The Relationship between myo-Inositol, ATP and Rotational Streaming

The rotational streaming of cytoplasm in barley root hairs has been stimulated about 1.3–1.8 times through continuous treatment with various solutions of myo-inositol. The stimulation attained the same level as after ATP administration and was dependent on the external myo-inositol supply with the employed concentrations. The stimulation was cut off by simultaneous treatment with myo-inositol and uranyl salts. By using uranyl acetate the rate of streaming was maintained about the value of the control. The uranyl chloride caused an inhibition in the rotational streaming and later made it to cease altogether. The simultaneous treatment with myo-inositol and 2.4-DNP (dinitrophenol) induced a quick inhibition in 60% of the root hairs. consecutively stopping rotational streaming. It is assumed that the stimulation of rotational streaming is not due to the direct effect of myo-inositol but to ATP formed in the reaction: inositol hexaphosphate ++ ADP ? ATP + inositol. According to the results obtained by testing with uranyl salts, the phosphorylation of inositol probably takes place at the cell surface. The effect of 2,4-nNP points to the presence of two competitive metabolic processes involved in ATP consumption: the upkeep of rotational streaming and the uptake of substances by the plant cell.     

Observations on an ATP-sensitive protein system from the plasmodia of a myxomycete

1. Extracts of the plasmodia of the myxomycete, Physarum polycephalum, exhibit reversible decreases in viscosity in response to the addition of ATP under appropriate conditions. The protoplasm material prepared by extraction with KCl solution can apparently exist in either a high or a low viscosity state. As prepared, it is in the low viscosity condition. Rapid and extensive increases in viscosity of the extract are brought about by addition of AMP, inorganic phosphate, or, under certain conditions, of ATP. Only after the high viscosity state has been attained does addition of appropriate quantities of ATP cause a reversible decrease in viscosity. 2. The active principle of crude plasmodial extracts may be concentrated by fractional precipitation with ammonium sulfate and is found in the fraction precipitated between 30 and 40 per cent saturation. This material possesses a higher viscosity than does the original crude extract and is apparently in the high viscosity state since the addition of ATP causes an immediate reversible decrease in viscosity. 3. The ATP-sensitive fraction of myxomycete plasmodia possesses a viscosity which is dependent upon its previous thermal treatment. Extracts incubated at 0° for a period of a few hours increase greatly in viscosity when they are returned to 24.5°. This increased viscosity is structural in nature, is destroyed by mechanical agitation of the solution, and may be reversibly destroyed by addition of ATP. 4. It is suggested that the ATP-responsive protein of myxomycete plasmodia may be related to sol-gel transformations which have been observed in intact plasmodia and may participate in the protoplasmic streaming of the intact organism. This suggestion is based upon the following facts: (a) the protoplasmic streaming of myxomycete plasmodia is increased by microinjection of ATP; (b) the gel portion of the cytoplasm at the site of the microinjection of ATP is extensively converted to the sol state. The changes in structure of the intact cytoplasm are thus similar in nature to the changes exhibited in response to ATP by the purified ATP-sensitive protein. 5. The ATP-sensitive protein of myxomycete plasmodia appears to undergo reversible aggregation to form a high viscosity state. The function of ATP is to break down the aggregates thus formed. Since a specific ATPase activity is associated with the purified material, added ATP is gradually destroyed and recovery of viscosity attends the spontaneous reconstitution of aggregates.     

Low viscosity in the aqueous domain of cell cytoplasm measured by picosecond polarization microfluorimetry

