Evidence for an interaction between the membrane protein of a paramyxovirus and actin.

Evidence for an interaction of the membrane (M) protein of Newcastle disease and Sendai viruses with cellular actin was obtained by three different techniques. M protein linked to Sepharose 4B was found to bind actin, but not myoglobin or bovine serum albumin, and to selectively remove actin from a mixture of these three proteins. Sedimentation of a mixture of M protein and F-actin through a sucrose gradient resulted in sedimentation of M protein with actin. Control proteins, bovine serum albumin and cytochrome c, did not sediment with actin. In circular dichroism studies, M protein added to actin in a 1:1 complex resulted in a significant increase in negative ellipticity at 220 nm, which corresponds to an increase in alpha-helix and a decrease in beta-structure and random coil. This is indicative of an interaction between M protein and actin. It is possible that the frequent identification of cellular actin in a number of enveloped viruses may be attributed to the interaction of actin and M protein or its equivalent.     

An 18K protein from ascites hepatoma cell depolymerizes actin filaments rapidly

Several actin binding proteins were isolated from ascites hepatoma cells AH7974 by DNase I affinity chromatography. Among them, a protein having a molecular weight of 18,000 was further purified by DEAE cellulose and hydroxyapatite column chromatographies and gel filtration on a Sephadex G-75 column. The 18K protein not only inhibits actin polymerization but also depolymerizes actin filaments. This conclusion was supported by viscosity and fluorescence intensity measurements and the DNase I inhibition assay. A chemical cross-linking experiment suggested that the 18K protein binds to monomeric actin and forms and 18K-actin 1:1 complex. The net depolymerization rate by the 18K protein measured by the DNase I inhibition assay was slower than the rapid reduction of the fluorescence intensity of pyrene-labeled F-actin upon addition of the 18K protein. This result suggests that the 18K protein not only binds to monomeric actin but also binds to actin filaments directly. The sedimentation assay showed that a part of the 18K protein was cosedimented with actin filaments. Electron microscopic observations demonstrated that the 18K protein decreased the amount of actin filaments and the remaining filaments appeared to be decorated and distorted by the 18K protein. The 18K protein had no Ca2+ ion sensitivity and exhibited the same effect on both this tumor actin and muscle actin.     

Isolation and identification of actin from the phytopathogenic filamentous fungus uromyces appendiculatus

Crude protein extracts of Uromyces appendiculatus contain a polypeptide that resembles actin in several ways. This protein eluates from DEAE-cellulose with concentrations of KCl known to release actin of other species from the cation. The polypeptide is recognized by polyclonal antibodies directed to sodium dodecyl sulfate-denatured actin of chicken gizzard as well as by a monoclonal antibody also made to gizzard actin from chicken, but not by antibodies made against rabbit skeletal muscle actin. Western blot analysis after electrophoresis of the protein on polyacrylamide revealed that the protein has an electrophoretic mobility very similar to that of rabbit skeletal muscle actin. We were unable either to isolate actin by affinity chromatography using immobilized DNase-I, or to identify bean rust actin using DNase-I inhibition assays. Nevertheless, large quantities of the protein sedimented by high speed centrifugation. The sedimented protein resisted attempts to solubilize it under conditions normally used to depolymerize actin filaments. Both of the latter findings indicate unusual features of bean rust actin. Immunocytochemical studies of actin localization in germlings of the fungus using two chicken gizzard actin antibodies revealed actin-containing sites which were similar to those previously observed with fluorescently tagged phallotoxin derivatives.     

Phosphatidic acid induces actin polymerization by activating protein kinases in soybean cells

Phosphatidic acid (PA) levels rise in response to wounding, stress and elicitors, suggesting that it mediates defense responses in plants. During such responses, actin filaments are altered. Since PA induces actin polymerization in animal cells we examined its effect on actin structures in suspension-cultured soybean cells. PA caused a three to four fold increase in cells containing filamentous actin. Immunoblotting with anti-actin antibody showed that actin polymerized within 30 min of treatment. The effect of PA on actin polymerization appears to be mediated by protein kinases because: 1) the effect was suppressed by staurosporin, a general protein kinase inhibitor, and by the protein kinase C-specific inhibitor, calphostin, 2) calyculin A, an inhibitor of protein phosphatase 1 and 2A, mimicked the effect of PA on actin polymerization, and 3) PA activated protein kinases in soybean cells. We suggest that a 54 kDa Ca2+-dependent protein kinase may transduce the PA signal because EGTA inhibited the 54 kDa kinase and the PA-induced actin polymerization, and similar protein kinases have been reported to co-localize with and regulate actin filaments. Our results support the role of PA as a signal mediator and identify actin as a downstream target of PA.     

