Cytoarchitecture and pattern of cytoplasmic streaming in root hairs ofMedicago truncatula during development and deformation by nodulation factors

Summary The cytoarchitecture and the pattern of cytoplasmic streaming change during the development of root hairs ofMedicago truncatula and after a challenge with nodulation (Nod) factors. We measured the speed and orientation of movement of 1–2 μm long organelles. The speed of organelle movement in cytoplasmic strands in the basal part of growing root hairs is 8–14 μm/s and is of the circulation type like in trichoblasts, bulges before tip-growth initiation, and full-grown hairs. In the subapical area of growing hairs, reverse-fountain streaming occurs discontinuously at a slower net speed. The reason for the slower speed is the fact that organelles often stop and jump. Reverse-fountain streaming is a pattern in which the main direction of organelle transport reverses 180 degrees before the cell tip is reached. Within minutes after their application to roots,Rhizobium leguminosarum-derived Nod factors, cause an increase and divergence in the subapical cytoplasmic strands. This phenomenon can best be observed in the growth-terminating hairs, since in hairs of this developmental stage, subapical cytoplasmic strands are transvacuolar. First, the tips of these hairs swell. The organelle movement in the swelling tip increases up to the level normal for circulation streaming, and the number of strands with moving organelles increases. When a new polar outgrowth emerges, reverse-fountain streaming is set up again, with all its characteristics like those seen in growing hairs. This outgrowth may obtain a new full root hair length, by which these hairs may become twice as long as nonchallenged hairs. Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

植物微管特效解聚剂APM对紫露草雄蕊毛细胞胞质环流的影响

采用体外渗透和显微注射的方法。将植物微管特效解聚剂甲基氨草磷(APM)引入紫露草雄蕊毛细胞后,发现原来沿着胞质束运动的胞质颗粒运动速度渐慢,进而胞质束消失,颗粒运动停止。显微注射后,还发现APM可通过胞间通道由被注射的细胞向两侧细胞扩散,从而也导致两侧细胞胞质束消失,颗粒运动停止。APM对胞质环流的抑制作用是可逆的。结果表明微管可能是胞质束的重要组份之一,植物胞质环流与微管的聚合与解聚状态有密切关系。     

Gravity perception in decapped roots of Zea mays

Time-lapse photography and light microscopy were used to determine whether or not sedimentation of the newly developed amyloplasts in the apex of Zea mays L. roots occurred at the time when geotropic responsiveness reappears following removal of the cap. All decapped roots exhibiting a geotropic response had some amyloplast sedimentation in the apical cortical cells. Exposing decapped roots to a centrifugal acceleration of 25 g for 4 h showed that amyloplasts of a similar size and development were not displaced within the cytoplasm when this treatment began 12 h after decapping, whereas displacement did occur when the treatment began 24 h after decapping. This finding indicates the occurrence of a change in the physical characteristics of the cytoplasm between 12 h and 24 h after removing of the cap, which allows amyloplast movement and thus restores gravity perception.     

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     

Amyloplast Sedimentation in Shoot Statocytes having a Large, Central Vacuole: Further Interpretation from Electron Microscopy

The claim (Lawton, Juniper, and Hawes, 1986) that amyloplastssediment through the central vacuole of geostimulated shootstatocytes has been critically examined. As the result of ourTEM study of Taraxacum statocytes and from theoretical considerationsof amyloplast sedimentation, we conclude that it is possiblefor individual amyloplasts surrounded by a layer of tonoplast-boundedcytoplasm to travel occasionally through the vacuole, but unlikelythat the majority of the amyloplasts in a statocyte sedimentin this manner. We put forward a scheme for amyloplast movementin shoot statocytes which emphasizes the fluidity of the tonoplastmembrane. In this scheme, it is expected that most amyloplastssediment in peripheral cytoplasm down the statocyte cell wall,but amyloplasts may also, as they sediment, create or breaktransvacuolar strands, or move through already existing transvacuolarstrands, or fall through the vacuole while enclosed by somecytoplasm and tonoplast membrane. Finally, it is suggested thatthe tonoplast membrane may have been neglected as a membranesite for detection of the gravity stimulus through interactionwith sedimenting amyloplasts. Key words: Amyloplast sedimentation, statocytes, geotropism, Taraxacum officinale     

Amyloplast development in etiolated and ethylene-treated pea epicotyls

The amyloplasts found in the apical hook cells of etiolated pea (Pisum sativum L.) epicotyls were randomly distributed. Sedimentation of endodermal amyloplasts in the direction of gravity became apparent in the transition from the hook to the top of the main axis of the epicotyl. Cortical amyloplasts in this region were not, however, sedimented. These patterns of sedimentation could not be related to changes in amyloplast size, and it is proposed that cytoplasmic properties determine amyloplast behaviour.The differentiation of plastids in the hook differed between the amyloplast-containing endodermal cells and the cortical cells, in which amoeboid plastids predominated over amyloplasts. Amyloplasts disappeared from the cortical cells in the main axis of the epicotyl, but in the endodermal cells sedimented amyloplasts were found throughout the upper epicotyl.Etiolated epicotyls induced to grow horizontally by treatment with ethylene had a normal content of amyloplasts, sedimented in the direction of gravity.     