Information about the rheological characteristics of the aqueous cytoplasm can be provided by analysis of the rotational motion of small polar molecules introduced into the cell. To determine fluid-phase cytoplasmic viscosity in intact cells, a polarization microscope was constructed for measurement of picosecond anisotropy decay of fluorescent probes in the cell cytoplasm. We found that the rotational correlation time (tc) of the probes, 2,7-bis-(2-carboxyethyl)-5-(and-6-)carboxyfluorescein (BCECF), 6-carboxyfluorescein, and 8-hydroxypyrene-1,3,6-trisulfonic acid (HPTS) provided a direct measure of fluid-phase cytoplasmic viscosity that was independent of probe binding. In quiescent Swiss 3T3 fibroblasts, tc values were 20-40% longer than those in water, indicating that the fluid-phase cytoplasm is only 1.2-1.4 times as viscous as water. The activation energy of fluid-phase cytoplasmic viscosity was 4 kcal/mol, which is similar to that of water. Fluid-phase cytoplasmic viscosity was altered by less than 10% upon addition of sucrose to decrease cell volume, cytochalasin B to disrupt cell cytoskeleton, and vasopressin to activate phospholipase C. Nucleoplasmic and peripheral cytoplasmic viscosities were not different. Our results establish a novel method to measure fluid-phase cytoplasmic viscosity, and indicate that fluid-phase cytoplasmic viscosity in fibroblasts is similar to that of free water.     

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.     

Cytoplasmic streaming inParamecium

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

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     

NaCl-induced changes in protoplasmic characteristics of Hordeum vulgare cultivars differing in salt tolerance

Water permeability and cytoplasmic viscosity and streaming were investigated in seedlings of two Hordeum vulgare cultivars differing in salt tolerance. Six-day-old seedlings were grown for 4 additional days in Hoagland solution with and without 100 m M NaCl added.
Observations and measurements were made in subepidermal cells of the coleoptile using plasmolytic and centrifugation methods and recordings of the speed of movement of microsomes.
Water permeability was about the same in controls of both cultivars, and was decreased by NaCl stress, but decreased less in the tolerant cultivar. Cells from control plants of the stress tolerant variety had a higher cytoplasmic viscosity than cells from the moderately sensitive cultivar. Cytoplasmic viscosity in both cultivars decreased due to NaCl stress, and more so in the sensitive one. Cytoplasmic streaming was faster in the controls of the salt sensitive cultivar than in controls of the salt tolerant cultivar; NaCl had no significant effect on cytoplasmic streaming in both cultivars.
The specific responses of the cytoplasm of the sensitive and tolerant cultivars to the salt treatment reflect differences in its structure and composition. These differences in the cytoplasm already exist before exposure to salt stress but some alterations of cytoplasmic parameters (e.g. water permeability) were induced by the saline environment.     

Determination of red blood cell membrane viscosity from rheoscopic observations of tank-treading motion.

Measurements of the dimensions and membrane rotational frequency of individual erythrocytes steadily tank-treading in a rheoscope are used to deduce the surface shear viscosity of the membrane. The method is based on an integral energy principle which says that the power supplied to the tank-treading cell by the suspending fluid is equal to the rate at which energy is dissipated by viscous action in the membrane and cytoplasm. The integrals involved are formulated with the aid of an idealized mathematical model of the tank-treading red blood cell (RBC) (Keller and Skalak, 1982, J. Fluid Mech., 120:24-27) and evaluated numerically. The outcome is a surface-averaged value of membrane viscosity which is representative of a finite interval of membrane shear rate. The numerical values computed show a clear shear-thinning characteristic as well as a significant augmentation of viscosity with cell age and tend toward agreement with those determined for the rapid phase of shape recovery in micropipettes (Chien, S., K.-L. P. Sung, R. Skalak, S. Usami, and A. Tozeren, 1978, Biophys. J., 24:463-487). The computations also indicate that the rate of energy dissipation in the membrane is always substantially greater than that in the cytoplasm.     

Über die Wirkung von ADP und einigen Kationen auf die Rotationsströmung in den Wurzelhaaren der Gerste (Hordeum vulgare L.)

