State of actin during the cycle of cohesiveness of the cytoplasm in parthenogenetically activated sea urchin egg

By the DNase I inhibition assay it is shown that the cytoplasmic matrix isolated 60 min after procaine activation of Paracentrotus lividus eggs contains about 20% of the total egg actin, mostly in polymerized form (85%). Electron microscopy studies on this cytoplasmic structure after treatment with heavy meromyosin (HMM), reveal that the decorated actin filaments are organized in bundles which are distributed radially, with the arrowheads pointing towards the central region. In addition few microtubules and a network of non-decorated microfilaments of about 3 nm diameter are observed. From the cytoplasmic pH determination and the DNase I inhibition assay on homogenates of eggs which were taken at different times of activation, it cannot be inferred that a direct relationship between the increase in the cytoplasmic pH and the increase in the amount of polymerized actin or of cytoplasmic matrix exists. Activation experiments carried out in the presence of colchicine shows that, although the formation of the cytoplasmic matrix is inhibited, polymerization of actin still occurs. Moreover, from the inhibition effects of cytochalasin B (CB) added before the activator it is shown that polymerization of actin is a necessary step for the organization of the cytoplasmic matrix. However, the cycles of cohesiveness of the cytoplasm observed in the course of the activation process do not appear to depend on cycles of polymerization and depolymerization of actin.     

Cytoplasmic actin and cochlear outer hair cell motility

Summary Isolated outer hair cells of the guinea pig lacking a cuticular plate and its associated infracuticular network retain the ability to shorten longitudinally and become thinner. Membrane ghosts lacking cytoplasm retain the cylindrical shape of the hair-cell, and although they do not shorten, they retain the ability to constrict and become thinner. These data suggest that cytoplasmic components are associated with outer hair-cell longitudinal shortening and that the lateral wall is responsible for maintaing cell shape and for constriction. Actin, a protein associated with the cytoskeleton and cell motility, is thought to be involved in outer hair-cell motility. To study its role, actin was localized in isolated outer hair cells by use of phalloidin labeled with fluorescein and antibodies against actin coupled to colloidal gold. In permeabilized guinea-pig hair cells stained with phalloidin, actin filaments are found along the lateral wall. In frozen-fixed hair cells actin filaments are distributed uniformly throughout the cytoplasm. Electron-microscopic studies show that antibodies label actin throughout the outer hair-cell body. Thus cytoplasmic actin filaments may provide the structural basis for the contraction-like events.     

Building distinct actin filament networks in a common cytoplasm

Eukaryotic cells generate a diversity of actin filament networks in a common cytoplasm to optimally perform functions such as cell motility, cell adhesion, endocytosis and cytokinesis. Each of these networks maintains precise mechanical and dynamic properties by autonomously controlling the composition of its interacting proteins and spatial organization of its actin filaments. In this review, we discuss the chemical and physical mechanisms that target distinct sets of actin-binding proteins to distinct actin filament populations after nucleation, resulting in the assembly of actin filament networks that are optimized for specific functions.     

The structure of cortical cytoplasm

Actin-rich cortical cytoplasm of phagocytic leucocytes forms pseudopodia and controls cell shape and movement by generating directional propulsive and contractile forces. Proteins purified from leucocytes form and deform an actin matrix. Actin-binding protein (ABP) cross-links actin filaments into a three-dimensional lattice with perpendicular branches. This structure, which can be visualized in the electron microscope, is consistent with physical properties of actin-ABP matrices. Gelsolin binds one end of actin filaments with high affinity in the presence of calcium; acumentin, another protein, constitutively binds the other end with low affinity. Together these proteins can control actin filament length and thereby regulate expansion (propulsion) or collapse of the actin network. The assembly state of the network also controls myosin-based contractile forces. A tug-of-war decides the direction of lattice movement, regions of lesser structure tending to move toward regions of greater structure.     

