The amino-terminal fragment of gelsolin is cross-linked to Cys-374 of actin in the EGTA-resistant actin-gelsolin complex.

It has been shown that the EGTA-resistant actin, one of the two actin molecules associated to gelsolin, can be predominantly cross-linked to gelsolin by benzophenone-4-maleimide (BPM), a photoaffinity-labeling reagent, which was conjugated to Cys-374 of actin prior to cross-linking (Doi, Y., Banba, M. and Vertut-Do?, A. (1991) Biochemistry 30, 5769-5777). When a chymotryptic digest of gelsolin containing the amino-terminal 15-kDa fragment was mixed with BPM-actin (42 kDa) and irradiated for cross-linking, a band of 58 kDa appeared on SDS-PAGE which was shown to contain actin molecule by using fluorescently labeled actin. The amino-terminal sequence of the 58-kDa complex was identical to that of gelsolin, confirming that the amino-terminal segment (residues 1-133) of pig plasma gelsolin lies closely to Cys-374 of actin in the EGTA-resistant complex.     

Three-dimensional image analysis of the complex of thin filaments and myosin molecules from skeletal muscle. V. Assignment of actin in the actin-tropomyosin-myosin subfragment-1 complex

To assign the actin molecule in the three-dimensional image of the actin-tropomyosin-myosin subfragment-1 (actin-TM-S1) complex, the three-dimensional image of the actin-tropomyosin complex was correlated to that of actin-TM-S1. To assess the similarity of two structures in a quantitative manner, we used a normalized cross-correlation function ("similarity function"). The calculation of similarity indicated that domain A and domain B defined in (1, 2) correspond to actin-tropomyosin. This assignment indicates that one S1 molecule strongly interacts with only one actin molecule, but at least two regions of S1 contribute to the binding. Comparison of the reconstituted models of thin filaments with those of decorated thin filaments suggested a change in the shape of the actin molecule.     

Cysteine-374 of actin resides at the gelsolin contact site in the EGTA-resistant actin-gelsolin complex.

The interaction of pig plasma gelsolin (G) and actin (A) was examined by using photoreactive 4-maleimidobenzophenone-actin (BPM-actin) in which BPM was previously conjugated to Cys-374 of actin through the maleimide moiety. In the presence of micromolar [Ca2+], the major cross-linked product observed after irradiation of the mixture of gelsolin (82 kDa) and actin (42 kDa) had an apparent molecular mass of 130 kDa although gelsolin predominantly existed in the form of an A2G complex (170 kDa). No cross-linked product was detected in the absence of Ca2+. BPM-actin itself did not give any cross-linked product. By use of fluorescent-labeled gelsolin, the cross-linked 130 kDa was shown to be an AG complex. The cross-linked complex was also formed from the A2G complex after removal of Ca2+ by [ethylenebis-(oxyethylenenitrilo)]tetraacetic acid (EGTA) followed by irradiation, indicating that it was the EGTA-resistant AG complex that was cross-linked. The results show that Cys-374 at the C-terminal segment of actin in the EGTA-resistant AG complex is 9-10 A apart from gelsolin. Furthermore, it was shown that the EGTA-resistant actin molecule once incorporated in the A2G complex did not exchange with free actin in the presence of Ca2+. This was also supported by the effect of phosphatidylinositol 4,5-bisphosphate, which did not dissociate the EGTA-resistant actin molecule from the A2G complex in the presence of Ca2+, but did after removal of Ca2+.     

Phalloidin and tropomyosin do not prevent actin filament shortening by the 90 kD protein-actin complex from brain

Previously we reported the purification from bovine brain of the 90 kD protein-actin complex that shortens actin filaments. In the present work we study the effect of this complex on actin polymerized in the presence of phalloidin (PL) or tropomyosin (TM) which are known to stabilize actin filaments. The effect of the complex has been compared with that of cytochalasin D (CD), a fungal metabolite that also shortens actin filaments. Low shear viscosimetry and electron microscopy showed that PL or TM could not prevent the shortening of actin filaments in the presence of 90 kD protein-actin complex whereas they effectively protected actin filaments from shortening by CD. We conclude that the 90 kD protein-actin complex is a more potent filament-shortening factor than CD.     

Physarum actin is phosphorylated as the actin-fragmin complex at residues Thr203 and Thr202 by a specific 80 kDa kinase.