Activity of a gelsolin-like actin modulator in rat skeletal muscle under protein catabolic conditions.

A gelsolin-like actin-modulating protein was isolated from rat skeletal muscle and characterized with respect to its interaction with actin. The protein, with a molecular mass of approx. 85 kDa, forms a stoichiometric complex with two actin molecules and is activated by micromolar concentrations of Ca2+. It effectively severs actin filaments and promotes nucleation of actin polymerization. The activity of this protein is detectable already in crude extracts by its capability to reduce the steady state viscosity of actin. Actin-modulating activities were determined in muscle extracts of rats kept under protein catabolic conditions, i.e. as generated by corticosterone treatment and starvation. In both cases we found a marked increase of modulator activity. The possibility is discussed that the increased activity of actin modulator indicates a fragmentation of actin filaments prior to the proteolytic degradation of actin.     

A novel actin filament-capping protein from sea urchin eggs: a 20,000-molecular-weight protein-actin complex

A novel protein factor which reduced the low-shear viscosity of rabbit skeletal muscle actin was purified from a 0.6 M KCl-extract of an insoluble fraction of sea urchin eggs by ammonium sulfate fractionation, gel filtration column chromatography, DNase I column chromatography, and hydroxylapatite column chromatography. This protein factor was shown to be a one-to-one complex of a 20,000-molecular-weight protein and egg actin. This protein complex accelerated the initial rate of actin polymerization, but reduced the steady-state viscosity of F-actin. It inhibited at substoichiometric amounts the elongation of actin filaments on sonicated F-actin fragments and depolymerization of F-actin induced by dilution. In addition, it increased the critical concentration of actin for polymerization. All these effects of this protein complex on actin could be explained by the "capping the barbed end" of the actin filament by the complex. The 20,000-molecular-weight protein which was separated from actin also possessed the barbed end-capping activities, but differed from the complex in that it did not accelerate the polymerization of actin.     

Purification and characterization of a Ca2+-dependent actin filament severing protein from bovine adrenal medulla

We describe the purification of an actin regulatory protein from bovine adrenal medulla. This protein caused a dose-dependent decrease of the specific viscosity of actin solution within 30 s of its addition in a Ca2+-sensitive way. Sedimentation assays and the observation by electron microscopy showed that this effect was ascribable to the fragmentation of actin filaments. This protein apparently promoted nucleation of actin polymerization and increased the critical concentration of actin for polymerization nearly 5-fold, suggesting its binding to the barbed end of actin filaments. The inhibitory effect of this protein on the elongation of actin from the barbed end of the myosin subfragment S1-labeled actin seeds confirmed this suggestion. These properties are similar to those of gelsolin. However, the physicochemical properties of this protein having a single polypeptide chain with a molecular weight of 74,000, a Stokes radius of 3.9 nm, a sedimentation coefficient (s0(20),w) of 4.5 S, and an immunological characterization showed that this protein is different from gelsolin.     

Tobacco WLIM1 is a novel F-actin binding protein involved in actin cytoskeleton remodeling

We used confocal microscopy and in vitro analyses to show that Nicotiana tabacum WLIM1, a LIM domain protein related to animal Cys-rich proteins, is a novel actin binding protein in plants. Green fluorescent protein (GFP)-tagged WLIM1 protein accumulated in the nucleus and cytoplasm of tobacco BY2 cells. It associated predominantly with actin cytoskeleton, as demonstrated by colabeling and treatment with actin-depolymerizing latrunculin B. High-speed cosedimentation assays revealed the ability of WLIM1 to bind directly to actin filaments with high affinity. Fluorescence recovery after photobleaching and fluorescence loss in photobleaching showed a highly dynamic in vivo interaction of WLIM1-GFP with actin filaments. Expression of WLIM1-GFP in BY2 cells significantly delayed depolymerization of the actin cytoskeleton induced by latrunculin B treatment. WLIM1 also stabilized actin filaments in vitro. Importantly, expression of WLIM1-GFP in Nicotiana benthamiana leaves induces significant changes in actin cytoskeleton organization, specifically, fewer and thicker actin bundles than in control cells, suggesting that WLIM1 functions as an actin bundling protein. This hypothesis was confirmed by low-speed cosedimentation assays and direct observation of F-actin bundles that formed in vitro in the presence of WLIM1. Taken together, these data identify WLIM1 as a novel actin binding protein that increases actin cytoskeleton stability by promoting bundling of actin filaments.     