A mechanochemical model of actin filaments

In eukaryotic cells, actin filaments are involved in important processes such as motility, division, cell shape regulation, contractility, and mechanosensation. Actin filaments are polymerized chains of monomers, which themselves undergo a range of chemical events such as ATP hydrolysis, polymerization, and depolymerization. When forces are applied to F-actin, in addition to filament mechanical deformations, the applied force must also influence chemical events in the filament. We develop an intermediate-scale model of actin filaments that combines actin chemistry with filament-level deformations. The model is able to compute mechanical responses of F-actin during bending and stretching. The model also describes the interplay between ATP hydrolysis and filament deformations, including possible force-induced chemical state changes of actin monomers in the filament. The model can also be used to model the action of several actin-associated proteins, and for large-scale simulation of F-actin networks. All together, our model shows that mechanics and chemistry must be considered together to understand cytoskeletal dynamics in living cells.     

Evolutionarily divergent, unstable filamentous actin is essential for gliding motility in apicomplexan parasites

Apicomplexan parasites rely on a novel form of actin-based motility called gliding, which depends on parasite actin polymerization, to migrate through their hosts and invade cells. However, parasite actins are divergent both in sequence and function and only form short, unstable filaments in contrast to the stability of conventional actin filaments. The molecular basis for parasite actin filament instability and its relationship to gliding motility remain unresolved. We demonstrate that recombinant Toxoplasma (TgACTI) and Plasmodium (PfACTI and PfACTII) actins polymerized into very short filaments in vitro but were induced to form long, stable filaments by addition of equimolar levels of phalloidin. Parasite actins contain a conserved phalloidin-binding site as determined by molecular modeling and computational docking, yet vary in several residues that are predicted to impact filament stability. In particular, two residues were identified that form intermolecular contacts between different protomers in conventional actin filaments and these residues showed non-conservative differences in apicomplexan parasites. Substitution of divergent residues found in TgACTI with those from mammalian actin resulted in formation of longer, more stable filaments in vitro. Expression of these stabilized actins in T. gondii increased sensitivity to the actin-stabilizing compound jasplakinolide and disrupted normal gliding motility in the absence of treatment. These results identify the molecular basis for short, dynamic filaments in apicomplexan parasites and demonstrate that inherent instability of parasite actin filaments is a critical adaptation for gliding motility.     

The polymerization of actin. III. Aggregates of nonfilamentous actin and its associated proteins: a storage form of actin

When echinoderm sperm are treated with the detergent Triton X-100 at pH 6.4 in 10 mM phosphate buffer, the membranes are solubilized, but the actin which is located in the periacrosomal region remains as a phase-dense cup. These cups can be isolated free from the flagella and chromatin and can be solubilized by increasing the pH to 8.0 and by changing the ionic strength and type of buffer used. Since the actin does not exist in the "F" state in unreacted sperm, and since the actin remains as a unit that does not diffuse away, it must be present in the mature sperm in a bound or storage state. The actin is, in fact, associated with a pair of proteins whose mol wt are 250,000 and 230,000. When the isolated cups are digested with trypsin, these high molecular weight proteins are digested, thereby liberating the actin. The actin will polymerize if heavy meromyosin or subfragment 1 is added to a preparation of isolated cups. Evidence is presented that this pair of high molecular weight proteins is similar in molecular weight and properties to erythrocyte spectrin. Attempts at transforming the storage form of actin in the cup into filaments were only moderately successful. The best conditions for filament formation involve incubating the cup in ATP and divalent salts. Careful examination of these cups reveals that the actin polymerized preferentially on either end of oriented filaments that already exist in the cup, indicating that self-nucleation is inefficacious. I conclude that the actin can exist in the storage form by its association with spectrin-like molecules and that the actin in this state polymerizes preferentially onto existing filaments.     

