TheDictyostelium discoideum 30,000 dalton protein contributes to phagocytosis

Summary TheDictyostelium discoideum 30 kDa actin-bundling protein cross-links actin filaments into bundles in vitro, and is present in filopodia and pseudopodia in living cells. Monoclonal antibodies reactive with this protein have been isolated, and employed as specific probes for the function of this protein. The monoclonal antibody B2C blocks the interaction of the 30 kDa protein with F-actin in vitro, and decreases phagocytosis ofE. coli when introduced into livingDictyostelium cells by controlled sonication. Use of this monoclonal antibody for visualization of the 30 kDa protein by immunofluorescence microscopy reveals striking localization around food particles during the process of phagocytosis. Double staining with rhodamine-labelled phalloidin and the monoclonal antibody documents the co-localization of the 30 kDa protein and actin during formation of phagocytic cups. The dissociation of the 30 kDa protein occurs during the process of maturation to form phagolysosomes. These results support the hypothesis that this actin cross-linking protein participates in dynamic rearrangements of actin filaments accompanying phagocytosis.Abbreviations ATP adenosine 5-triphosphate - DEAE diethyl aminoethyl - EDTA (ethylenedinitrilo)-tetraacetic acid - EGTA ethylene glycol-bis(-aminoethyl ether) N,N,N,N-tetraacetic acid - PAGE polyacrylamide gel electrophoresis - PIPES piperazine-N,N-bis[2-ethanesulfonic acid] - SDS sodium dodecyl sulfate - Sorensen's buffer 2mM Na₂HPO₄+15mM KH₂PO₄, pH6.1 - Tris tris-(hydroxymethyl) aminomethane     

Locking the hydrophobic loop 262-274 to G-actin surface by a disulfide bridge prevents filament formation

Models of F-actin structure predict the importance of hydrophobic loop 262-274 at the interface of subdomains 3 and 4 to interstrand interactions in filaments. If this premise is correct, prevention of the loop conformational change--its swinging motion--should abort filament formation. To test this hypothesis, we used site-directed mutagenesis to create yeast actin triple mutant (LC)2CA (L180C/L269C/C374A). This mutation places two cysteine residues in positions potentially enabling the locking of loop 262-274 to the monomer surface via disulfide formation. Exposure of the purified mutant to oxidation catalysts resulted in an increased electrophoretic mobility of actin on SDS PAGE and a loss of two cysteines by DTNB titrations, consistent with disulfide formation. The polymerization of un-cross-linked mutant actin by MgCl2 was inhibited strongly but could be restored to wild type actin levels by phalloidin and improved greatly through copolymerization with the wild-type actin. Light scattering measurements revealed nonspecific aggregation of the cross-linked actin under the same conditions. Electron microscopy confirmed the absence of filaments and the presence of amorphous aggregates in the cross-linked actin samples. Reduction of the disulfide bond by DTT restored normal actin polymerization in the presence of MgCl2 and phalloidin. These observations provide strong experimental support for a critical role of the hydrophobic loop 262-274 in the polymerization of actin into filaments.     

Phalloidin enhances actin assembly by preventing monomer dissociation

Incubation of the isolated acrosomal bundles of Limulus sperm with skeletal muscle actin results in assembly of actin onto both ends of the bundles. These cross-linked bundles of actin filaments taper, thus allowing one to distinguish directly the preferred end for actin assembly from the nonpreferred end; the preferred end is thinner. Incubation with actin in the presence of equimolar phalloidin in 100 mM KCl, 1 mM MgCl2 and 0.5 mM ATP at pH 7.5 resulted in a slightly smaller association rate constant at the preferred end than in the absence of the drug (3.36 +/- 0.14 X 10(6) M-1 s-1 vs. 2.63 +/- 0.22 X 10(6) M-1 s- 1, control vs. experimental). In the presence of phalloidin, the dissociation rate constant at the preferred end was reduced from 0.317 +/- 0.097 s-1 to essentially zero. Consequently, the critical concentration at the preferred end dropped from 0.10 microM to zero in the presence of the drug. There was no detectable change in the rate constant of association at the nonpreferred end in the presence of phalloidin (0.256 +/- 0.015 X 10(6) M-1 s-1 vs. 0.256 +/- 0.043 X 10(6) M-1 s-1, control vs. experimental); however, the dissociation rate constant was reduced from 0.269 +/- 0.043 s-1 to essentially zero. Thus, the critical concentration at the nonpreferred end changed from 1.02 microM to zero in the presence of phalloidin. Dilution-induced depolymerization at both the preferred and nonpreferred ends was prevented in the presence of phalloidin. Thus, phalloidin enhances actin assembly by lowering the critical concentration at both ends of actin filaments, a consequence of reducing the dissociation rate constants at each end.     