A high molecular weight actin binding protein: Its localization in the cortex of the sea urchin egg

From the Triton-treated cortex fraction of sea urchin eggs, a high molecular weight actin binding protein (260K protein) was solubilized by a high salt solution and purified. A cosedimentation assay revealed that the 260K protein binds to actin filaments in a concentration-dependent manner. The low-shear viscosity of actin solutions largely increased in a concentration-dependent manner after addition of 260K protein. Electron microscopy showed that this protein induces the formation of large curled bundles of actin filaments. Different from fascin-induced actin bundles, no clear striations were observed within the actin bundles formed by the 260K protein. Antibodies against the 260K protein were raised in a rabbit and affinity purified. Immunoblotting analysis of Triton-solubilized cortex and various subcellular fractions showed that first only a single band reacted with the antibody and second that the 260K protein exclusively localized in the cortex fraction. Indirect immunofluorescence microscopy localized the protein in the cortex and the region of the cleavage furrow. After double staining, the fluorescence images for actin filaments and the 260K protein well correlate with each other.     

A 40,000-dalton protein from Dictyostelium discoideum affects assembly properties of actin in a Ca2+-dependent manner

A 40,000-dalton protein that affects the assembly properties of actin in a Ca2+-dependent manner has been purified from Dictyostelium discoideum. Gel filtration chromatography indicates that the native form of this protein is a monomer. A major effect of this protein is to reduce the sedimentability of F-actin in a stoichiometric fashion. Nearly complete loss of sedimentability is observed at ratios of the 40,000-dalton protein to actin of greater than 1:10. At low stoichiometries, this protein can accelerate the rate of actin assembly under certain experimental conditions. These effects of the 40,000- dalton protein on the actin assembly properties described above require calcium ion. The 40,000-dalton protein does not exert its effects by proteolyzing actin. Furthermore, peptide maps demonstrate that this protein is not a proteolytic fragment of actin.     

An actin-depolymerizing protein in embryonic chicken skeletal muscle: purification and characterization

In embryonic skeletal muscle, a large amount of non-polymerized actin exists in the cytoplasm (Shimizu and Obinata [1986] J. Biochem. 99, 751-759). A 19-kDa protein (called 19K protein) which binds to G-actin was purified by sequential chromatography on DNase I-agarose, hydroxylapatite, SP-Sephadex, and Sephadex G-75, from the sarcoplasmic fraction of embryonic chicken skeletal muscle. This protein decreased the extent of actin polymerization at a steady state and increased the monomeric actin in a concentration-dependent fashion; it also caused quick depolymerization of F-actin, as determined by spectrophotometry at 237 nm, viscometry, DNase I inhibition assay, and electron microscopy. The molar ratio of 19K protein and actin interacting with each other was estimated to be 1:1. From these results, 19K protein was regarded as being actin depolymerizing protein. The amount of 19K protein in muscle decreased during development. The inhibitory action of 19K protein was removed by myosin or heavy meromyosin, and actin filaments were formed on the surface of myosin filaments when myosin filaments were added to a mixture of actin and 19K protein in a physiological salt solution. We propose that actin assembly is dually controlled in the developing muscle by the inhibitor(s) and an accelerator (myosin); this mechanism may enable the ordered assembly of actin and myosin in the early phase of myofibrillogenesis.     

Isolation of actin-binding protein and villin from toad oocytes

Two actin-modulating proteins have been purified from toad oocytes. A high-molecular weight protein, similar in structure and function to macrophage actin-binding protein, accounts for the isotropic actin-crosslinking activity in oocyte homogenates. A calcium-dependent activity in toad oocyte homogenates which shortens actin filaments is accounted for by a 95,000-dalton protein which resembles villin, an actin-severing and -bundling protein of avian epithelial brush borders. In the presence of high (? μM) calcium, this protein shortens actin filaments in a concentration-dependent fashion and stimulates filament assembly when added to monomeric actin. In the absence of calcium the protein promotes the formation of actin filament bundles. Therefore, in the toad oocyte actin can be crosslinked into a network by actin-binding protein. Calcium regulation of the actin network may be mediated by villin. These results are different from those reported in echinoderm eggs.     

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.     

Paramyxovirus membrane protein enhances antibody production to new antigenic determinants in the actin molecule: a model for virus-induced autoimmunity.