利用激光AFM和TEM探索肌动蛋白体外自装配聚合结构

细胞内肌动蛋白(actin)通过与actin结合蛋白(actin binding proteins,ABPs)相互作用,形成以F-actin为基础多种ABPs参与装配的高度有序的超分子聚合结构,行使各种重要生理功能。在体外聚合条件下,不存在F-actin稳定剂时纯化的actin主要通过自装配形成大尺度的聚集堆积结构;这种表观无序的结构体系由于被认为不具备细胞功能活性而受到忽视。利用激光原子力显微镜(atomic force microscope,AFM)和透射电子显微镜(transmission electron microscope,TEM)技术,对actin体外通过自装配过程形成的大尺度聚集结构进行了细致的观察和分析。研究发现,actin在体外通过自装配过程除了形成无序的蛋白堆积物之外,还能够聚合形成复杂的离散结构,包括树状分支的纤维丛、无规卷曲的纤维簇以及具有不同直径的长纤维等;这些大尺度纤维复合物明显不同于在ABPs或过量F-actin稳定剂参与下形成的由单根微丝和微丝束构成的聚合结构。表明无ABPs或F-actin稳定剂存在的情况下,体外聚合的F-actin在一定条件下可进一步聚集缠绕形成复杂的纤维结构或无序的蛋白堆积物。事实上,actin自装配过程反映了其固有的聚合热力学特性,深入探索将有助于理解ABPs在体内actin超分子聚合结构体系装配中的调控作用及其分子机制。     

Activation of cytosolic Slingshot-1 phosphatase by gelsolin-generated soluble actin filaments

Slingshot-1 (SSH1) is a protein phosphatase that dephosphorylates and activates cofilin, an actin-severing and -disassembling protein. SSH1 is bound to and activated by F-actin, but not G-actin. SSH1 is accumulated in the F-actin-rich lamellipodium but is also diffusely distributed in the cytoplasm. It remains unknown whether SSH1 is activated by soluble (low-level polymerized) actin filaments in the cytoplasm. In this study, we show that SSH1 binds to gelsolin via actin filaments in the cytosolic fraction. Gelsolin promoted solubilization of actin filaments and SSH1 in cell-free assays and in cultured cells. SSH1 was activated by gelsolin-generated soluble actin filaments. Furthermore, gelsolin enhanced cofilin dephosphorylation in neuregulin-stimulated cells. Our results suggest that cytosolic SSH1 forms a complex with gelsolin via soluble actin filaments and is activated by gelsolin-generated soluble actin filaments and that gelsolin promotes stimulus-induced cofilin dephosphorylation through increasing soluble actin filaments, which support SSH1 activation in the cytoplasm.     

Nebulin regulation of actin filament lengths: new angles

The highly organized arrays of thick and thin filaments found in striated muscles continue to be the subject of studies that yield groundbreaking concepts regarding cell motility. One example is the idea that massive, linearly extended polypeptides function as molecular rulers that set the length of polymeric filaments. Actin filaments that are polymerized in vitro exhibit wide variations in length, but many cells can assemble structures that contain actin filaments that are remarkably uniform. In striated muscles, the giant nebulin polypeptide extends the length of the actin filaments, and nebulin size has been correlated with actin filament lengths in muscles from different species. Here, I discuss a recent study by Gregorio and colleagues that demonstrates that nebulin knockdown leads to loss of actin filament-length regulation in cardiomyocytes, providing functional evidence that is consistent with the molecular ruler concept.     

Unusual kinetic and structural properties control rapid assembly and turnover of actin in the parasite Toxoplasma gondii

Toxoplasma is a protozoan parasite in the phylum Apicomplexa, which contains a number of medically important parasites that rely on a highly unusual form of motility termed gliding to actively penetrate their host cells. Parasite actin filaments regulate gliding motility, yet paradoxically filamentous actin is rarely detected in these parasites. To investigate the kinetics of this unusual parasite actin, we expressed TgACT1 in baculovirus and purified it to homogeneity. Biochemical analysis showed that Toxoplasma actin (TgACT1) rapidly polymerized into filaments at a critical concentration that was 3-4-fold lower than conventional actins, yet it failed to copolymerize with mammalian actin. Electron microscopic analysis revealed that TgACT1 filaments were 10 times shorter and less stable than rabbit actin. Phylogenetic comparison of actins revealed a limited number of apicomplexan-specific residues that likely govern the unusual behavior of parasite actin. Molecular modeling identified several key alterations that affect interactions between monomers and that are predicted to destabilize filaments. Our findings suggest that conserved molecular differences in parasite actin favor rapid cycles of assembly and disassembly that govern the unusual form of gliding motility utilized by apicomplexans.     