The cytoskeleton of Cobaea seed hairs:

The cell wall of Cobaea scandens seed hairs developed in a characteristic sequence, with the deposition of a cellulose thread onto a pectic swelling layer was the final event. The cellulose thread was intracellularly accompanied by a band of 10–18 microtubules. During the formation of the swelling layer the microtubules were homogeneously distributed; they ran circumferentially normal to the cell axis. When cellulose-thread formation started, the microtubules became arranged in a helical band. The density of the microtubules varied during the different phases of development. The highest density was observed before cellulosethread formation and ranged from 6–15 m·m^-2. The length of the microtubules, 20–30 m, was determined by direct measurements, as well as estimated from the total microtubular length in a given area and the counted free ends. With the indirect immunofluorescence technique the microtubules of the band stained inhomogeneously. Those which were located at the edges of the band fluoresced more intensely than those of the central part. Attempts to visualize actin filaments in the hair cells with rhodaminyl-conjugated phalloidin resulted in a homogeneous staining of the area of the microtubular band, indicating that actin filaments may be present in this region. Though, in thin sections and dry-cleaved cells, filamentous structures were observed between the microtubules, caution is expressed that the observed fluorescence was, indeed, due to actin filaments. The role of the filamentous structures is discussed with respect to formation and maintenance of the microtubular band. Microtubules apparently did not cross coated pits which were visualized in the plasma membrane through the dry-cleaving technique.Abbreviations IFT indirect immunofluorescence technique - RP rhodaminyl-conjugated phalloidin - SEM scanning electron microscopy     

Leiomodin and tropomodulin in smooth muscle

Evidence isaccumulating to suggest that actin filament remodeling is critical forsmooth muscle contraction, which implicates actin filament ends asimportant sites for regulation of contraction. Tropomodulin (Tmod) andsmooth muscle leiomodin (SM-Lmod) have been found in many tissuescontaining smooth muscle by protein immunoblot and immunofluorescencemicroscopy. Both proteins cofractionate with tropomyosin in theTriton-insoluble cytoskeleton of rabbit stomach smooth muscle and aresolubilized by high salt. SM-Lmod binds muscle tropomyosin, abiochemical activity characteristic of Tmod proteins. SM-Lmod stainingis present along the length of actin filaments in rat intestinal smoothmuscle, while Tmod stains in a punctate pattern distinct from that ofactin filaments or the dense body marker -actinin. After smoothmuscle is hypercontracted by treatment with 10 mM Ca²⁺,both SM-Lmod and Tmod are found near -actinin at the periphery ofactin-rich contraction bands. These data suggest that SM-Lmod is anovel component of the smooth muscle actin cytoskeleton and, furthermore, that the pointed ends of actin filaments in smooth musclemay be capped by Tmod in localized clusters.

     

Interaction of force transmission and sarcomere assembly at the muscle-tendon junctions of carp (Cyprinus carpio): ultrastructure and distribution of titin (connectin) and α-actinin

At muscle-tendon junctions of red and of white axial muscle fibres of carp, new sarcomeres are found adjacent to existing sarcomeres along the bundles of actin filaments that connect the myofibrils with the junctional sarcolemma. As the filament bundles that transmit force to the junction originate proximal to new sarcomeres, they probably relieve these new sarcomeres from premature loading. In red fibres, these filament bundles are long (up to 20 m) and dense, permitting light-microscopical immunohistochemistry (double reactions: anti-titin or anti--actinin and phalloidin). New sarcomeres have clear I bands; their A band lengths are similar to those of older sarcomeres and the thick filaments lie in register. T tubules are found at the distal side of new sarcomeres but terminal Z lines are absent. The late addition of -actinin suggests that -actinin mainly has a stabilizing role in sarcomere formation. The presence of titin in the terminal fibre protrusions is in agreement with its supposed role in sarcomere formation, viz. the integration of thin and thick filaments. The absence of a terminal Z line from sarcomeres with well-registered A bands suggests that this structure is not essential for the anchorage of connective (titin) filaments.     