The Physarum EGTA-resistant actin-fragmin complex, previously named cap 42(a+b), is phosphorylated in the actin subunit by an endogenous kinase [Maruta and Isenberg (1983) J. Biol. Chem., 258, 10151-10158]. This kinase has been purified and characterized. It is an 80 kDa monomeric enzyme, unaffected by known kinase regulators. Staurosporine acts as a potent inhibitor. The actin-fragmin complex is the preferred substrate. The phosphorylation is inhibited by micromolar Ca2+ concentrations, but only in the presence of additional actin. Polymerized actin (vertebrate muscle and non-muscle isoforms) and actin complexes with various actin-binding proteins are poorly phosphorylated. The heterotrimer consisting of two actins and one fragmin, which is formed from cap 42(a+b) and actin in the presence of micromolar concentrations of Ca2+, is also a poor substrate. From the other substrates tested, only histones were significantly phosphorylated, in particular histone H1. In the same manner, casein kinase I could also phosphorylate the actin-fragmin complex. The major phosphorylation site in actin is Thr203. A second minor site is Thr202. These residues constitute one of the contact sites for DNase I [Kabsch et al. (1990) Nature, 347, 37-44] and are also part of one of the predicted actin-actin contact sites in the F-actin model [Holmes et al. (1990) Nature, 347, 44-49].     

Crystal structure of the complex between actin and human vitamin D-binding protein at 2.5 A resolution

A high-affinity complex formed between G-actin and plasma vitamin D-binding protein (DBP) is believed to form part of a scavenging system in the plasma for removing actin released from damaged cells. In the study presented here, we describe the crystal structure of the complex between actin and human vitamin D-binding protein at 2.5 A resolution. The complex contains one molecule of each protein bound together by extensive ionic, polar, and hydrophobic interactions. It includes an ATP and a calcium ion bound to actin, but no evidence of vitamin D metabolites bound to the DBP. Both actin and DBP are multidomain molecules, two major domains in actin and three in DBP. All of these domains contribute to the interaction between the molecules. DBP enfolds the end of the actin molecule, principally in actin subdomain 3 but with additional interactions in actin subdomain 1. This orientation is similar to the binding of profilin to actin, as predicted from previous studies. The more extensive interactions of DBP give an affinity for actin some 3 orders of magnitude higher than that for profilin. The larger "footprint" of DBP on actin also leads to an overlap with the actin-binding site of gelsolin domain I.     

The interaction between N-WASP and the Arp2/3 complex links Cdc42-dependent signals to actin assembly

Although small GTP-binding proteins of the Rho family have been implicated in signaling to the actin cytoskeleton, the exact nature of the linkage has remained obscure. We describe a novel mechanism that links one Rho family member, Cdc42, to actin polymerization. N-WASP, a ubiquitously expressed Cdc42-interacting protein, is required for Cdc42-stimulated actin polymerization in Xenopus egg extracts. The C terminus of N-WASP binds to the Arp2/3 complex and dramatically stimulates its ability to nucleate actin polymerization. Although full-length N-WASP is less effective, its activity can be greatly enhanced by Cdc42 and phosphatidylinositol (4,5) bisphosphate. Therefore, N-WASP and the Arp2/3 complex comprise a core mechanism that directly connects signal transduction pathways to the stimulation of actin polymerization.     

pH-dependent rate of formation of the gelsolin-actin complex from gelsolin and monomeric actin

The assembly of gelsolin with actin was followed by the increase of the fluorescence intensity of a fluorescence label bound to actin. The time course of the formation of the gelsolin-actin complex in the presence of micromolar [Ca2+] could be quantitatively interpreted by a model in which one actin molecule binds slowly to gelsolin in a rate-determining step and subsequently a second actin molecule is bound at least 40 times more rapidly. The rate of binding of the first actin molecule to gelsolin was found to be remarkably slow and to depend on the pH. The rate constants of formation of the gelsolin-actin complex range from 1.5 X 10(4) M-1 s-1 at pH 8 to 7 X 10(4) M-1 s-1 at pH 6.     

Crystallization of the complex of actin with gelsolin segment 1.

Crystals of a 1:1 complex between human gelsolin segment 1 and actin have been grown from solutions containing polyethylene glycol 6000. The crystals are orthorhombic, space group P2(1)2(1)2(1); the axes are a = 57.4 A, b = 70.4 A, c = 184.5 A. They are moderately stable to X-rays and diffract to beyond 2.5 A. There is one molecule of complex in the asymmetric unit.     

Rate constants and equilibrium constants for binding of actin to the 1:1 gelsolin-actin complex.

