoplasmic streaming and intracellular movement of many organelles in plants, has not been studied by genetic means. Here, we show that Arabidopsis thaliana formin3 (AFH3) is an actin nucleation factor responsible for the formation of longitudinal actin cables in pollen tubes. The Arabidopsis AFH3 gene encodes a 785–amino acid polypeptide, which contains a formin homology 1 (FH1) and a FH2 domain. In vitro analysis revealed that the AFH3 FH1FH2 domains interact with the barbed end of actin filaments and have actin nucleation activity in the presence of G-actin or G actin-profilin. Overexpression of AFH3 in tobacco (Nicotiana tabacum) pollen tubes induced excessive actin cables, which extended into the tubes'' apices. Specific downregulation of AFH3 eliminated actin cables in Arabidopsis pollen tubes and reduced the level of actin polymers in pollen grains. This led to the disruption of the reverse fountain streaming pattern in pollen tubes, confirming a role for actin cables in the regulation of cytoplasmic streaming. Furthermore, these tubes became wide and short and swelled at their tips, suggesting that actin cables may regulate growth polarity in pollen tubes. Thus, AFH3 regulates the formation of actin cables, which are important for cytoplasmic streaming and polarized growth in pollen tubes.     

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.     

Study of cytoplasm streaming as a cytophysiological method in radiolabeled experiment

Estimation of influence of ionizing radiation, high-frequency electromagnetic radiation and their combined action on a higher water plant Elodea canadensis has been carried out using cytophysiological method of determination of the cytoplasm streaming rate. It was shown that low-intensive electromagnetic radiation modifies reaction of the differentiated cells on radiolesion. The rate of cytoplasm streaming can be used as an informative characteristic of plant cell state in radiobiological experiment.     

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.     

Microtubules regulate the organization of actin filaments at the cortical region in root hair cells ofHydrocharis

Summary We studied the mechanism controlling the organization of actin filaments (AFs) inHydrocharis root hair cells, in which reverse fountain streaming occurs. The distribution of AFs and microtubules (MTs) in root hair cells were analyzed by fluorescence microscopy and electron microscopy. AFs and MTs were found running in the longitudinal direction of the cell at the cortical region. AFs were observed in the transvacuolar strand, but not MTs. Ultrastructural studies revealed that AFs and MTs were colocalized and that MTs were closer to the plasma membrane than AFs. To examine if MTs regulate the organization of AFs, we carried out a double inhibitor experiment using cytochalasin B (CB) and propyzamide, which are inhibitors of AFs and MTs, respectively. CB reversibly inhibited cytoplasmic streaming while propyzamide alone had no effect on it. However, after treatment with both CB and propyzamide, removal of CB alone did not lead to recovery of cytoplasmic streaming. In these cells, AFs showed a meshwork structure. When propyzamide was also removed, cytoplasmic streaming and the original organization of AFs were recovered. These results strongly suggest that MTs are responsible for the organization of AFs inHydrocharis root hair cells.     

ULTRASTRUCTURE,DEVELOPMENT AND CYTOPLASMIC ROTATION OF SETA-BEARING CELLS OF COLEOCHAETE SCUTATA (CHLOROPHYCEAE)1

Part of the cytoplasm, which always contains the plastid, of seta-bearing cells of Coleochaete scutata Bréb. rotates clockwise about the base of the seta. Many golgi bodies, vesicles and much endoplasmic reticulum occupy the bridges between the rotating central core of cytoplasm and the stationary peripheral layer of these cells. The setae, which grow from their base, are devoid of organelles other than vesicles and elongate mitochondria. At irregular intervals along the thin seta wall are annular thickenings containing callose. Microtubules which encircle the base of the seta disappear on treatment with colchicine. This drug had no effect on the speed of rotational streaming or the growth rate of existing hairs but did inhibit the development of new setae. Cytochalasin B slowed, but did not stop, streaming after 3 h exposure. However caffeine, but not EDTA, EGTA or the Ca ionophore A23187, reversibly inhibited cyclosis. The mechanism of cytoplasmic rotation is discussed in the light of these drug treatments and the presence of actin in the alga.     