Glutathionyl(cysteine-374) actin forms filaments of low mechanical stability

Rabbit muscle actin reacts with 2,4-dinitrophenylglutathionyldisulfide, forming a mixed disulfide in position 374. The product S-(cysteine-374)glutathionyl actin forms filaments which are easily disrupted under shearing stress. Even weak mechanical strain, as exerted, for example, during capillary viscometry or heating the solution to 37°C, leads to considerable breakage of these filaments. Because of spontaneous repair which consumes ATP, the mechanically broken filaments exhibit an approx. 6-fold enhanced steady-state ATPase activity as compared to normal F-actin. Monomers of glutathionyl actin have a reduced affinity for their bound nucleotide and a slightly increased critical concentration. Disruption of the filaments and enhanced ATPase activity are reversed by the addition of KCl or the mushroom toxin phalloidin. By the large stabilizing effects of KCl and phalloidin on glutathionyl actin filaments we propose glutathionyl actin as a tool for detecting filament-stabilizing agents and for studying the different mechanisms of filament stabilization     

Forces measured with micro-fabricated cantilevers during actomyosin interactions produced by filaments containing different myosin isoforms and loop 1 structures

Background

There is evidence that the actin-activated ATP kinetics and the mechanical work produced by muscle myosin molecules are regulated by two surface loops, located near the ATP binding pocket (loop 1), and in a region that interfaces with actin (loop 2). These loops regulate force and velocity of contraction, and have been investigated mostly in single molecules. There is a lack of information of the work produced by myosin molecules ordered in filaments and working cooperatively, which is the actual muscle environment.

Methods

We use micro-fabricated cantilevers to measure forces produced by myosin filaments isolated from mollusk muscles, skeletal muscles, and smooth muscles containing variations in the structure of loop 1 (tonic and phasic myosins). We complemented the experiments with in-vitro assays to measure the velocity of actin motility.

Results

Smooth muscle myosin filaments produced more force than skeletal and mollusk myosin filaments when normalized per filament overlap. Skeletal muscle myosin propelled actin filaments in a higher sliding velocity than smooth muscle myosin. The values for force and velocity were consistent with previous studies using myosin molecules, and suggest a close correlation with the myosin isoform and structure of surface loop 1.

General significance

The technique using micro-fabricated cantilevers to measure force of filaments allows for the investigation of the relation between myosin structure and contractility, allowing experiments to be conducted with an array of different myosin isoforms. Using the technique we observed that the work produced by myosin molecules is regulated by amino-acid sequences aligned in specific loops.     

Interrelation between the spatial disposition of actin filaments and microtubules during the differentiation of tracheary elements in culturedZinnia cells

Summary Changes in the spatial relationship between actin filaments and microtubules during the differentiation of tracheary elements (TEs) was investigated by a double staining technique in isolatedZinnia mesophyll cells. Before thickening of the secondary wall began to occur, the actin filaments and microtubules were oriented parallel to the long axis of the cell. Reticulate bundles of microtubules and aggregates of actin filaments emerged beneath the plasma membrane almost simultaneously, immediately before the start of the deposition of the secondary wall. The aggregates of actin filaments were observed exclusively between the microtubule bundles. Subsequently, the aggregates of actin filaments extended preferentially in the direction transverse to the long axis of the cell, and the arrays of bundles of microtubules which were still present between the aggregates of actin filaments became transversely aligned. The deposition of the secondary walls then took place along the transversely aligned bundles of microtubules.Disruption of actin filaments by cytochalasin B produced TEs with longitudinal bands of secondary wall, along which bundles of microtubules were seen, while TEs produced in the absence of cytochalasin B had transverse bands of secondary wall. These results indicate that actin filaments play an important role in the change in the orientation of arrays of microtubules from longitudinal to transverse. Disruption of microtubules by colchicine resulted in dispersal of the regularly arranged aggregates of actin filaments, but did not inhibit the formation of the aggregates itself, suggesting that microtubules are involved in maintaining the arrangement of actin filaments but are not involved in inducing the formation of the regularly arranged aggregates of actin filaments.These findings demonstrate that actin filaments cooperate with microtubules in controlling the site of deposition of the secondary wall in developing TEs.Abbreviations DMSO dimethylsulfoxide - EGTA ethyleneglycolbis(-aminoethyl ether)-N,N,N,N-tetraacetic acid - FITC fluorescein isothiocyanate - MSB microtubule-stabilizing buffer - PBS phosphate buffered saline - PIPES piperazine-N,N-bis(2-ethanesulfonic acid) - TE tracheary element     