The rate constant and equilibrium constant of association of an actin monomer with 1:1 gelsolin-actin complex isolated from chicken were measured by using fluorescently labeled actin. According to fluorescence stopped-flow experiments, the rate constant of formation of the 1:2 gelsolin-actin complex from 1:1 gelsolin-actin complex and actin was found to be about 2 x 10(7) M-1 s-1 under conditions where gelsolin binds Ca2+. The rate of dissociation of one actin molecule from the 1:2 gelsolin-actin complex was determined by exchange of actin for fluorescently labeled actin. The rate constant of dissociation was about 0.02 s-1. Thus, the equilibrium constant for association of actin with 1:1 gelsolin-actin complex can be calculated to be in the range of 10(9) M-1. The rate of dissociation of actin from 1:2 gelsolin-actin complex was independent of the Ca2+ concentration. Ca2+ affects only the rate of association of actin with 1:1 gelsolin-actin complex.     

The world according to Arp: regulation of actin nucleation by the Arp2/3 complex.

The coordination of cell shape change and locomotion requires that actin polymerization at the cell cortex be tightly controlled in response to both intracellular and extracellular cues. The Arp2/3 complex - an actin filament nucleating and organizing factor - appears to be a central player in the cellular control of actin assembly. Recently, a molecular pathway leading from key signalling molecules to actin filament nucleation by the Arp2/3 complex has been discovered. In this pathway, the GTPase Cdc42 acts in concert with WASP family proteins to activate the Arp2/3 complex. These findings have led to a more complete picture of the mechanism of actin filament generation and organization during cell motility.     

Toca-1 mediates Cdc42-dependent actin nucleation by activating the N-WASP-WIP complex

An important signaling pathway to the actin cytoskeleton links the Rho family GTPase Cdc42 to the actin-nucleating Arp2/3 complex through N-WASP. Nevertheless, these previously identified components are not sufficient to mediate Cdc42-induced actin polymerization in a physiological context. In this paper, we describe the biochemical purification of Toca-1 (transducer of Cdc42-dependent actin assembly) as an essential component of the Cdc42 pathway. Toca-1 binds both N-WASP and Cdc42 and is a member of the evolutionarily conserved PCH protein family. Toca-1 promotes actin nucleation by activating the N-WASP-WIP/CR16 complex, the predominant form of N-WASP in cells. Thus, the cooperative actions of two distinct Cdc42 effectors, the N-WASP-WIP complex and Toca-1, are required for Cdc42-induced actin assembly. These findings represent a significantly revised view of Cdc42-signaling and shed light on the pathogenesis of Wiskott-Aldrich syndrome.     

Shape of the myosin head in the rigor complex. Three-dimensional image reconstruction of the actin-tropomyosin-heavy meromyosin complex

The structure of the actin-tropomyosin-heavy meromyosin rigor complex was studied by image analysis of electron micrographs. The arrowhead of the rigor complex has a whisker-like structure with a dense turning point at the "barb" of the arrowhead. The neck region of the myosin head in the reconstructed three-dimensional image is present in the area corresponding to the dense point. It is concluded that at least one extra-thin area contributes to the neck region, and that the two heads in the heavy meromyosin molecule join a double helical rope beyond the end of the large head (G in this study). (This is different from previous interpretations). It is also concluded that the heavy meromyosin has a short bent part near the head/rod junction in the rigor complex.     

Cdc42 induces filopodia by promoting the formation of an IRSp53:Mena complex.

BACKGROUND: The Rho GTPases Rho, Rac, and Cdc42 regulate the organization of the actin cytoskeleton by interacting with multiple, distinct downstream effector proteins. Cdc42 controls the formation of actin bundle-containing filopodia at the cellular periphery. The molecular mechanism for this remains as yet unclear. RESULTS: We report here that Cdc42 interacts with IRSp53/BAP2 alpha, an SH3 domain-containing scaffold protein, at a partial CRIB motif and that an N-terminal fragment of IRSp53 binds, via an intramolecular interaction, to the CRIB motif-containing central region. Overexpression of IRSp53 in fibroblasts leads to the formation of filopodia, and both this and Cdc42-induced filopodia are inhibited by expression of the N-terminal IRSp53 fragment. Using affinity chromatography, we have identified Mena, an Ena/VASP family member, as interacting with the SH3 domain of IRSp53. Mena and IRSp53 act synergistically to promote filopodia formation. CONCLUSION: We conclude that the interaction of Cdc42 with the partial CRIB motif of IRSp53 relieves an intramolecular, autoinhibitory interaction with the N terminus, allowing the recruitment of Mena to the IRSp53 SH3 domain. This IRSp53:Mena complex initiates actin filament assembly into filopodia.     