Time-lapse analysis of gravitropism in Ceratodon protonemata

The tip cell of the protonema of the moss Ceratodon purpureus (Hedw.) Brid. is negatively gravitropic when grown in the dark on supplemented agar. Gravitropism, plastid distribution, and plastid movement were studied in living cells using time-lapse video microscopy and infrared light. A wrong-way (downward) curvature preceded upward curvature and was detected as early as 2 minutes after reorientation. Upward curvature began 30-45 minutes after reorientation to the horizontal. Cell division temporarily reversed upward curvature, but did not inhibit wrong-way curvature. Since significant amyloplast sedimentation always occurred before the start of upward curvature, it is possible that these amyloplasts function as statoliths for upward curvature. However, no significant amyloplast sedimentation occurred before wrong-way curvature. Thus, this early phase of gravitropism cannot require plastid sedimentation for gravity sensing. Most plastids moved within and between zones, and plastid zonation was highly dynamic. Plastids moved toward the apex and toward the base of the cell at rates much slower than cytoplasmic streaming. Despite the dynamic nature of plastid movement and zonation, during upward curvature the distance between sedimented plastids and the apex stayed constant. Time-lapse analysis has revealed intriguing events not readily seen previously using destructive sampling.     

Amyloplast sedimentation kinetics in gravistimulated maize roots

Amyloplast sedimentation in gravistimulated maize (Zea mays L.) roots was measured using the change in angle from the center of the cell to each amyloplast as an index of sedimentation. Using tissue fixed after gravistimulation, the relationship between mean amyloplast angle and the duration of gravistimulation was found to be linear when plotted on a logarithmic time scale. Extrapolated values for the onset of angular change are 5.9 s after the start of gravistimulation for the entire population of amyloplasts and 11.8 s for lead amyloplasts. By multiplying the instantaneous angular velocity (in radians) by the cell center to amyloplast radius, it is possible to calculate the initial sedimentation velocity to be 19.1 m min^-1 at 5.9 s. During sedimentation, the mean amyloplast angles surpass the calculated cell corner angle of 123° at 2.2 min for all amyloplasts and at 19 s for lead amyloplasts near the new lower wall. Thus, substantial sedimentation occurs within the presentation time, calculated to be 4.1 min. These kinetics are consistent with several hypotheses of graviperception.Symbol t_p presentation time     

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     

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.     

Immunolocalization of myosin in rhizoids ofChara globularis Thuill

Summary Myosin-related proteins have been localized immunocytochemically in gravity-sensing rhizoids of the green algaChara globularis using a monoclonal antibody against the heavy chain of myosin from mouse 3T3 cells and a polyclonal antibody to bovine skeletal and smooth muscle myosin. In the basal zone of the rhizoids which contain a large vacuole, streaming endoplasm and stationary cortical cytoplasm, the monoclonal antibody stained myosin-related proteins as diffusely fluorescing endoplasmic strands. This pattern is similar to the arrangement of subcortical actin filament bundles. In the apical zone which contains an aggregation of ER membranes and secretory vesicles for tip growth, diffuse immunofluorescence was detected; the intensity of the signal increasing towards the apical cell wall. The most prominent myosin-staining was associated with the surface of statoliths in the apical zone. The polyclonal antibody produced a punctate staining pattern in the basal zone, caused by myosin-related proteins associated with the surface of drganelles in the streaming endoplasm and the periphery of the nucleus. In the apical zone, this antibody revealed myosin-immunofluorescence on the surface of statoliths in methacrylate-embedded rhizoids. Neither antibody revealed myosin-immunofluorescence on the surface of organelles and vesicles in the relatively stationary cytoplasm of the subapical zone. These results indicate (i) that different classes of myosin are involved in the various transport processes inChara rhizoids; (ii) that cytoplasmic streaming in rhizoids is driven by actomyosin, corresponding to the findings onChara internodal cells; (iii) that actindependent control of statolith position and active movement is mediated by myosin-related proteins associated with the statolith surfaces; and (iv) that myosin-related proteins are involved in the process of tip growth.     