Zusammenfassung In getrennten Versuchen wurde die Wirkung von ADP, Ca⁺⁺, Mg⁺⁺, K⁺ und Cu⁺⁺ auf die Rotationsströmung in den Wurzelhaaren der Gerste (Hordetim vulgare L.) untersucht. Das in verschiedenen Konzentrationen fortdauernd verabreichte ADP bedingte eine Stimulation der Plasmaströmung. Die Beschleunigung der Rotationsströmung war der ADP-Konzentration gegenüber umgekehrt proportional (Abb. 3).Von den untersuchten Kationen hatte nur Ca⁺⁺ (1·10^–3 Mol) eine Stimulationswirkung. Diese Stimulationswirkung wird der Aktivierung eines Enzyms bzw. eines kontraktilen Proteins mit ATPase-Eigenschaften zugeschrieben.Die Rolle von ADP und einigen Kationen bei der Stimulation der Rotation wurde dann mit Hilfe einer gemischten Behandlung untersucht. Diese bestand in der gleichzeitigen Verabreichung von ADP (1·10^–6 Mol) und CaCl₂, MgCl₂, KCl (1 · 10^–3 Mol) oder CuCl₂ (1·10^–6 Mol). Es wurde festgestellt, daß Mg⁺⁺ und Ca⁺⁺ eine antagonistische Wirkung ausüben. Ca⁺⁺ hebt die durch ADP induzierte Stimulation auf und reduziert die Rotationsgeschwindigkeit plötzlich bis auf den Kontrollwert. Die Mg⁺⁺-Wirkung bewirkt, nach einer zeitweiligen Beibehaltung der Stimulation, ebenfalls eine Abnahme der Geschwindigkeit. K⁺ hat eine ähnliche Wirkung wie Ca⁺⁺. Cu⁺⁺ beeinträchtigt die ADP-induzierte Stimulation in geringem Maße.Die gleichzeitige Einwirkung von ADP und einigen Kationen erlaubt die Aufstellung folgender Hypothese. Die Rotationsstimulation erfolgt dank dem ATP, das auf Kosten des von außen absorbierten ADP in den Mitochondrien synthetisiert wird. Die zusätzliche ATP-Synthese kann durch gleichzeitige Ca⁺⁺-Behandlung unterbunden werden. NachHanson und Mitarb, sollen Ca⁺⁺ und ADP um ein phosphoryliertes Zwischenprodukt in Kompetition treten, so daß es zu einer Ansammlung von Ca⁺⁺ und P_a in der Zelle kommt. Andererseits könnte teilweise auch die aktive, energieverbrauchende Salzabsorption die Geschwindigkeitsabnahme der Rotation bei gemischter Behandlung erklären.

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The effect of ADP and some cations on rotational streaming in barley (Hordeum vulgare L.) root hairs

Summary The effect of ADP, Ca⁺⁺, Mg⁺⁺, K⁺, and Cu⁺⁺ upon rotational streaming within barley (Hordeum vulgäre L.) root hairs was separately studied. It was shown that various solutions of ADP may stimulate the streaming after continuous treatment. The rate increase of the rotational streaming was inverse proportional to ADP concentration (Fig. 3).From the investigated cations only Ca⁺⁺ (1·10^–3M) caused a stimulation of streaming after continuous treatment. This effect is probably due to enzymic activation of a contractile proteine which has ATPase feature.The role of ADP and of the investigated cations in the stimulation of the rotational streaming was studied by means of mixed treatment. This kind of treatment consists in a simultaneous administration of ADP (1 · 10^–6M) and CaCl₂, MgCl₂, KCl (1 · 10^–3M), or CuCl₂ (1 · 10^–6M) solutions. Ca⁺⁺ and Mg⁺⁺ showed an antagonistic action. Ca⁺⁺ brings about an immediately suppress of ADP induced stimulation. Suddenly the rate of streaming comes back to control. Mg⁺⁺ after a temporary maintaining of stimulation, also causes the lowering of the streaming. The action of K⁺ was very similar to those of Ca⁺⁺. Cu⁺⁺ changes to a little extent the stimulation caused by ADP.The simultaneous action of ADP and of the investigated cations allow us to express the following hypothesis. The stimulation of the rotational streaming after ADP treatment probably is due to ATP synthetized in mitochondria on the account of ADP. The additional synthesis of ATP can be prevented by simultaneous administration of Ca⁺⁺. According toHanson and his coworkers Ca⁺⁺ would compete with ADP for a phosphorylated intermediate product. From a such competition would result the Ca⁺⁺ and P_i accumulation. The active uptake of salts which require energy would also explain the lowering of the rotational streaming rate after the mixed treatment.