The effect of laser microsurgery on cytoplasmic strands and cytoplasmic streaming in isolated plant protoplasts

Cytoplasmic strands of actively streaming isolated callus derived protoplasts of higher plants were subjected to laser microsurgery. Typically, the irradiated strand retracted and cytoplasmic streaming stopped in the entire cell. At the same time, all cytoplasmic strands disintegrated, and formerly not totally spherically shaped protoplasts became spherical. This result indicates tension as a stability factor of cell shape and the cytoplasmic make-up and demonstrates that the nonspherical shape of these protoplasts is not due to cell wall residues. Cytoplasmic streaming as well as the strands were quickly reestablished and often the irregular shape of the protoplast appeared again. Treatment of unirradiated cells with cytochalasin B showed similar effects. The results are discussed with respect to the involvement of cytoskeletal elements in cytoplasmic streaming and organization.     

Roles of actin filaments in cytoplasmic streaming and organization of transvacuolar strands in root hair cells ofHydrocharis

Summary Effects of cytochalasin B and mycalolide-B on cytoplasmic streaming, organizations of actin filaments and the transvacuolar strand were studied in root hair cells ofHydrocharis, which shows reverse fountain streaming. Both toxins inhibited cytoplasmic streaming and destroyed the organizations of actin filaments and transvacuolar strands. However, we found a great difference between these toxins with respect to reversibility. The effects of cytochalasin B were reversible but not those of mycalolide B. The present results suggest that actin filaments work as a track of cytoplasmic streaming and as a cytoskeleton to maintain the transvacuolar strand. The usefulness of root hair cells ofHydrocharis in studying the dynamic organization of actin filaments of plant is discussed.Abbreviations CB cytochalasin B - DMSO dimethylsulfoxide - ML-B mycalolide B     

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.     

Lidocaine,a local anesthetic,reversibly inhibits cytoplasmic Streaming inVallisneria mesophyll cells

Summary Lidocaine, which like other local anesthetics is known to inhibit intracellular transport in animal cells, was tested for its effect on the rotational cytoplasmic streaming in the mesophyll cells of the aquatic plantVallisneria. The drug caused reversible inhibition of cytoplasmic streaming in a dose dependent manner within the 2–20 mM range; higher concentrations resulted in permanent cessation of all cytoplasmic motion. Upon recovery following replacement of the normal bathing medium, cytoplasmic rotation was always resumed in the direction of the original movement exhibited by a given cell. The lidocaine effect was virtually independent of the ionic composition of the incubation medium, but it was markedly affected by the external pH; acidic conditions (pH 6) largely prevented the inhibition of streaming, whereas an alkaline environment (pH 8) accelerated both the onset of the effect and the recovery upon removal of the anesthetic. On the basis of these results and findings in other systems, it is suggested that lidocaine acts through interference with mechanisms that regulate cytoplasmic streaming, rather than with the motile apparatus or the supply of metabolic energy.Abbreviation APW artificial pond water     

A Translocation Hypothesis based on the Structure of Plant Cytoplasm

Two types of linear structures have been seen in plant cytoplasm,largely by phase-contrast microscopy. Microscopic fine threads,o.Iµ to Iµ in diameter, were revealed in hair cells,where they formed endoplasmic systems along streaming pathwaysin the parietal cytoplasm and in transvacuolar strands. Duringcirculation streaming, small plastids and mitochondria-likeparticles were observed moving along the fine threads. Similarfine threads, together with small plastids and mitochondria-likeparticles occurred in phloem exudate and transcellular microscopicstrands. The transcellular strands, Iµ to 7µ indiameter, were seen in sieve-tube elements, phloem parenchyma,border parenchyma, and cortical cells. The movement of small plastids across end walls in border-parenchymacells, the appearance of the same structures within strandsin phloem cells, and the undiminished occurrence of small plastidsin successive drops of phloem exudate are collectively takenas evidence for their participation in translocation. Particlemovement is thought to occur through transcellular strands inassociation with fine threads, and to be motivated by a transcellularform of protoplasmic streaming.