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

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

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

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

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

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

Involvement of actin filaments in chloroplast division of the algaClosterium ehrenbergii

Summary Studies have been made of whether actin filaments and microtubules are involved in the chloroplast division ofClosterium ehrenbergii (Conjugatae). Fluorostaining with rhodamine-phalloidin showed 5 types of localization of F-actin: (1) cables of actin filaments running in the cortical cytoplasm along the cell's long axis, (2) condensed actin filaments at the septum, (3) perinuclear distribution of actin filaments, (4) F-actins in a marking pin-like configuration adjacent to the nucleus of semicells just before completion of chloroplast kinesis, and (5) actin filaments girdling the isthmus of the constricted and dividing chloroplasts. Cytochalasin D (CD) at a concentration of 6 to 25 M caused significant disruption of actin filaments and the arrest of chloroplast kinesis, nuclear division, septum formation and cytoplasmic streaming within 3 to 6h. Chloroplast kinesis and cytoplasmic streaming recovered when cells were transferred to the medium without CD after CD treatment, or were subjected to prolonged contact with CD for more than 9h. In these cells there was a coincidental reappearance of actin filaments. A tubulin inhibitor, amiprophos-methyl at 330 M, did not inhibit chloroplast kinesis but did inhibit division and positioning of the nucleus. These results suggest that actin filaments do play a role in the mechanism of chloroplast kinesis but that microtubules do not appear to be involved in the process.Abbreviations APM amiprophos-methyl - CD cytochalasin D - DAPI 4,6-diamidino-2-phenylindole - DIC Nomarski differential interference contrast - DMSO dimethyl sulfoxide - Rh-Ph rhodamine-phalloidin     

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

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

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

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

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

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

Microfilaments and microtubules control the shape, motility, and subcellular distribution of cortical mitochondria in characean internodal cells

Summary. The shape, motility, and subcellular distribution of mitochondria in characean internodal cells were studied by visualizing fluorescent dyes with confocal laser scanning microscopy and conducting drug-inhibitor experiments. Shape, size, number, and distribution of mitochondria varied according to the growth status and the metabolic activity within the cell. Vermiform (sausage-shaped), disc-, or amoeba-like mitochondria were present in elongating internodes, whereas very young cells and older cells that had completed growth contained short, rodlike organelles only. Mitochondria were evenly distributed and passively transported in the streaming endoplasm. In the cortex, mitochondria were sandwiched between the plasma membrane and the stationary chloroplast files and distributed in relation to the pattern of pH banding. Highest mitochondrial densities were found at the acid, photosynthetically more active regions, whereas the alkaline sites contained fewer and smaller mitochondria. In the cortex of elongating cells, small mitochondria moved slowly along microtubules or actin filaments. The shape and motility of giant mitochondria depended on the simultaneous interaction with both cytoskeletal systems. There was no microtubule-dependent motility in the cortex of nonelongating mature cells and mitochondria only occasionally travelled along actin filaments. These observations suggest that mitochondria of characean internodes possess motor proteins for microtubules and actin filaments, both of which can be used either as tracks for migration or for immobilization. The cortical cytoskeleton probably controls the spatiotemporal distribution of mitochondria within the cell and promotes their association with chloroplasts, which is necessary for exchange of metabolites during photosynthesis and detoxification.Correspondence and reprints: Arbeitsgruppe Pflanzenphysiologie, Fachbereich Zellbiologie, Universität Salzburg, Hellbrunnerstrasse 34, 5020 Salzburg, Austria.     

Cytoskeletal alterations in interphase cells of the green alga Spirogyra decimina in response to heavy metals exposure: I. The effect of cadmium