     

ATP synthesis in rod outer segments of bovine retina by the reversal of the disk Ca(2+) pump

Purified disk membranes from rod outer segments of the bovine retina were able to synthesize ATP with a maximal activity (about 52 nmoles ATP/min/mg of protein) at physiological calcium concentrations. This activity was inhibited by vanadate or thapsigargin but not by oligomycin, suggesting the reversal functioning of the disk Ca(2+)-ATPase, which would act as a ATP synthesizer at the expense of the calcium gradient between the disks and the cytoplasm of the rod outer segment. The results are discussed in terms of the need of an immediate source of ATP on the disk membranes where the energy is required to supply the rapid reactions of the photoreception processes.     

Aggregation and disaggregation of red blood cells

The aggregation of red blood cells may be analyzed as an interaction of an adhesive surface energy and the elastic stored energy which results from deformation of the cell. The adhesive surface energy is the work required to separate a unit adhered area and is the resultant of adhesive forces due to the bridging molecules that bind the cells together and the electrostatic repulsion due to surface charge. The elastic strain energy in the case of the red blood is associated with the membrane elasticity only since the interior of the cell is liquid. The membrane elasticity is due both to bending stiffness and shear. The area expansion is small and may be neglected. These assumptions allow realistic computation of red cell shapes in rouleaux. The disaggregation of rouleaux requires an external force which must overcome the adhesive energy and also supply additional elastic energy of deformation. Depending on the geometry, the initial effect of elastic energy may tend to aid disaggregation. In a shear flow, the stresses on a suspended rouleau alternately tend to compress and to disaggregate the cells if they are free to rotate. This introduces a time dependence so that viscous effects due to the viscosity of the cell membrane, the cell cytoplasm and the external fluid may play a role in determining whether disaggregation proceeds to completion or not.     

Transient depletion of transported metabolites in the streaming cytoplasm of Chara upon shading the long-distance transmission pathway

Export of reducing power from chloroplasts to cytoplasm serves to balance the NADPH/ATP ratio that is optimal for CO₂ assimilation. Rapid cytoplasmic streaming in characean algae conveys the exported metabolites downstream towards the shaded plastids where envelope transporters may operate for the import of reducing power in accordance with the direction of concentration gradients. Import of reducing equivalents by chloroplasts in the analyzed area transiently enhances the pulse-modulated chlorophyll fluorescence F′ controlled by the redox state of photosystem II acceptor Q_A. When the microfluidic pathway was transferred to darkness while the analyzed cell area remained in dim background light, the amplitude of cyclosis-mediated F′ changes dropped sharply and then recovered within 5–10 min. The suppression of long-distance signaling indicates temporal depletion of transmitted metabolites in the streaming cytoplasm. The return to overall background illumination induced an exceptionally large F′ response to the first local light pulse admitted to a remote cell region. This indicates the appearance of excess reductants in the streaming cytoplasm at a certain stage of photosynthetic induction. The results suggest highly dynamic exchange of metabolites between stationary chloroplasts lining the microfluidic pathway and the streaming cytoplasm upon light–dark and dark–light transitions. Evidence is obtained that slow stages of chlorophyll fluorescence induction in algae with rapid cytoplasmic streaming directly depend on cyclosis-mediated long-distance delivery of metabolites produced far beyond the analyzed cell area.     

Rotational diffusion of TEMPONE in the cytoplasm of Chinese hamster lung cells.