Centrin- and α-actinin-like immunoreactivity in the ciliary rootlets of insect sensilla

Summary Long ciliary rootlets are a characteristic feature of the dendritic inner segments of the sensory cells in insect sensilla. These rootlets are composed of highly ordered filaments and are regularly cross-striated. Collagenase digestion and immunohistochemistry reveal that the rootlets are probably not composed of collagen fibers. However, double-labeling experiments with phalloidin and anti--actinins show that antibodies to -actinin react with the ciliary rootlets of the sensilla, but do not stain the scolopale, which is composed of actin filaments as visualized by phalloidin. Antibodies to centrin, a contractile protein isolated from flagellar rootlets of green algae, also stain the ciliary rootlets. Within the ciliary rootlets of insect sensilla, -actinin may be associated with filaments other than actin filaments. The immunohistochemical localization of a centrin-like protein suggests that contractions probably occur within the rootlets. The centrin-like protein may play a role during the mechanical transduction or adaptation of the sensilla.     

Orientation and rotational dynamics of spin-labeled phalloidin bound to actin in muscle fibers

We have used electron paramagnetic resonance spectroscopy (EPR) to investigate the orientational distribution of actin in thin filaments of glycerinated muscle fibers in rigor, relaxation, and contraction. A spin-labeled derivative of a mushroom toxin, phalloidin (PHSL), was bound to actin in the muscle fibers (PHSL–fibers). The EPR spectrum of unoriented PHSL–labeled myofibrils consisted of three sharp lines with a splitting between the outer extrema (2T) of 42.8 ± 0.1 G, indicating that the spin labels undergo restricted nanosecond rotational motion within an estimated halfcone angle of 76°. When the PHSL–fiber bundle was oriented parallel to the magnetic field, the splitting between the zero-crossing points (2T′) was 42.7 ± 0.1 G. When the fiber bundle was perpendicular to the magnetic field, 2T′ decreased to 34.5 ± 0.2 G. This anisotropy shows that the motion of the probe is restricted in orientation by its binding site on actin, so that the EPR spectrum of PHSL–fiber bundles would be sensitive to small changes in the mean axial orientation of the PHSL–actin interface. No differences in the EPR spectra were observed in fibers during rigor, relaxation, or contraction, indicating that the mean axial orientation of the PHSL binding site changes by less than 5°, and that the amplitude of nanosecond probe rotational motion, which should be quite sensitive to the local environment of the phalloidin, changes by no more than 1°. These results rule out large changes in the overall geometry of the actin filament and in the local conformation of actin near the phalloidin binding site during the generation of isometric tension in muscle fibers. © 1993 Wiley-Liss, Inc.     

激光原子力显微镜观察肌动蛋白体外自组织纤维结构多态性的初步研究

利用原子力显微镜(atomic force microscope,AFM)技术,研究了肌动蛋白体外通过自组织过程形成的纤维结构及其多态性。肌动蛋白在体外通过自组织过程能够聚合形成离散的树状分支的纤维丛和具有不同直径的长纤维等高级纤维结构,表现出明显的结构多态性;与微丝工具药物鬼笔环肽干预下自装配形成的主要由单根微丝和微丝束等纤维成份构成的连续网络结构明显不同。     

Conformation changes of actin during formation of filaments and paracrystals and upon interaction with DNase I, cytochalasin B, and phalloidin

