Gravity-dependent polarity of cytoplasmic streaming inNitellopsis

Summary The internodal cells of the characean algaNitellopsis obtusa were chosen to investigate the effect of gravity on cytoplasmic streaming. Horizontal cells exhibit streaming with equal velocities in both directions, whereas in vertically oriented cells, the downwardstreaming cytoplasm flows ca. 10% faster than the upward-streaming cytoplasm. These results are independent of the orientation of the morphological top and bottom of the cell. We define the ratio of the velocity of the downward- to the upward-streaming cytoplasm as the polar ratio (PR). The normal polarity of a cell can be reversed (PR<1) by treatment with neutral red (NR). The NR effect may be the result of membrane hyperpolarization, caused by the opening of K⁺ channels. The K⁺ channel blocker TEA Cl^– inhibits the NR effect.External Ca²⁺ is required for normal graviresponsivness. The [Ca²⁺] of the medium determines the polarity of cytoplasmic streaming. Less than 1 M Ca²⁺ resulted in a PR<1 while greater than 1 M Ca²⁺ resulted in the normal gravity response. The voltage-dependent Ca²⁺ -channel blocker, nifedipine, inhibited the gravity response in a reversible manner, while treatment with LaCl₃ resulted in a PR<1, indicating the presence of two types of Ca²⁺ channels. A new model for graviperception is presented in which the whole cell acts as the gravity sensor, and the plasma membrane acts as the gravireceptor. This is supported by ligation and UV irradiation experiments which indicate that the membranes at both ends of the cell are required for graviperception. The density of the external medium also affects the PR ofNitellopsis. Calculations are presented that indicate that the weight of the protoplasm may provide enough potential energy to open ion channels.     

Detection of gravity-induced polarity of cytoplasmic streaming inChara

Summary Gravity induces a polarity of cytoplasmic streaming in vertically-oriented internodal cells of characean algae. The motive force that powers cytoplasmic streaming is generated at the ectoplasmic/endoplasmic interface. The velocity of streaming, which is about 100 m/s at this interface, decreases with distance from the interface on either side of the cell to 0 m/s near the middle. Therefore, when discussing streaming velocity it is necessary to specify the tangential plane through the cell in which streaming is being measured. This is easily done with a moderate resolution light microscope (which has a lateral resolution of 0.6 m and a depth of field of 1.4 m), but is obscured when using any low resolution technique, such as low magnification light microscopy or laser Doppler spectroscopy. In addition, the effect of gravity on the polarity of cytoplasmic streaming declines with increasing physiological age of isolated cells. Using a classical mechanical analysis, we show that the effect of gravity on the polarity of cytoplasmic streaming cannot result from the effect of gravity acting directly on individual cytoplasmic particles. We suggest that gravity may best be perceived by the entire cell at the plasma membrane-extracellular matrix junction.     

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     

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.     

Ca2+ ion reversibly inhibits the cytoplasmic streaming ofNitella

Summary When Ca²⁺, K⁺ or Cl^– was injected iontophoretically into the cytoplasm of intactNitella cell, only Ca²⁺ reversibly inhibited the cytoplasmic streaming. However, when an extremely large current was used, the cytoplasmic streaming was reversibly inhibited irrespective of the ion species. This inhibition may be due to a transient increase of free Ca²⁺.     

Involvement of Ca2 + and flowing endoplasm in recovery of cytoplasmic streaming after K+-induced cessation