Summary. The aim of the study was to elucidate the effect of cadmium ions on the arrangement of the actin and tubulin cytoskeleton, as well as the relationships between cytoskeletal changes and growth processes in the green filamentous alga Spirogyra decimina. Batch cultures of algae were carried out under defined conditions in the presence of various cadmium concentrations. In control cells, the cytoskeleton appeared to be a transversely oriented pattern of both microtubules and actin filaments of various thickness in the cell cortex; colocalization of cortical microtubules and actin filaments was apparent. Microtubules were very sensitive to the presence of cadmium ions. Depending on the cadmium concentration and the time of exposure, microtubules disintegrated into short rod-shaped fragments or they completely disappeared. A steep increase in cell width and a decrease in growth rate accompanied (and probably ensued) a very rapid disintegration of microtubules. Actin filaments were more stable because they were disturbed several hours later than microtubules at any cadmium concentration used. When cadmium ions were washed out, the actin cytoskeleton was rebuilt even in cells in which actin filaments were completely disintegrated at higher cadmium concentrations (40 or 100 μM). The much more sensitive microtubules were regenerated after treatment with lower cadmium concentrations (10 or 15 μM) only. Correspondence and reprints: Centre of Phycology, Institute of Botany, Academy of Sciences of the Czech Republic, Dukelská 135, 379 82 Třeboň, Czech Republic.     

Regeneration of actin bundles in Chara: polarized growth and orientation by endoplasmic flow

Strong irradiation of localized areas of the alga Chara produces chloroplast damage and extensive loss of the actin bundles responsible for cytoplasmic streaming. Immunofluorescence using a monoclonal antibody binding to the actin bundles has been used to follow their regrowth. Bundle regeneration is polarized so that new bundles develop from the ends of the actin bundles delivering endoplasm to the damaged area and not from bundles removing endoplasm. According to the previously established polarity of the actin filaments this growth is occurring from the "barbed" but not the "pointed" ends of the component filaments. The frequently irregular orientation of the regenerated bundles contrasts with the straight, parallel arrangement of the bundles before destruction. The arrangement of the regenerated bundles is suggested to depend on orientation by passive endoplasmic flow rather than a cortical template. As a result, bundles follow sweeping curves and can form a U-turn connecting oppositely polarized bundles normally separated by the neutral line. In addition to development in continuity with the free ends of pre-existing bundles, visualization of small, discrete fluorescent structures suggests that bundles can begin to form in isolation within the damaged areas. The results are discussed in terms of the polarized actin polymerisation seen in vitro, additional controls which may operate on bundle growth in vivo, and the ability of flow to orient F-actin. The relevance of the findings to normal cell ontogeny is assessed.     

Accelerated sliding of pollen tube organelles along Characeae actin bundles regulated by Ca2+

Pollen tubes show active cytoplasmic streaming. We isolated organelles from pollen tubes and tested their ability to slide along actin bundles in characean cell models. Here, we show that sliding of organelles was ATP-dependent and that motility was lost after N-ethylmaleimide or heat treatment of organelles. On the other hand, cytoplasmic streaming in pollen tube was inhibited by either N-ethylmaleimide or heat treatment. These results strongly indicate that cytoplasmic streaming in pollen tubes is supported by the "actomyosin"-ATP system. The velocity of organelle movement along characean actin bundles was much higher than that of the native streaming in pollen tubes. We suggested that pollen tube "myosin" has a capacity to move at a velocity of the same order of magnitude as that of characean myosin. Moreover, the motility was high at Ca2+ concentrations lower than 0.18 microM (pCa 6.8) but was inhibited at concentration higher than 4.5 microM (pCa 5.4). In conclusion, cytoplasmic streaming in pollen tubes is suggested to be regulated by Ca2+ through "myosin" inactivation.     

Cellular organelle transport and positioning by plasma streaming

Our analysis of known data reveals that translocations of passively movable cellular organelles from tiny granules up to large cell nuclei can be ascribed to transport by streaming cytoplasm. The various behaviours, such as velocity changes during more or less interrupted movements, forth and back shuttling and particle rotation result from different types of plasma circulation. Fast movements over long distances, as observed in the large characean internodial cells occur in strong streams generated by myosin in bundles of actin filaments in the direction of the barbed filament ends. Slow movements with frequent reversions of the direction are typical for neuronal axons, in which an anterograde plasma flow, produced in a thin layer of membrane-attached actin filaments, is compensated by a retrograde stream, produced by dynein activity in the central bundle of microtubules. Here particle rotation is due to steep flow velocity gradients, and frequent changes of particle movements result from minor particle displacements in radial directions. Similar shuttling of pigment granules in the lobes of epidermal chromatophores results from the same mechanism, whereby the centrifugal movement along astral microtubules is due to flow generated by excess of kinesin activity and the centripetal movement to the plasma recycling through the intermicrotubular space. If the streaming pattern is reversed by switching to excess dynein activity, the moving granules are trapped in the high microtubule density at the aster center. The presence of larger bodies in asters disturbs the regular, kinesin-dependent microtubule distribution in such a way that a superimposed centrifugal plasma flow develops in the microtubule-dense layer along them, which is recycled in the microtubule-free space, created by their presence. Consequently, at excess kinesin activity, nuclei, mitochondria as well as chromosome fragments move towards the aster center until they reach a dynamically stabilized position that depends on the local microtubule density. These various behaviours are not rationally explainable by models based on a mechanical stepping along microtubules or actin filaments.     