Spin labels attached to rabbit muscle actin became more immobilized upon conversion of actin from the G state to the F state with 50 mM KCl. Titration of G-actin with MgCl2 produced F-actin-like EPR spectra between 2 and 5 mM-actin filaments by electron microscopy. Higher concentrations of MgCl2 produced bundles of actin and eventually paracrystals, accompanied by further immobilization of spin labels. The effects of MgCl2 and KCl were competitive: addition of MgCl2 to 50 mM could convert F-actin (50 mM KCl) to paracrystalline (P) actin; the reverse titration (0 to 200 mM KCl in the presence of 20 mM MgCl2) was less complete. Addition of DNase I to G- or F-actin gave the expected amorphous electron micrographic pattern, and the actin was not sedimentable at (400,000 x g x h). EPR showed that the actin was in the G conformation. Addition of DNase I to paracrystalline actin gave the F conformation (EPR) but the actin was "G" by electron microscopy. Phalloidin converted G-actin to F-actin, had no effect on F-actin, and converted P-actin to the F state by electron microscopy but maintained the P conformation by EPR. Cytochalasin B produced no effects observable by EPR or centrifugation but "untwisted" paracrystals into nets. Since actin retained its P conformation by EPR in two states which were morphologically not P, we conclude that the P state is a distinct conformation of the actin molecule and that actin filaments aggregate to form bundles (and eventually paracrystals) when actin monomers are able to enter the P conformation.     

Detection of small differences in actomyosin function using actin labeled with different phalloidin conjugates

This study shows that there is only a negligible difference in actomyosin function in the in vitro motility assay among actin filaments labeled with Rhodamine phalloidin (RhPh), Alexa-488 phalloidin (APh), and biotin-XX phalloidin (BPh). Similar results were obtained at varying ionic strengths (0.02-0.13 M), in the presence of imidazole or 3-[N-morpholino]propanesulfonic acid (MOPS) buffer, and at varying MgATP concentrations (0.1-3 mM). If RhPh- and APh-labeled filaments were studied in a given flow cell, there was minimal variability in sliding velocity between the fluorophores (standard deviation of 3% of the absolute sliding velocity). The variability was considerably smaller than that between flow cells, allowing us to use dual labeling of different actin types and then apply analysis of variance to detect minor functional differences between them. Using this method, we could statistically verify a 4% difference (P<0.001) in sliding velocity (3mM Mg ATP) between cardiac and skeletal muscle actin. Suggested improvements of the method would readily allow the detection of even smaller differences. We discuss implications of the results for nanotechnological applications, understanding actomyosin function, and reducing experimental costs and the use of laboratory animals.     

Mammalian Formin Fhod3 Regulates Actin Assembly and Sarcomere Organization in Striated Muscles

Actin filament assembly in nonmuscle cells is regulated by the actin polymerization machinery, including the Arp2/3 complex and formins. However, little is known about the regulation of actin assembly in muscle cells, where straight actin filaments are organized into the contractile unit sarcomere. Here, we show that Fhod3, a myocardial formin that localizes to thin actin filaments in a striated pattern, regulates sarcomere organization in cardiomyocytes. RNA interference-mediated depletion of Fhod3 results in a marked reduction in filamentous actin and disruption of the sarcomeric structure. These defects are rescued by expression of wild-type Fhod3 but not by that of mutant proteins carrying amino acid substitution for conserved residues for actin assembly. These findings suggest that actin dynamics regulated by Fhod3 are critical for sarcomere organization in striated muscle cells.In striated muscle, thin actin filaments and thick filaments of myosin are highly organized to form myofibrils (1) (Fig. 1A). During myofibrillogenesis, actin cytoskeleton undergoes dynamic remodeling to produce uniform lengths of straight filaments packaged in the sarcomere, a contractile unit of myofibrils (2–4). In nascent sarcomeres, a filamentous actin-containing structure, referred to as the Z-body or I-Z-I structure, emerges as a precursor of the Z-line that anchors actin filaments. Subsequent alignment of the precursors leads to formation of a striated pattern of the Z-line, and myosin filaments are incorporated between Z-lines. Finally, the M-line that serves as an anchoring site for myosin filaments becomes visible; the appearance is accompanied by alignment of the unanchored end of actin filaments (5). Thus, the mature distribution pattern of actin filaments is constructed at the final step in myofibril assembly, indicating that actin filaments continue to develop throughout myofibrillogenesis. However, the regulation of actin dynamics in this process has remained poorly understood. In nonmuscle cells, organization of actin cytoskeleton is achieved by two major actin nucleating-polymerizing systems, formins and the Arp2/3 complex, with the former producing long straight actin filaments and the latter producing branched actin network (6, 7). Because an unbranched straight actin filament is the major form in striated muscle cells, it is possible that a formin family protein serves as the key regulator of actin dynamics in myofibrils.Open in a separate windowFIGURE 1.Localization of Fhod3 in cultured rat cardiomyocytes. A, shown is a representation of the sarcomere structure (upper panel) and relative localization of Fhod3 and other sarcomeric proteins from B–D (lower panel). B–D, neonatal rat cardiomyocytes were subjected to immunofluorescent double staining for endogenous Fhod3 (red) and α-actinin (green) (B), myomesin (green) (C), or phalloidin (green) (D). For Fhod3 staining, the anti-Fhod3-(650–802) polyclonal antibodies were used. Scale bar, 10 μm.Formins are characterized by the presence of two conserved regions, the formin homology 1 and 2 domains (FH1 and FH2 domains, respectively)² (8, 9). The FH2 domain associates with the barbed end of an actin filament and promotes actin nucleation and polymerization. The FH2 domain continues to associate with the barbed end during polymerization; this processive association protects the growing barbed end from capping proteins that inhibit actin elongation. The FH1 domain, located N-terminally to the FH2 domain, accelerates the FH2-mediated actin elongation via recruiting profilin complexed with an actin monomer. Through cooperation of the FH1 and FH2 domains, formins produce long straight actin filaments even in the presence of capping proteins. Here, we focused on the role of the mammalian formin Fhod3 (previously designated as Fhos2L), which is expressed predominantly in the heart (10), in actin assembly in myofibrils.     