Membrane-associated actin filaments in the cortical cytoplasm of the rat mast cell

Cytoplasmic microfilaments are regular constituents of the cortical cytoplasm of rat mast cells. Heavy meromyosin binding to the microfilaments in glycerinated mast cells indicates that they represent actin filaments. Many of the actin filaments were found to be attached to spots of increased density of the plasma membrane. The actin filaments, possibly as part of an actomyosin system, may be involved in exocytosis of mast cell granules.     

Barbed end-capping protein regulates polarity of actin filaments from the human erythrocyte membrane

The directional polymerization of G actin on single-layered erythrocyte membranes has been examined in the presence or absence of a barbed end-capping protein isolated from sea urchin eggs. When in the absence of the capping protein the single-layered erythrocyte membranes were incubated with 2 microM of G actin, exceeding the critical concentrations, about half of polymerized actin filaments became orientated with arrowheads of heavy meromyosin pointing toward the membrane at 2 microM of G actin. In contrast, in the presence of the capping protein, nearly 90% of the polymerized filaments were directed with arrowheads of HMM pointing away from the membranes. Furthermore, only preincubation of the erythrocyte membranes with the capping protein is effective to a similar extent in regulating the polarity of actin filaments from the membranes. The results obtained are discussed particular as regards to the physiological roles of the barbed end-capping protein in situ.     

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。     

Actin-binding protein promotes the bipolar and perpendicular branching of actin filaments

Branching filaments with striking perpendicularity form when actin polymerizes in the presence of macrophage actin-binding protein. Actin- binding protein molecules are visible at the branch points. Compared with actin polymerized in the absence of actin-binding proteins, not only do the filaments branch but the average length of the actin filaments decreases from 3.2 to 0.63 micrometer. Arrowhead complexes formed by addition of heavy meromyosin molecules to the branching actin filaments point toward the branch points. Actin-binding protein also accelerates the onset of actin polymerization. All of these findings show that actin filaments assemble from nucleating sites on actin- binding protein dimers. A branching polymerization of actin filaments from a preexisting lattice of actin filaments joined by actin-binding protein molecules could generate expansion of cortical cytoplasm in amoeboid cells.     

Effects of temperature on actin polymerized by Ca2+. Direct evidence of fragmentation.

When the temperature is lowered from 20 to 4 degrees C, the specific viscosity of actin polymerized in the presence of either 4 mM-CaCl2 or 2 mM-MgCl2, but not of actin polymerized in the presence of 90 mM-KCl, is decreased by 50% in the absence of free ATP. Addition of ATP restores the viscosity of the actin polymerized by Mg2+, but not that of actin polymerized by Ca2+, to the original value. The effect of temperature on actin polymerized in the presence of Ca2+ is due to (a) polymer-into-monomer conversion, (b) latero-lateral aggregation of filaments, and (c) fragmentation of the filaments. Fragmentation, as demonstrated by fractional centrifugation and electron microscopy, was the most important of these.     