Polarized actin bundles formed by human fascin-1: their sliding and disassembly on myosin II and myosin V in vitro

Fascin-1 is a putative bundling factor of actin filaments in the filopodia of neuronal growth cones. Here, we examined the structure of the actin bundle formed by human fascin-1 (actin/fascin bundle), and its mode of interaction with myosin in vitro. The distance between cross-linked filaments in the actin/bundle was 8-9 nm, and the bundle showed the transverse periodicity of 36 nm perpendicular to the bundle axis, which was confirmed by electron microscopy. Decoration of the actin/fascin bundle with heavy meromyosin revealed that the arrowheads of filaments in the bundle pointed in the same direction, indicating that the bundle has polarity. This result suggested that fascin-1 plays an essential role in polarity of actin bundles in filopodia. In the in vitro motility assay, actin/fascin bundles slid as fast as single actin filaments on myosin II and myosin V. When myosin was attached to the surface at high density, the actin/fascin bundle disassembled to single filaments at the pointed end of the bundle during sliding. These results suggest that myosins may drive filopodial actin bundles backward by interacting with actin filaments on the surface, and may induce disassembly of the bundle at the basal region of filopodia.     

Association of actin filaments with axonal microtubule tracts

Axoplasmic organelles move on actin as well as microtubules in vitro and axons contain a large amount of actin, but little is known about the organization and distribution of actin filaments within the axon. Here we undertake to define the relationship of the microtubule bundles typically found in axons to actin filaments by applying three microscopic techniques: laser-scanning confocal microscopy of immuno-labeled squid axoplasm; electronmicroscopy of conventionally prepared thin sections; and electronmicroscopy of touch preparations-a thin layer of axoplasm transferred to a specimen grid and negatively stained. Light microscopy shows that longitudinal actin filaments are abundant and usually coincide with longitudinal microtubule bundles. Electron microscopy shows that microfilaments are interwoven with the longitudinal bundles of microtubules. These bundles maintain their integrity when neurofilaments are extracted. Some, though not all microfilaments decorate with the S1 fragment of myosin, and some also act as nucleation sites for polymerization of exogenous actin, and hence are definitively identified as actin filaments. These actin filaments range in minimum length from 0.5 to 1.5 µm with some at least as long as 3.5 µm. We conclude that the microtubule-based tracks for fast organelle transport also include actin filaments. These actin filaments are sufficiently long and abundant to be ancillary or supportive of fast transport along microtubules within bundles, or to extend transport outside of the bundle. These actin filaments could also be essential for maintaining the structural integrity of the microtubule bundles.     

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.     

Polycation induced actin bundles

Three polycations, polylysine, the polyamine spermine and the polycationic protein lysozyme were used to study the formation, structure, ionic strength sensitivity and dissociation of polycation-induced actin bundles. Bundles form fast, simultaneously with the polymerization of MgATP-G-actins, upon the addition of polycations to solutions of actins at low ionic strength conditions. This indicates that nuclei and/or nascent filaments bundle due to attractive, electrostatic effect of polycations and the neutralization of repulsive interactions of negative charges on actin. The attractive forces between the filaments are strong, as shown by the low (in nanomolar range) critical concentration of their bundling at low ionic strength. These bundles are sensitive to ionic strength and disassemble partially in 100 mM NaCl, but both the dissociation and ionic strength sensitivity can be countered by higher polycation concentrations. Cys374 residues of actin monomers residing on neighboring filaments in the bundles can be cross-linked by the short span (5.4 Å) MTS-1 (1,1-Methanedyl Bismethanethiosulfonate) cross-linker, which indicates a tight packing of filaments in the bundles. The interfilament cross-links, which connect monomers located on oppositely oriented filaments, prevent disassembly of bundles at high ionic strength. Cofilin and the polysaccharide polyanion heparin disassemble lysozyme induced actin bundles more effectively than the polylysine-induced bundles. The actin-lysozyme bundles are pathologically significant as both proteins are found in the pulmonary airways of cystic fibrosis patients. Their bundles contribute to the formation of viscous mucus, which is the main cause of breathing difficulties and eventual death in this disorder.     