Sarcomere structures in the rabbit psoas muscle as revealed by fluorescent analogs of phalloidin

Summary The fluorescent analogs of phalloidin (rhodamine-and fluorescein-phalloidin) bind tightly to the skinned fibres of rabbit psoas muscle at essentially the same sites as phalloidin and mainly stain the known regions of actin localization in the sarcomere: the thin filaments and Z bands. On both sides of the Z bands, unstained zones were observed, suggesting the presence of proteins tightly bound to the thin filaments. In myofibrils which are stretched to such an extent that the actin and myosin filaments do not overlap, stained bands could also be seen at the myosin-band border, which suggests the localization of actin at these sites.     

Importance of actin cytoskeleton behaviour during preservation of carrot cell suspensions in liquid nitrogen

Summary Conventional methods for preservation of suspended, highly vacuolated, plant cells in liquid nitrogen (LN) usually involve equilibration in molar concentrations of cryoprotective additives, followed by slow cooling to an intermediate subzero temperature (–40 °C), before quenching in LN. Cryomicroscopy was used to monitor the reversible protoplasmic shrinkage of cryoprotected carrot cells, caused by freeze-induced dehydration. Behaviour of actin filaments was analyzed by fluorescence microscopy after labelling with rhodarnine-conjugated phalloidin, in relation to the type of pretreatment and to survival and regrowth ability after preservation at — 196 °C. Loading with dimethylsulphoxide (Me₂SO, 5%) resulted in high survival rates (70%) and regrowth. After thawing, the actin filament (MF) abundance was reduced, but the structure and distribution of the remaining MFs seemed undisturbed. Higher Me₂SO concentrations caused further reduction of MFs, which appeared fragmented after thawing. MFs were maintained by pretreatment with 0.5 M sorbitol alone but carrot cells did not survive at — 196 °C. The same pretreatment, followed by incubation with cytochalasin D (10 M), which greatly reduced MFs, enabled plasmolyzed carrot cells to survive preservation in liquid nitrogen. Thus, after both Me₂SO and sorbitol plus cytochalasin D pretreatments, partial disruption of actin filaments seemed to accompany (Me₂SO) or promote (sorbitol plus cytochalasin D) freezing tolerance at extremely low temperatures.Abbreviations CD cytochalasin D - FDA fluorescein diacetate - LN liquid nitrogen - MF actin filament - Me₂SO dimethylsulphoxide     

Mechanism of the formation of contractile ring in dividing cultured animal cells. I. Recruitment of preexisting actin filaments into the cleavage furrow