Summary When K⁺ of high concentration (50 mM) was applied toNitella cells, the cytoplasmic streaming stopped instantly as in the case of electrical stimulation. Recovery of the streaming after chemical stimulation was much slower than after electrical stimulation. When the endoplasm content was modified by centrifugation, streaming recovery was accelerated in the centrifugal cell fragments rich in endoplasm and deccelerated in those poor in it. The recovery was also accelerated either by permeabilizing the plasmalemma in the presence of EGTA in the external solution or by removing the tonoplast by vacuolar perfusion with the EGTA-containing medium. We concluded that the streaming was recovered due to decrease of the cytoplasmic Ca²⁺ concentration, which seems to be accelerated by sequestering of Ca²⁺ by endoplasmic components. The slow recovery of the streaming after KCl-stimulated cessation is assumed to be caused by continuous influx of Ca^{2 +} during the prolonged membrane depolarization.Abbreviations ATP adenosine 5-triphosphoric acid - EGTA ethyleneglycol-bis-(-aminoethyl ether)N,N-tetraacetic acid - PIPES piperazine-N,N-bis(2-ethanesulfonic acid)     

The effect of the external medium on the gravity-induced polarity of cytoplasmic streaming in Chara corallina (Characeae)

Gravity induces a polarity of cytoplasmic streaming in vertical internodal cells of Chara such that the downwardly directed stream moves faster than the upwardly directed stream. In order to determine whether the statolith theory (in which intracellular sedimenting particles are responsible for gravity sensing) or the gravitational pressure theory (in which the entire protoplast acts as the gravity sensor) best explain the gravity response in Chara internodal cells, we controlled the physical properties of the external medium, including density and osmolarity, with impermeant solutes and examined the effect on the polarity of cytoplasmic streaming. As the density of the external medium is increased, the polarity of cytoplasmic streaming decreases and finally disappears when the density of the external medium is equal to that of the cell (1015 kg/m3). A further increase in the density of the external medium causes a reversal of the gravity response. These results are consistent with the gravitational pressure theory of gravity sensing since the buoyancy of the protoplast is dependent on the difference between the density of the protoplast and the external medium, and are inconsistent with the statolith theory since the buoyancy of intracellular particles are unaffected by changes in the external medium.     

Role of calcium ion in the excitability and electrogenic pump activity of theChara corallina membrane: I. Effects of La3+, verapamil,EGTA, W-7, and TFP on the action potential

Summary The cytoplasmic streaming of the normal internodal cell of giant algaChara stops transiently at about the peak of action potential. Application of La³⁺ or verapamil (a calcium channel blocker) or removal of external Ca²⁺ by EGTA caused a partial depolarization of the resting potential, partial decrease of the membrane conductance and a marked decrease of the amplitude of action potential. Under these conditions, the conductance at the peak of action potential reduced markedly and the streaming of cytoplasm did not cease during action potential (excitation-cessation (EC) uncoupling). The effects of Ca²⁺ channel blockers could not be removed by addition of CaCl₂ to the external medium. In contrast, the effect of EGTA on the excitability could be removed to a greater extent and the cytoplasmic streaming ceased at about the peak of action potential by the addition of Ca²⁺ externally. Application of calmodulin antagonists W-7 or TFP caused similar effects on the action potential and on the cytoplasmic streaming.     

Reversible inhibition of cytoplasmic streaming by intracellular Ca2+ in tonoplast-free cells ofChara australis

Summary The effect of the intracellular concentration of Ca²⁺ on the cytoplasmic streaming of tonoplast-free cells ofChara australis was studied by intracellular perfusion. The perfusion media contained 1 mM Mg · ATP. Both cell ends were cut and left open. Media of different Ca²⁺ concentrations were perfused through the cell and the rate of the cytoplasmic streaming just after perfusion was measured. The critical concentration of Ca²⁺ for inhibiting the streaming was 5 × 10^–4M, which was substantially higher than that found earlier byWilliamson (1975) andHayama et al. (1979). Recovery from the inhibition occurred, though not completely, by removing Ca²⁺.In tonoplast-free cells the Ca²⁺ sensitivity differed according to the culture conditions. Cells cultured indoors exhibited a higher sensitivity than those cultured outdoors. Theformer cells contained granule-rich endoplasm aggregates after loss of the tonoplast, while the latter cells did no such aggregates. The aggregates were fixed to the cortical gel with a high dosage of Ca²⁺ and freed by removing it.     