Actin filament turnover regulated by cross-linking accounts for the size, shape, location, and number of actin bundles in Drosophila bristles

Drosophila bristle cells are shaped during growth by longitudinal bundles of cross-linked actin filaments attached to the plasma membrane. We used confocal and electron microscopy to examine actin bundle structure and found that during bristle elongation, snarls of uncross-linked actin filaments and small internal bundles also form in the shaft cytoplasm only to disappear within 4 min. Thus, formation and later removal of actin filaments are prominent features of growing bristles. These transient snarls and internal bundles can be stabilized by culturing elongating bristles with jasplakinolide, a membrane-permeant inhibitor of actin filament depolymerization, resulting in enormous numbers of internal bundles and uncross-linked filaments. Examination of bundle disassembly in mutant bristles shows that plasma membrane association and cross-bridging adjacent actin filaments together inhibits depolymerization. Thus, highly cross-bridged and membrane-bound actin filaments turn over slowly and persist, whereas poorly cross-linked filaments turnover more rapidly. We argue that the selection of stable bundles relative to poorly cross-bridged filaments can account for the size, shape, number, and location of the longitudinal actin bundles in bristles. As a result, filament turnover plays an important role in regulating cytoskeleton assembly and consequently cell shape.     

Microtubule-associated proteins (MAPs) and the organization of actin filaments in vitro

When purified muscle actin was mixed with microtubule-associated proteins (MAPs) prepared from brain microtubules assembled in vitro, actin filaments were organized into discrete bundles, 26 nm in diameter. MAP-2 was the principal protein necessary for the formation of the bundles. Analysis of MAP-actin bundle formation by sedimentation and electrophoresis revealed the bundles to be composed of approximately 20% MAP-2 and 80% actin by weight. Transverse striations were observed to occur at 28-nm intervals along negatively stained MAP- actin bundles, and short projections, approximately 12 nm long and spaced at 28-nm intervals, were resolved by high-resolution metal shadowing. The formation of MAP-actin bundles was inhibited by millimolar concentrations of ATP, AMP-PCP (beta, gamma-methylene- adenosine triphosphate), and pyrophosphate but not by AMP, ADP, or GTP. The addition of ATP to a solution containing MAP-actin bundles resulted in the dissociation of the bundles into individual actin filaments; discrete particles, presumably MAP-2, were periodically attached along the splayed filaments. These results demonstrate that MAPs can bind to actin filaments and can induce the reversible formation of actin filament bundles in vitro.     

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     

Affinity of alpha-actinin for actin determines the structure and mechanical properties of actin filament gels.

Proteins that cross-link actin filaments can either form bundles of parallel filaments or isotropic networks of individual filaments. We have found that mixtures of actin filaments with alpha-actinin purified from either Acanthamoeba castellanii or chicken smooth muscle can form bundles or isotropic networks depending on their concentration. Low concentrations of alpha-actinin and actin filaments form networks indistinguishable in electron micrographs from gels of actin alone. Higher concentrations of alpha-actinin and actin filaments form bundles. The threshold for bundling depends on the affinity of the alpha-actinin for actin. The complex of Acanthamoeba alpha-actinin with actin filaments has a Kd of 4.7 microM and a bundling threshold of 0.1 microM; chicken smooth muscle has a Kd of 0.6 microM and a bundling threshold of 1 microM. The physical properties of isotropic networks of cross-linked actin filaments are very different from a gel of bundles: the network behaves like a solid because each actin filament is part of a single structure that encompasses all the filaments. Bundles of filaments behave more like a very viscous fluid because each bundle, while very long and stiff, can slip past other bundles. We have developed a computer model that predicts the bundling threshold based on four variables: the length of the actin filaments, the affinity of the alpha-actinin for actin, and the concentrations of actin and alpha-actinin.