Paramyxovirus membrane (M) protein specifically binds to cellular actin but not to bovine serum albumin or myoglobin, as determined by affinity chromatography and enzyme-linked immunosorbent assay. The binding site for M protein on actin is different from the binding sites for antiactin antibodies. The interaction of M protein with actin resulted in production of antibodies to several new antigenic sites on the actin molecule. Five rabbits immunized with actin alone produced antibodies against the N-terminal sequence (residues 1 to 39). Another five rabbits immunized with a mixture of M protein and actin produced antibodies against a C-terminal fragment and a central region as well as the N-terminal fragment. By immunoblotting with proteolytic fragments of actin, the new antigenic sites were located between amino acid residues 40 to 113, 114 to 226, and 227 to 375. Antisera taken from some patients with recent measles virus infections demonstrated antiactin antibodies to sites other than the N-terminal fragment of actin (amino acids 1 to 39). The interaction of paramyxovirus M protein with actin and the subsequent production of antibodies to new antigenic sites may serve as a model for one of the mechanisms of virus-induced autoimmunity.     

Kinetic evidence for insertion of actin monomers between the barbed ends of actin filaments and barbed end-bound insertin, a protein purified from smooth muscle

An actin polymerization-retarding protein was isolated from chicken gizzard smooth muscle. This protein copurified with vinculin on DEAE-cellulose and gel filtration columns. The polymerization-retarding protein could be separated from vinculin by hydroxylapatite chromatography. The isolated polymerization-retarding protein lost its activity within a few days, but was stable for weeks when it was not separated from vinculin. We termed the polymerization-retarding protein "insertin". Because of the instability of the isolated insertin, we investigated the effect of insertin-vinculin on actin polymerization. Insertin-vinculin retarded nucleated actin polymerization maximally fivefold. Polymerization at the pointed ends of gelsolin-capped actin filaments was not affected by insertin-vinculin, suggesting that insertin-vinculin binds to the barbed ends, but not to the pointed ends, of actin filaments. Retarded polymerization was observed even if the actin monomer concentration was between the critical concentrations of the ends of treadmilling actin filaments. As at this low monomer concentration the pointed ends depolymerize, monomers appeared to be inserted at the barbed ends between the terminal subunit and barbed end-bound insertin molecules. Insertin-vinculin was found not to increase the actin monomer concentration to the value of the pointed ends. These observations support the conclusion that insertin is not a barbed end-capping protein but an actin monomer-inserting protein. According to a quantitative analysis of the kinetic data, all observations could be explained by a model in which two insertin molecules were assumed to bind co-operatively to the barbed ends of actin filaments. Actin monomers were found to be inserted between the barbed ends and barbed end-bound insertin molecules at a rate of about 1 x 10(6) M-1 s-1. Insertin may be an essential part of the machinery of molecules that permit treadmilling of actin filaments in living cells by insertion of actin molecules between membranes and actin filaments.     

Crosslinking of actin filaments and inhibition of actomyosin subfragment-1 ATPase activity by streptococcal M6 protein

M proteins are antiphagocytic molecules on the surface of group A streptococci having physical characteristics similar to those of mammalian tropomyosin. Both are alpha-helical coiled-coil fibrous structures with a similar seven-residue periodicity of nonpolar and charged amino acids. To determine if M protein is functionally similar to tropomyosin we studied the interaction of M protein with F-actin. At low ionic strength, M protein binds to actin weakly with a stoichiometry different from that of tropomyosin. M protein does not compete with tropomyosin for the binding to actin, indicating that it is functionally different from tropomyosin. M protein does compete with myosin subfragment-1 for binding to actin and induces the formation of bundles of actin filaments. The formation of actin aggregates is associated with a sharp reduction in the rate of ATP hydrolysis by subfragment-1. Intact streptococci having M protein on their surface are shown to bind to actin.     

Three-dimensional reconstruction of an actin bundle

We present the three-dimensional structure of an actin filament bundle from the sperm of Limulus. The bundle is a motile structure which by changing its twist, converts from a coiled to an extended form. The bundle is composed of actin plus two auxiliary proteins of molecular masses 50 and 60 kD. Fraying the bundle with potassium thiocyanate created three classes of filaments: actin, actin plus the 60-kD protein, and actin plus both the auxiliary proteins. We examined these filaments by transmission electron microscopy and scanning transmission electron microscopy (STEM). Three-dimensional reconstructions from electron micrographs allowed us to visualize the actin subunit and the 60- and 50-kD subunits bound to it. The actin subunit appears to be bilobed with dimensions 70 X 40 X 35 A. The inner lobe of the actin subunit, located at 20 A radius, is a prolate ellipsoid, 50 X 25 A; the outer actin lobe, at 30 A radius, is a 35-A-diam spheroid. Attached to the inner lobe of actin is the 60-kD protein, an oblate spheroid, 55 X 40 A, at 50 A radius. The armlike 50-kD protein, at 55 A radius, links the 60-kD protein on one of actin's twin strands to the outer lobe of the actin subunit on the opposite strand. We speculate that the 60-kD protein may be a bundling protein and that the 50-kD protein may be responsible for the change in twist of the filaments which causes extension of the bundle.     