Light-affected ca fluxes in protoplasts from vallisneria mesophyll cells

In Vallisneria gigantea Graebner mesophyll cells, red light irradiation induces cytoplasmic streaming by decreasing the Ca²⁺ concentration in the cytoplasm, while far-red light irradiation inhibits it by increasing the concentration (S Takagi, R Nagai 1985 Plant Cell Physiol 26: 941-951). To examine the effects of light irradiation on Ca²⁺ fluxes across the cell membrane, protoplasts are isolated from the mesophyll cells. Changes in Ca²⁺ concentration in a solution bathing the protoplasts are monitored by spectrophotometry, using the Ca²⁺ -sensitive dye murexide. Red light irradiation induces an increase in Ca²⁺ concentration, which means an efflux of Ca²⁺ from the protoplasts. Subsequent far-red light irradiation produces a rapid decrease in Ca²⁺ concentration down to the dark control level; however, this is not observed in the presence of the Ca²⁺ -channel blocker nifedipine. Vanadate inhibits both the streaming and the Ca²⁺ efflux induced by red light irradiation. The results suggest that red light and far-red light control Ca²⁺ movements across the cell membrane, which in turn regulate the streaming.     

Participation of Ca2+ in cessation of cytoplasmic streaming induced by membrane excitation inCharaceae internodal cells

Summary The mechanism of the cessation of cytoplasmic streaming upon membrane excitation inCharaceae internodal cells was investigated.Cell fragments containing only cytoplasm were prepared by collecting the endoplasm at one cell end by centrifugation. In such cell fragments lacking the tonoplast, an action potential induced streaming cessation, indicating that an action potential at the plasmalemma alone is enough to stop the streaming.The active rotation of chloroplasts passively flowing together with the endoplasm also stopped simultaneously with the streaming cessation upon excitation. The time lag or interval between the rotation cessation and the electrical stimulation for inducing the action potential increased with the distance of the chloroplasts from the cortex. The time lag was about 1 second/15 m, suggesting that an agent causing the rotation cessation is diffused throughout the endoplasm.Using internodes whose tonoplast was removed by replacing the cell sap with EGTA-containing solution (tonoplast-free cells,Tazawa et al. 1976), we investigated the streaming rate with respect to the internal Ca²⁺ concentration. The rate was roughly identical to that of normal cells at a Ca²⁺ concentration of less than 10^–7 M. It decreased with an increase in the internal Ca²⁺ concentration and was zero at 1 mM Ca²⁺.The above results, together with the two facts that Ca²⁺ reversibly inhibits chloroplast rotation (Hayama andTazawa, unpublished) and the streaming in tonoplast-free cells does not stop upon excitation (Tazawa et al. 1976), lead us to conclude that a transient increase in the Ca²⁺ concentration in the cytoplasm directly stops the cytoplasmic streaming. Both Ca influxes across the resting and active membranes were roughly proportional to the external Ca²⁺ concentration, which did not affect the rate of streaming recovery. Based on these results, several possibilities for the increase in Ca²⁺ concentration in the cytoplasm causing streaming cessation were discussed.     

Cessation of cytoplasmic streaming follows an increase of cytoplasmic Ca2+ during action potential inNitella

Summary Taking advantage of prolonged action potential under low temperature, we studied temporal relationship among the action potential, increase of cytoplasmic Ca²⁺ concentration and cessation of cytoplasmic streaming inNitella. The Ca²⁺ concentration began to increase at a very early stage of the action potential and the cessation of streaming followed that increase.Abbreviations APW artificial pond water     

Studies on cessation of cytoplasmic streaming under K+-induced depolarization inNitella axilliformis