The correlation time for rotational diffusion (tau R) of 2,2,6,6-tetramethyl-4-piperidone-N-oxide (TEMPONE) in Chinese hamster lung (V79) cells has been measured. For these cells in an isosmotic solution at 20 degrees C, tau R = 4.18 X 10(-11) s, approximately 3.6 times greater than tau R = 1.17 X 10(-11) s in water. The relationship between tau R and viscosity was investigated in a number of glycerol-water (0-50%) and sucrose-water (20-40%) solutions and a constant Stokes-Einstein volume of 44 A3 was found for TEMPONE in solutions of less than 20% glycerol and sucrose. This gives an average shear viscosity (for rotation of a small molecule) of 0.038 poise for the cytoplasm. When nonsecular terms were used in the calculation of tau R, the activation energies for rotation of TEMPONE in the above solutions correlated well with the activation energies for shear viscosity. The viscosity increases as the cell is shrunk in hypertonic solutions. It also increases with decreasing temperature with an activation energy of 3.7 kcal/mol, about the same as the activation energy for the viscosity of pure water. The rotational correlation times were carefully calculated considering inhomogeneous line broadening, non-Lorentzian line shapes, the need for accurate tensor values and nonsecular terms.     

The reaction between actomyosin and adenosine triphosphate

1. A study is made of the effect of adenosine triphosphate (ATP) upon the viscosity of solutions of actomyosin in 0.5 M KCl. 2. The observed effects are discussed in terms of an initial drop of the viscosity (viscosity response) and its subsequent slow reversal (recovery effect). The latter is ascribed to a decrease in the ATP concentration through enzymatic hydrolysis. 3. The recovery effect is inhibited by Mg, activated by Ca, in accordance with the effect of these ions on the activity of myosin-ATPase. 4. The viscosity response is not inhibited, probably promoted by Mg. It is not promoted, probably inhibited by Ca. 5. The viscosity response is induced not only by ATP, but to a certain extent also by inosinetriphosphate, inorganic triphosphate, and inorganic pyrophosphate, not by adenosine diphosphate or monophosphate. 6. The viscosity response could be obtained with enzymatically inactive myosin. 7. It is concluded that the effect of ATP upon myosin does not depend on its enzymatic hydrolysis.     

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.     

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.     

Dynamic complexity inPhysarum polycephalum shuttle streaming

Summary The nature of the oscillator controlling shuttle streaming inPhysarum polycephalum is not well understood. To examine the possibility of complex behavior in shuttle streaming, the time between reversal of streaming direction was measured over several hours in an intact plasmodium to produce a time series. Time series data were then used to analyze shuttle streaming dynamics. Complexity in shuttle streaming is revealed by an inverse frequency (1/f) power spectrum where the amplitude of reversals is plotted against their frequency. The complex dynamics of shuttle streaming is also shown by a trajectory in phase space typical of a strange attractor. Finally, shuttle streaming time series data have a dominant Lyapunov exponent of approximately zero. Dynamic systems with a Lyapunov exponent of zero exist in a state at the edge of chaos. Systems at the edge exhibit self-organized criticality, which produces complex behavior in many physical and biological systems. We propose that complex dynamics inPhysarum shuttle streaming is an example of self-organized criticality in the cytoplasm. The complex behavior ofPhysarum is an emergent phenomenon that probably results from the interaction of actin filaments, myosin, ATP, and other components involved in cell motility.     

Long‐Lifetime Triboelectric Nanogenerator Operated in Conjunction Modes and Low Crest Factor

The high‐output triboelectric nanogenerator (TENG) is indispensable for its practical applications toward industrial products. However, the electricity loss in simple parallel connection among all units and the typically high crest factor output seriously hamper the practical applications of TENG. Here, a rectified TENG is reported in parallel structure to solve the problem of electricity loss in simple parallel connection. The rotational contact–separation structure with phase difference between rectified TENGs addresses high crest factor output and extends service life of rotational TENG simultaneously. The current crest factor is dramatically decreased to 1.31 in multiple rectifier multiple TENG in parallel (MRM‐TENG), while that of TENG in simple parallel is higher than 6. Meanwhile, the current output can retain up to ≈93% of its initial performance after 7 200 000 rotations under 2.00 r s^?1 of 1000 h. Furthermore, the equivalent current can be in linear growth with low crest factor by making MRM‐TENG in parallel for distributed energy supply without electricity loss. This work may provide a new strategy for TENG in parallel to achieve a low crest factor output and long‐term cycling stability power generation in distributed energy harvesting for large‐scale power application.