Cytochalasin B and the structure of actin gels

We analyzed the structure of gels formed when macrophage actin-binding protein crosslinks skeletal muscle actin polymers and the effect of the fungal metabolite cytochalasin B on this structure. Measurement of the actin filament length distribution permitted calculation of the critical concentration of crosslinker theoretically required for gelation of actin polymer networks. The experimentally determined critical concentration of actin-binding protein agreed sufficiently with the theoretical to conclude that F-actin-actin-binding protein gels are networks composed of isotropically oriented filaments crosslinked at intervals. The effects of cytochalasin B on these actin networks fits this model. Cytochalasin B (1) bound to F-actin (but not to actin-binding protein), (2) decreased the length of actin filaments without increasing the quantity of monomeric actin, (3) decreased the rigidity of actin networks both in the presence and absence of crosslinking proteins and (4) increased the critical concentration of actin-binding protein required for incipient gelation by a magnitude predicted from network theory if filaments were divided and shortened by the extents observed. The effects of cytochalasin B on gelation were highly dependent on actin concentration and were inhibited by the actin-stabilizing agent phalloidin. Therefore, cytochalasin B diminishes actin gel structure by severing actin filaments at limited sites. The demonstration of gel-sol transformations in actin networks caused by limited actin filament cleavage suggests a new mechanism for the control of cytoplasmic structure.     

A balance of capping protein and profilin functions is required to regulate actin polymerization in Drosophila bristle

Profilin is a well-characterized protein known to be important for regulating actin filament assembly. Relatively few studies have addressed how profilin interacts with other actin-binding proteins in vivo to regulate assembly of complex actin structures. To investigate the function of profilin in the context of a differentiating cell, we have studied an instructive genetic interaction between mutations in profilin (chickadee) and capping protein (cpb). Capping protein is the principal protein in cells that caps actin filament barbed ends. When its function is reduced in the Drosophila bristle, F-actin levels increase and the actin cytoskeleton becomes disorganized, causing abnormal bristle morphology. chickadee mutations suppress the abnormal bristle phenotype and associated abnormalities of the actin cytoskeleton seen in cpb mutants. Furthermore, overexpression of profilin in the bristle mimics many features of the cpb loss-of-function phenotype. The interaction between cpb and chickadee suggests that profilin promotes actin assembly in the bristle and that a balance between capping protein and profilin activities is important for the proper regulation of F-actin levels. Furthermore, this balance of activities affects the association of actin structures with the membrane, suggesting a link between actin filament dynamics and localization of actin structures within the cell.     

Interactions with PIP2, ADP-actin monomers, and capping protein regulate the activity and localization of yeast twinfilin

Twinfilin is a ubiquitous actin monomer-binding protein that regulates actin filament turnover in yeast and mammalian cells. To elucidate the mechanism by which twinfilin contributes to actin filament dynamics, we carried out an analysis of yeast twinfilin, and we show here that twinfilin is an abundant protein that localizes to cortical actin patches in wild-type yeast cells. Native gel assays demonstrate that twinfilin binds ADP-actin monomers with higher affinity than ATP-actin monomers. A mutant twinfilin that does not interact with actin monomers in vitro no longer localizes to cortical actin patches when expressed in yeast, suggesting that the ability to interact with actin monomers may be essential for the localization of twinfilin. The localization of twinfilin to the cortical actin cytoskeleton is also disrupted in yeast strains where either the CAP1 or CAP2 gene, encoding for the alpha and beta subunits of capping protein, is deleted. Purified twinfilin and capping protein form a complex on native gels. Twinfilin also interacts with phosphatidylinositol 4,5-bisphosphate (PI[4,5]P2), and its actin monomer-sequestering activity is inhibited by PI(4,5)P2. Based on these results, we propose a model for the biological role of twinfilin as a protein that localizes actin monomers to the sites of rapid filament assembly in cells.