Internodal cells ofNitella axilliformis had a membrane potential of about−120mV and showed active cytoplasmic streaming with a rate of about 90 μm/sec in artificial pond water (APW) at 25C. When APW was replaced with 50 mM KCl solution, the membrane potential depolarized accompanying an action potential, and the cytoplasmic streaming stopped. Soon after this quick cessation, the streaming started again, but its velocity remained very low for at least 60 min. Removal of KCl from the external medium led to repolarization of the membrane and accelerated recovery of the streaming. The change in the concentration of free Ca²⁺ in the cytoplasm ([Ca²⁺]_c) was monitored by light emission from aequorin which had previously been injected into the cytoplasm. Upon application of KCl to the external medium, the light emission, i.e., [Ca²⁺]_c, quickly increased. It then decreased exponentially and reached the original low level within 100 sec. The cause of the long-lasting inhibition of cytoplasmic streaming observed even when [Ca²⁺]_c had returned to its low resting level is discussed based on the mechanism proposed for action potential-induced cessation of cytoplasmic streaming; inactivation of myosin by Ca²⁺-dependent phosphorylation or formation of cross bridge between actin filaments and myosin.     

Membrane control of cytoplasmic streaming in characean cells

When a characean cell generates an action potential, cytoplasmic streaming transiently stops and then recovers gradually. Calcium ion is one of the most important factors mediating between membrane excitation and cessation of cytoplasmic streaming. When an internode ofNitella flexilis is subjected to transcellular osmosis, both membrane depolarization and cessation of streaming take place at the endoosmotic part of the cell. It was also found that Ca²⁺ plays a key role in mediating between osmosis induced hydration of the cytoplasm and the cessation of cytoplasmic streaming. The present article reviews how Ca²⁺ acts as a second messenger in intracellular signal transduction in controlling the cytoplasmic streaming.     

Effect of calcium ion on cytoplasmic streaming during turgor regulation in a brackish water charophyte Lamprothamnium

Abstract The brackish water charophyte Lamprothamnium succinctum regulates its turgor pressure against changes in the external osmotic pressure. Upon hypotonic treatment, the rate of cytoplasmic streaming in the internodal cells fell to almost zero, and then recovered to the original value within 20 min. The decrease could be inhibited by lowering the external Ca²⁺ concentration in the hypotonic medium. Also, cytoplasmic streaming in tonoplast-free cells of L. succintum was sensitive to Ca²⁺ like freshwater charophyte. Thus, the concentration of free Ca²⁺ in the cytoplasm seems to increase transiently upon hypotonic treatment.     

Cytoplasmic streaming inChara rhizoids

Summary In-vivo videomicroscopy ofChara rhizoids under 10^–4g demonstrated that gravity affected the velocities of cytoplasmic streaming. Both, the acropetal and basipetal streaming velocities increased on the change to microgravity. The endogenous difference in the velocities of the oppositely directed cytoplasmic streams was maintained under microgravity, yet the difference was diminished as the basipetal streaming velocity increased more than the acropetal streaming velocity. Direction and structure of microfilaments labeled by rhodamine-phalloidin had not changed after 6 min of microgravity.Abbreviations g gravitational acceleration - Nizemi slow rotating centrifuge microscope - Texus technological experiments under reduced gravity     

Studies on the tonoplast action potential ofNitella flexilis

Summary The origins of the two peaks of the action potential inNitella flexilis were analyzed by inserting two microelectrodes. one into the vacuole and the other into the cytoplasm. It was unequivocally demonstrated that the rapid first peak was generated at the plasmalemma and the slow second peak at the tonoplast. MnCl₂ applied in the external medium abolished the second, tonoplast, peak but not the first, plasmalemma, peak, MnCl₂ also inhibited the cessation of the cytoplasmic streaming accompanying the action potential. CaCl₂ added in MnCl₂-containing medium recovered generation of the tonoplast action potential and the streaming cessation. Since it has been established that the cessation of cytoplasmic streaming on membrane excitation is caused by an increase in cytoplasmic free Ca^2– (Williamson, R.E., Ashley, C.C., 1982.Nature (London) 296:647–651: Tominaga, Y., Shimmen, T., Tazawa, M., 1983,Protoplasma 116:75–77), it is suggested that the tonoplast action potential is also induced by an increase in cytoplasmic Ca²⁺ resulting from the plasmalemma excitation. When vacuolar Cl was replaced with SO ₄ ² by vacuolar perfusion, the polarity of the second, slow peak was reversed from vacuolar positive to vacuolar negative with respect to the cytoplasm, supporting the previous report that the tonoplast action potential is caused by increase in Cl permeability (Kikuyama, M., Tazawa, M., 1976.J. Membrane Biol.29:95–110).     