Cytokinesis of animal cells involves the formation of the circumferential actin filament bundle (contractile ring) along the equatorial plane. To analyze the assembly mechanism of the contractile ring, we microinjected a small amount of rhodamine-labeled phalloidin (rh-pha) or rhodamine-labeled actin (rh-actin) into dividing normal rat kidney cells. rh-pha was microinjected during prometaphase or metaphase to label actin filaments that were present at that stage. As mitosis proceeded into anaphase, the labeled filaments became associated with the cortex of the cell. During cytokinesis, rh-pha was depleted from polar regions and became highly concentrated into the equatorial region. The distribution of total actin filaments, as revealed by staining the whole cell with fluorescein phalloidin, showed a much less pronounced difference between the polar and the equatorial regions. The sites of de novo assembly of actin filaments during the formation of the contractile ring were determined by microinjecting rh-actin shortly before cytokinesis, and then extracting and fixing the cell during mid-cytokinesis. Injected rhodamine actin was only slightly concentrated in the contractile ring, as compared to the distribution of total actin filaments. Our results indicate that preexisting actin filaments, probably through movement and reorganization, are used preferentially for the formation of the contractile ring. De novo assembly of filaments, on the other hand, appears to take place preferentially outside the cleavage furrow.     

Localization of actin filaments on mitotic apparatus in tobacco BY-2 cells

Actin filaments are among the major components of the cytoskeleton, and participate in various cellular dynamic processes. However, conflicting results had been obtained on the localization of actin filaments on the mitotic apparatus and their participation in the process of chromosome segregation. We demonstrated by using rhodamine-phalloidin staining, the localization of actin filaments on the mitotic spindles of tobacco BY-2 cells when the cells were treated with cytochalasin D. At prophase, several clear spots were observed at or near the kinetochores of the chromosomes. At anaphase, the actin filaments that appeared to be pulling chromosomes toward the division poles were demonstrated. However, as there was a slight possibility that these results might have been the artifacts of cytochalasin D treatment or the phalloidin staining, we analyzed the localization of actin filaments at the mitotic apparatus immunologically. We cloned a novel BY-2 -type actin cDNA and prepared a BY-2 actin antibody. The fluorescence of the anti-BY-2 actin antibody was clearly observed at the mitotic apparatus in both non-treated and cytochalasin D-treated BY-2 cells during mitosis. The facts that similar results were obtained in both actin staining with rhodamine-phalloidin and immunostaining with actin antibody strongly indicate the participation of actin in the organization of the spindle body or in the process of chromosome segregation. Furthermore, both filamentous actin and spindle bodies disappeared in the cells treated with propyzamide, which depolymerizes microtubules, supporting the notion that actin filaments are associated with microtubules organizing the spindle body.Hiroshi Yasuda and Katsuhiro Kanda contributed equally.     

Actins from plant and animal sources tend not to form heteropolymers in vitro and function differently in plant cells

Summary. Pollen and skeletal muscle actins were purified and labeled with fluorescent dyes that have different emission wavelengths. Observation by electron microscopy shows that the fluorescent actins are capable to polymerize into filamentous actin in vitro, bind to myosin S-1 fragments, and have a critical concentration similar to unlabeled actin, indicating that they are functionally active. The globular actins from two sources were mixed and polymerized by the addition of ATP and salts. The copolymerization experiment shows that when excited by light of the appropriate wavelength, both red actin filaments (pollen actin) and green actin filaments (muscle actin) can be visualized under the microscope, but no filaments exhibiting both green and red colors are detected. Furthermore, coprecipitations of labeled pollen actin with unlabeled pollen and skeletal muscle actin were performed. Measurements of fluorescent intensity show that the amount of labeled pollen actin precipitating with pollen actin was much higher than that with skeletal muscle actin, indicating that pollen and muscle actin tend not to form heteropolymers. Injection of labeled pollen actin into living stamen hair cells results in the formation of normal actin filaments in transvacuolar strands and the cortical cytoplasm. In contrast, labeled skeletal muscle actin has detrimental effects on the cellular architecture. The results from coinjection of the actin-disrupting reagent cytochalasin D with pollen actin show that overexpression of pollen actin prolongs the displacement of the nucleus and facilitates the recovery of the nuclear position, actin filament architecture, and transvacuolar strands. However, muscle actin perturbs actin filaments when injected into stamen hair cells. Moreover, nuclear displacement occurs more rapidly when cytochalasin D and muscle actin are coinjected into the cell. It is concluded that actins from plant and animal sources behave differently in vitro and in vivo and that they are functionally not interchangeable.