Amyloplasts as possible statoliths in gravitropic protonemata of the moss Ceratodon purpureus

The kinetics of gravitropism and of amyloplast sedimentation were studied in dark-grown protonemata of the moss Ceratodon purpureus (Hedw.) Brid. The protonemata grew straight up at a rate of 20–25 m·h^– in nutrient-supplemented agar. After they were oriented to the horizontal, upward curvature was first detected after 1–1.5 h and reached 84° by 24 h. The tip cells exhibited an amyloplast zonation, with a tip cluster of nonsedimenting amyloplasts, an amyloplast-free zone, and a zone with pronounced amyloplast sedimentation. This latter zone appears specialized more for lateral than for axial sedimentation since amyloplasts sediment to the lower wall in horizontal protonemata but do not fall to the basal wall in vertical protonemata. Amyloplast sedimentation started within 15 min of gravistimulation; this is within the 12–17-min presentation time. The data support the hypothesis that some amyloplasts function as statoliths in these cells.This work was supported by the National Aeronautics and Space Administration grant NAGW-780. We thank Professor E. Hartmann and J. Schwuchow for providing Ceratodon cultures, Dr. John Z. Kiss and Jeff Young for valuable discussions, and Professor Rainer Hertel (University of Freiburg, FRG) for bringing this material to our attention.     

Dynamic changes in the actin cytoskeleton during the high-fluence rate response of theMougeotia chloroplast

Summary Since photo-induced orientation movement of a single, ribbon-shaped chloroplast in each cell of the filamentous green algaMougeotia is inhibited in the presence of cytochalasin B, actin is thought to be involved in the process of chloroplast movements. However, this possibility remains to be proved. A specific class of cytoplasmic filaments, which emerge from the advancing front of the moving chloroplast, can be seen by differential interference contrast (DIC) microscopy. However, no one has yet succeeded in defining the nature of these filaments. We have been able to stain the actin filaments (AFs) associated with the moving chloroplast with fluorescein-conjugated phalloidin (FP) after pre-treatment withm-maleimidobenzoyl N-hydroxysuccinimide ester (MBS). No filamentous structures were observed in cells that had been pre-irradiated with low-fluence rate red light. However, transversely oriented fluorescent filaments appeared at the front edge of the moving chloroplast when it began to rotate under irradiation with high-fluence rate white light. These filaments disappeared after completion of the orientation movement, suggesting the simultaneous appearance of AFs and the orientation movement of the chloroplast. Thick cytoplasmic strands connecting the edge of the chloroplast with the parietal cytoplasm were often seen by DIC microscopy before and after completion of the high-fluence rate orientation movement. These thick cytoplasmic strands could not be stained by FP, but were often stained by 3,3-dihexyloxacarbocyanine iodide (DiOC₆(3)), suggesting that they are transvacuolar strands that include endoplasmic reticulum.     

PHASE CINEMICROGRAPHIC OBSERVATIONS ON CULTURED CELLS. II. MASS MOVEMENT OF CYTOPLASM IN EUPHORBIA MARGINATA

Mass movement is a form of streaming in which distinct quantities of cytoplasm flow as entities along a transvacuolar strand or cytoplasmic striations of the peripheral cytoplasm. An individual mass can move at variable velocities during a brief period of time or change its direction of flow. Two masses, when moving at different velocities in the same or different directions along a strand, can be observed to collide. This can occur repeatedly, resulting in the formation of a mass of considerable size. Many organelles can be observed to move at velocities differing from that of the mass; some can be observed to change directions during their movement. A mass may represent a dilation of one or more microstreams within the cytoplasm. Folding of the microstreams within a mass may explain the changes in the direction of movement observed for some organelles. Several levels of movement are associated with streaming, including those of the ground plasm, of the organelles, of the transvacuolar strands and of the cytoplasm masses. These, and possibly more subtle aspects of the streaming phenomenon, must be incorporated into any theory of streaming.     

An Arabidopsis E3 ligase, SHOOT GRAVITROPISM9, modulates the interaction between statoliths and F-actin in gravity sensing

Higher plants use the sedimentation of amyloplasts in statocytes as statolith to sense the direction of gravity during gravitropism. In Arabidopsis thaliana inflorescence stem statocyte, amyloplasts are in complex movement; some show jumping-like saltatory movement and some tend to sediment toward the gravity direction. Here, we report that a RING-type E3 ligase SHOOT GRAVITROPISM9 (SGR9) localized to amyloplasts modulates amyloplast dynamics. In the sgr9 mutant, which exhibits reduced gravitropism, amyloplasts did not sediment but exhibited increased saltatory movement. Amyloplasts sometimes formed a cluster that is abnormally entangled with actin filaments (AFs) in sgr9. By contrast, in the fiz1 mutant, an ACT8 semidominant mutant that induces fragmentation of AFs, amyloplasts, lost saltatory movement and sedimented with nearly statically. Both treatment with Latrunculin B, an inhibitor of AF polymerization, and the fiz1 mutation rescued the gravitropic defect of sgr9. In addition, fiz1 decreased saltatory movement and induced amyloplast sedimentation even in sgr9. Our results suggest that amyloplasts are in equilibrium between sedimentation and saltatory movement in wild-type endodermal cells. Furthermore, this equilibrium is the result of the interaction between amyloplasts and AFs modulated by the SGR9. SGR9 may promote detachment of amyloplasts from AFs, allowing the amyloplasts to sediment in the AFs-dependent equilibrium of amyloplast dynamics.     