High hydrostatic pressure induces slow contraction in mouse cardiomyocytes

Cardiomyocytes are contractile cells that regulate heart contraction. Ca²⁺ flux via Ca²⁺ channels activates actomyosin interactions, leading to cardiomyocyte contraction, which is modulated by physical factors (e.g., stretch, shear stress, and hydrostatic pressure). We evaluated the mechanism triggering slow contractions using a high-pressure microscope to characterize changes in cell morphology and intracellular Ca²⁺ concentration ([Ca²⁺]_i) in mouse cardiomyocytes exposed to high hydrostatic pressures. We found that cardiomyocytes contracted slowly without an acute transient increase in [Ca²⁺]_i, while a myosin ATPase inhibitor interrupted pressure-induced slow contractions. Furthermore, transmission electron microscopy showed that, although the sarcomere length was shortened upon the application of 20 MPa, this pressure did not collapse cellular structures such as the sarcolemma and sarcomeres. Our results suggest that pressure-induced slow contractions in cardiomyocytes are driven by the activation of actomyosin interactions without an acute transient increase in [Ca²⁺]_i.     

Hydrostatic and osmotic pressure activated channel in plant vacuole

The vacuolar membrane of red beet vacuoles contains a channel which was not gated by voltage or Ca²⁺ ions. Its unit conductance was 20 pS in 200 mM symmetrical KCl solutions. It was stretch activated: the conductance remained constant but the probability of opening was increased by suction or pressure applied to a membrane patch. A 1.5-kNm^-2 suction applied to isolated patches or a 0.08-kNm^-2 pressure applied to a 45-μm diameter vacuole induced an e-fold change in the mean current. A 75% inhibition of the channel current was obtained with 10 μM Gd³⁺ on the cytoplasmic side. The channel was more permeable for K⁺ than for Cl^- (P_K/P_Cl ~ 3). A possible clustering for this channel was suggested by the recordings of the patch current. The channel properties were not significantly affected by a change in sorbitol osmolality in the solutions under isoosmotic conditions, between 0.6 and 1 mol/kg sorbitol. However, the channel was very sensitive to an osmotic gradient. A 0.2-mol/kg sorbitol gradient induced a two-fold increase in unit conductance and a thirty-fold increase in the mean patch current of the channel. A current was measured, when the osmotic gradient was the only driving force applied to the vacuolar membrane. The hydrostatic and osmotic pressure (HOP) activated channel described in this paper could be gated in vivo condition by a change in osmolality, without the need of a change in the turgor pressure in the cell. The HOP channel represents a possible example of an osmoreceptor for plant cells.     

Cytoplasmic streaming affects gravity-induced amyloplast sedimentation in maize coleoptiles

Living maize (Zea mays L.) coleoptile cells were observed using a horizontal microscope to determine the interaction between cytoplasmic streaming and gravity-induced amyloplast sedimentation. Sedimentation is heavily influenced by streaming which may (1) hasten or slow the velocity of amyloplast movement and (2) displace the plastid laterally or even upwards before or after sedimentation. Amyloplasts may move through transvacuolar strands or through the peripheral cytoplasm which may be divided into fine cytoplasmic strands of much smaller diameter than the plastids. The results indicate that streaming may contribute to the dynamics of graviperception by influencing amyloplast movement.