Biochemical characterization of complex formation by human erythrocyte spectrin, protein 4.1, and actin

Ternary complex formation between the major human erythrocyte membrane skeletal proteins spectrin, protein 4.1, and actin was quantified by measuring cosedimentation of spectrin and band 4.1 with F-actin. Complex formation was dependent upon the concentration of spectrin and band 4.1, each of which promoted the binding of the other to F-actin. Simultaneous measurement of the concentrations of spectrin and band 4.1 in the sedimentable complex showed that a single molecule of band 4.1 was sufficient to promote the binding of a spectrin dimer to F-actin. However, the molar ratio of band 4.1/spectrin in the complex was not fixed, ranging from approximately 0.6 to 2.2 as the relative concentration of added spectrin to band 4.1 was decreased. A mole ratio of 0.6 band 4.1/spectrin suggests that a single molecule of band 4.1 can promote the binding of more than one spectrin dimer to an actin filament. Saturation binding studies showed that in the presence of band 4.1 every actin monomer in a filament could bind at least one molecule of spectrin, yielding ternary complexes with spectrin/actin mole ratios as high as 1.4. Electron microscopy of such complexes showed them to consist of actin filaments heavily decorated with spectrin dimers. Ternary complex formation was not affected by alteration in Mg2+ or Ca2+ concentration but was markedly inhibited by KCl above 100 mM and nearly abolished by 10 mM 2,3-diphosphoglycerate or 10 mM adenosine 5'-triphosphate. Our data are used to refine the molecular model of the red cell membrane skeleton.     

Domain-specific chaperone-induced expansion is required for beta-actin folding: a comparison of beta-actin conformations upon interactions with GroEL and tail-less complex polypeptide 1 ring complex (TRiC)

Actin, an abundant cytosolic protein in eukaryotic cells, is dependent on the interaction with the chaperonin tail-less complex polypeptide 1 ring complex (TRiC) to fold to the native state. The prokaryotic chaperonin GroEL also binds non-native beta-actin, but is unable to guide beta-actin toward the native state. In this study we identify conformational rearrangements in beta-actin, by observing similarities and differences in the action of the two chaperonins. A cooperative collapse of beta-actin from the denatured state to an aggregation-prone intermediate is observed, and insoluble aggregates are formed in the absence of chaperonin. In the presence of GroEL, however, >90% of the aggregation-prone actin intermediate is kept in solution, which shows that the binding of non-native actin to GroEL is effective. The action of GroEL on bound flourescein-labeled beta-actin was characterized, and the structural rearrangement was compared to the case of the beta-actin-TRiC complex, employing the homo fluorescence resonance energy transfer methodology previously used [Villebeck, L., Persson, M., Luan, S.-L., Hammarstr?m, P., Lindgren, M., and Jonsson, B.-H. (2007) Biochemistry 46 (17), 5083-93]. The results suggest that the actin structure is rearranged by a "binding-induced expansion" mechanism in both TRiC and GroEL, but that binding to TRiC, in addition, causes a large and specific separation of two subdomains in the beta-actin molecule, leading to a distinct expansion of its ATP-binding cleft. Moreover, the binding of ATP and GroES has less effect on the GroEL-bound beta-actin molecule than the ATP binding to TRiC, where it leads to a major compaction of the beta-actin molecule. It can be concluded that the specific and directed rearrangement of the beta-actin structure, seen in the natural beta-actin-TRiC system, is vital for guiding beta-actin to the native state.     

Ca2+-dependent actin-binding phosphoprotein in Physarum polycephalum. Subunit b is a DNase I-binding and F-actin capping protein

Physarum contains at least two distinct DNase I-binding proteins, i.e. actin and Cap 42 (a + b). The latter, a tight (1:1) complex of Cap 42 (a) and Cap 42 (b) (Maruta, H., Isenberg. G., Schreckenbach, T., Hallmann, R., Risse, G., Schibayama, T., and Hesse, J. (1983) J. Biol. Chem. 258, 10144-10150), is a Ca2+-dependent F-actin capping protein. DNase I binds to Cap 42 (b) but not to Cap 42 (a). Consequently, DNase I-agarose was used for an affinity-purification of Cap 42 (a + b), after its separation from actin by DEAE-cellulose chromatography. Cap 42 (a + b) was dissociated into its subunits when released from DNase I-agarose by 8.8 M formamide. The two subunits were subsequently separated from each other on hydroxylapatite. Both Cap 42 (a) and Cap 42 (b) were Ca2+-dependent F-actin capping proteins that cap the fast growing end of actin filaments and block actin polymerization at this end. Like Cap 42 (a + b), Cap 42 (b) required Ca2+ for its capping activity only when phosphorylated. The phosphorylation of Cap 42 (b) was completely blocked by DNase I or a tertiary complex of Cap 42 (a), actin, and Ca2+. Cap 42 (b) is not identical with native (= polymerizable) actin because (i) Cap 42 (b) was unable to form filaments, (ii) the Cap 42 (b) kinase did not phosphorylate native actin, and (iii) fragmin formed a tight (1:1) complex with native actin but not with Cap 42 (b). Although it is unlikely that Cap 42 (b) is simply a denatured form of actin that has lost its polymerizability during the preparation, it still remains to be clarified whether Cap 42 (b) is a nonpolmerizable actin variant derived from a distinct actin gene or a post-translationally modified form of polymerizable actin.     