Microinjection of pollen‐specific actin‐depolymerizing factor, ZmADF1, reorientates F‐actin strands in Tradescantia stamen hair cells

Maize actin-depolymerizing factor (ADF) binds both monomeric and filamentous actin and increases actin dynamics in vitro. To test its effects in vivo, recombinant pollen ADF1 was expressed in bacteria and microinjected into Tradescantia stamen hair cells. Initially, all cytoplasmic streaming ceased and the central, longitudinal transvacuolar strands were disrupted. After 20–45 min, streaming resumed but in the form of conspicuous transverse pathways of movement in the cortex. Staining the actin filaments by a second injection of fluorescein-conjugated phalloidin showed that the longitudinal actin cables seen in controls had been replaced by a thickening of the transverse cortical arrays, whose orientation matched the new pattern of streaming. Microinjection of rhodamine–tubulin confirmed that the microtubules also formed a transverse cortical array and it is suggested that the spatial cues for re-modelling the actin after ADF1 injection may be provided by the microtubular system.     

Cytoplasmic streaming in the root cortex and its role in the delivery of potassium to the shoot

The influence of cytochalasin B (CB), a potent inhibitor of cytoplasmic streaming, on ⁸⁶Rb-labelled K⁺ translocation by detopped Lycopersicon esculentum Mill., Cucumis sativus L. and Zea mays L. plants was examined by measuring the radioactivity in xylem exudate before and after the addition of CB to the medium bathing the roots. CB caused complete cessation of cytoplasmic streaming in root segments within 15 min but was without effect on either total ⁸⁶Rb uptake or exudation. Thus factors other than cytoplasmic streaming limit the movement of K⁺ across the symplast of the root of higher plants.     

Amyloplast sedimentation and organelle saltation in living corn columella cells

Amyloplast sedimentation during gravistimulation and organelle movements was studied in living central rootcap cells of Zea mays L. cv. Merit. Cells from sectioned roots were viewed with a horizontally-mounted videomicroscope. The kinetics of gravity-induced amyloplast sedimentation were comparable to those calculated from experiments using fixed material. Individual amyloplasts fell at an average velocity of 5.5 micrometers min-1; the maximal velocity of fall measured was 18.0 micrometers min-1. Amyloplasts often rotated, sometimes rose in the cytoplasm, and occasionally underwent sudden rapid movements as fast as 58 micrometers min-1. Saltations of other organelles were frequently observed. This appears to be the first report of cytoplasmic streaming in the presumptive statocytes of roots.     

Amyloplast displacement is necessary for gravisensing in Arabidopsis shoots as revealed by a centrifuge microscope

The starch‐statolith hypothesis proposes that starch‐filled amyloplasts act as statoliths in plant gravisensing, moving in response to the gravity vector and signaling its direction. However, recent studies suggest that amyloplasts show continuous, complex movements in Arabidopsis shoots, contradicting the idea of a so‐called ‘static’ or ‘settled’ statolith. Here, we show that amyloplast movement underlies shoot gravisensing by using a custom‐designed centrifuge microscope in combination with analysis of gravitropic mutants. The centrifuge microscope revealed that sedimentary movements of amyloplasts under hypergravity conditions are linearly correlated with gravitropic curvature in wild‐type stems. We next analyzed the hypergravity response in the shoot gravitropism 2 (sgr2) mutant, which exhibits neither a shoot gravitropic response nor amyloplast sedimentation at 1  g . sgr2 mutants were able to sense and respond to gravity under 30  g conditions, during which the amyloplasts sedimented. These findings are consistent with amyloplast redistribution resulting from gravity‐driven movements triggering shoot gravisensing. To further support this idea, we examined two additional gravitropic mutants, phosphoglucomutase (pgm) and sgr9, which show abnormal amyloplast distribution and reduced gravitropism at 1  g . We found that the correlation between hypergravity‐induced amyloplast sedimentation and gravitropic curvature of these mutants was identical to that of wild‐type plants. These observations suggest that Arabidopsis shoots have a gravisensing mechanism that linearly converts the number of amyloplasts that settle to the ‘bottom’ of the cell into gravitropic signals. Further, the restoration of the gravitropic response by hypergravity in the gravitropic mutants that we tested indicates that these lines probably have a functional gravisensing mechanism that is not triggered at 1  g .