Bidirectional polymerization of G-actin on the human erythrocyte membrane

The directional polymerization of actin on the erythrocyte membrane has been examined at various concentrations of G-actin by thin-section electron microscopy. For this purpose, a new experimental system using single-layered erythrocyte membranes with the cytoplasmic surfaces freely exposed was developed. The preformed actin filaments did not bind with the cytoplasmic surface of the erythrocyte membranes. When the erythrocyte membranes were incubated at low concentrations (0.3 and 0.5 microM) of G-actin, greater than 80% of polymerized actin filaments pointed toward the membranes mainly in an end-on fashion, as judged by arrowhead formation with heavy meromyosin. At higher concentrations (2 and 4 microM) of G-actin, about half of the polymerized actin filaments were directed with arrowheads pointing toward the membranes, while the rest of the filaments showed the opposite polarity pointing away from the membranes. The majority of polymerized actin filaments formed loops at the points of attachment to the membranes. In contrast, when G-actin (2 and 4 microM) in the presence of cytochalasin B was polymerized into filaments, approximately 70% showed the polarity pointing away from the membrane mainly in an end-on fashion. To check the treadmilling phenomena, the erythrocyte membranes with bidirectionally polymerized actin filaments were further incubated with G-actin at the overall critical concentration. In this case, almost all (90%) of actin filaments showed the polarity with arrowheads pointing toward the membranes. The results obtained are discussed with special reference to the mode of association of actin filaments with the plasma membrane in general.     

Isolation and characterization of hog thyroid actin

When the thyroglobulin content is subtracted, actin represents approximately 4.6% of the total protein content in the hog thyroid gland. Actin has been isolated from acetone-dehydrated slices and purified to homogeneity by gel filtration, DEAE-cellulose chromatography and two polymerization-depolymerization cycles. Purified actin (Mr = 42000) contains the beta and gamma species with a 2 to 1 stoichiometry. In the presence of 0.1 M KCl and 2 mM MgCl2 thyroid actin polymerized into 6 nm diameter filaments; under these conditions the critical concentration was 30 micrograms/ml and the intrinsic viscosity 4.7 dl/g.     

The Isolated Comet Tail Pseudopodium of Listeria monocytogenes: A Tail of Two Actin Filament Populations, Long and Axial and Short and Random

Listeria monocytogenes is driven through infected host cytoplasm by a comet tail of actin filaments that serves to project the bacterium out of the cell surface, in pseudopodia, to invade neighboring cells. The characteristics of pseudopodia differ according to the infected cell type. In PtK2 cells, they reach a maximum length of ~15 μm and can gyrate actively for several minutes before reentering the same or an adjacent cell. In contrast, the pseudopodia of the macrophage cell line DMBM5 can extend to >100 μm in length, with the bacteria at their tips moving at the same speed as when at the head of comet tails in bulk cytoplasm. We have now isolated the pseudopodia from PtK2 cells and macrophages and determined the organization of actin filaments within them. It is shown that they possess a major component of long actin filaments that are more or less splayed out in the region proximal to the bacterium and form a bundle along the remainder of the tail. This axial component of filaments is traversed by variable numbers of short, randomly arranged filaments whose number decays along the length of the pseudopodium. The tapering of the tail is attributed to a grading in length of the long, axial filaments.

The exit of a comet tail from bulk cytoplasm into a pseudopodium is associated with a reduction in total F-actin, as judged by phalloidin staining, the shedding of α-actinin, and the accumulation of ezrin. We propose that this transition reflects the loss of a major complement of short, random filaments from the comet, and that these filaments are mainly required to maintain the bundled form of the tail when its borders are not restrained by an enveloping pseudopodium membrane. A simple model is put forward to explain the origin of the axial and randomly oriented filaments in the comet tail.

     

The coordination between actin filaments and adhesion in mesenchymal migration

Mesenchymal cell motility is characterized by a polarized distribution of actin filaments, with a network of short branched actin filaments at the leading edge, and polymers of actin filaments arranged into distinct classes of actin stress fibres behind the leading edge. Importantly, the distinct actin filaments are characteristically associated with discrete adhesion structures and both the adhesions and the actin filaments are co-ordinately regulated during cell migration. While it has long been known that these macromolecular structures are intimately linked in cells, precisely how they are co-ordinately regulated is presently unknown. Live imaging data now suggests that the focal adhesions may act as sites of actin polymerization resulting in the generation of tension-bearing actin bundles of actin filaments (stress fibres). Moreover, a picture is emerging to suggest that the tropomyosin family of proteins that can determine actin filament dynamics may also play a key role in determining the transition between adhesion states. Molecules such as the tropomyosins are therefore tantalizing candidates to orchestrate the coordination of actin and adhesion dynamics during mesenchymal cell migration.