A novel type of protein kinase phosphorylates actin in the actin-fragmin complex.

Actin-fragmin kinase (AFK) from Physarum polycephalum specifically phosphorylates actin in the EGTA-resistant 1:1 actin-fragmin complex. The cDNA deduced amino acid sequence reveals two major domains of approximately 35 kDa each that are separated by a hinge-like proline/serine-rich segment of 50 residues. Whereas the N-terminal domain does not show any significant similarity to protein sequences from databases, there are six complete kelch repeats in the protein that comprise almost the entire C-terminal half of the molecule. To prove the intrinsic phosphorylation activity of AFK, full-length or partial cDNA fragments were expressed both in a reticulocyte lysate and in Escherichia coli. In both expression systems, we obtained specific actin phosphorylation and located the catalytic domain in the N-terminal half. Interestingly, this region did not contain any of the known protein kinase consensus sequences. The only known sequence motif present that could have been involved in nucleotide binding was a nearly perfect phosphate binding loop (P-loop). However, introduction of two different point mutations into this putative P-loop sequence did not alter the catalytic activity of the kinase, which indicates an as yet unknown mechanism for phosphate transfer. Our data suggest that AFK belongs to a new class of protein kinases and that this actin phosphorylation might be the first example of a widely distributed novel type of regulation of the actin cytoskeleton in non-muscle cells.     

Distribution of the cadherin-catenin complex in normal human thyroid epithelium and a thyroid carcinoma cell line

E-cadherin is the major cell-cell adhesion molecule expressed by epithelial cells. Cadherins form a complex with three cytoplasmic proteins, α-, β-, and γ-catenin, and the interaction between them is crucial for anchoring the actin cytoskeleton to the intercellular adherens junctions. The invasive behavior of cancer cells has been attributed to a dysfunction of these molecules. In this study, we examined the distribution of the cadherin-catenin complex in a Chinese human thyroid cancer cell line, CGTH W-2, compared with that in normal human thyroid epithelial cells. In the normal cells, using immunofluorescence staining, E-cadherin and α-, β-, and γ-catenin were found to be localized at the intercellular junction and appeared as 135, 102, 90, and 80 kD proteins on Western blots. In CGTH W-2 cells, no E-cadherin and γ-catenin immunoreactivity was detected by immunofluorescence or Western blotting; α- and β-catenin were detected as 102 and 90 kD proteins on blots but gave a diffuse cytoplasmic immunofluorescence staining pattern in most cells, while β-catenin was also distributed throughout the cytoplasm in most cells but was found at the cell junction in some, where it colocalized with α-actinin. The present data indicate that the loss of cell adhesiveness in these cancer cells may be due to incomplete assembly of the cadherin-catenin complex at the cell junction. However, this defect did not affect the linkage of actin bundles to vinculin-enriched intercellular junctions. J. Cell. Biochem. 70:330–337, 1998. © 1998 Wiley-Liss, Inc.     

Cdc42-dependent actin dynamics controls maturation and secretory activity of dendritic cells

Cell division cycle 42 (Cdc42) is a member of the Rho guanosine triphosphatase family and has pivotal functions in actin organization, cell migration, and proliferation. To further study the molecular mechanisms of dendritic cell (DC) regulation by Cdc42, we used Cdc42-deficient DCs. Cdc42 deficiency renders DCs phenotypically mature as they up-regulate the co-stimulatory molecule CD86 from intracellular storages to the cell surface. Cdc42 knockout DCs also accumulate high amounts of invariant chain–major histocompatibility complex (MHC) class II complexes at the cell surface, which cannot efficiently present peptide antigens (Ag’s) for priming of Ag-specific CD4 T cells. Proteome analyses showed a significant reduction in lysosomal MHC class II–processing proteins, such as cathepsins, which are lost from DCs by enhanced secretion. As these effects on DCs can be mimicked by chemical actin disruption, our results propose that Cdc42 control of actin dynamics keeps DCs in an immature state, and cessation of Cdc42 activity during DC maturation facilitates secretion as well as rapid up-regulation of intracellular molecules to the cell surface.