Mechanisms of formin-mediated actin assembly and dynamics

Cellular viability requires tight regulation of actin cytoskeletal dynamics. Distinct families of nucleation-promoting factors enable the rapid assembly of filament nuclei that elongate and are incorporated into diverse and specialized actin-based structures. In addition to promoting filament nucleation, the formin family of proteins directs the elongation of unbranched actin filaments. Processive association of formins with growing filament ends is achieved through continuous barbed end binding of the highly conserved, dimeric formin homology (FH) 2 domain. In cooperation with the FH1 domain and C-terminal tail region, FH2 dimers mediate actin subunit addition at speeds that can dramatically exceed the rate of spontaneous assembly. Here, I review recent biophysical, structural, and computational studies that have provided insight into the mechanisms of formin-mediated actin assembly and dynamics.     

Mechanisms of actin rearrangements mediating platelet activation.

The detergent-insoluble cytoskeleton of the resting human blood platelet contains approximately 2,000 actin filaments approximately 1 micron in length crosslinked at high angles by actin-binding protein and which bind to a spectrin-rich submembrane lamina (Fox, J., J. Boyles, M. Berndt, P. Steffen, and L. Anderson. 1988. J. Cell Biol. 106:1525-1538; Hartwig, J., and M. DeSisto. 1991. J. Cell Biol. 112:407-425). Activation of the platelets by contact with glass results within 30 s in a doubling of the polymerized actin content of the cytoskeleton and the appearance of two distinct new actin structures: bundles of long filaments within filopodia that end at the filopodial tips (filopodial bundles) and a circumferential zone of orthogonally arrayed short filaments within lamellipodia (lamellipodial network). Neither of these structures appears in cells exposed to glass with cytochalasin B present; instead the cytoskeletons have numerous 0.1-0.3-microns-long actin filament fragments attached to the membrane lamina. With the same time course as the glass-induced morphological changes, cytochalasin-sensitive actin nucleating activity, initially low in cytoskeletons of resting platelets, increases 10-fold in cytoskeletons of thrombin-activated platelets. This activity decays with a time course consistent with depolymerization of 0.1-0.3-microns-long actin filaments, and phalloidin inhibits this decay. Cytochalasin-insensitive and calcium-dependent nucleation activity also increases markedly in platelet extracts after thrombin activation of the cells. Prevention of the rise in cytosolic Ca2+ normally associated with platelet activation with the permeant Ca2+ chelator, Quin-2, inhibits formation of lamellipodial networks but not filopodial bundles after glass contact and reduces the cytochalasin B-sensitive nucleation activity by 60% after thrombin treatment. The filopodial bundles, however, are abnormal in that they do not end at the filopodial tips but form loops and return to the cell body. Addition of calcium to chelated cells restores lamellipodial networks, and calcium plus A23187 results in cytoskeletons with highly fragmented actin filaments within seconds. Immunogold labeling with antibodies against gelsolin reveals gelsolin molecules at the ends of filaments attached to the submembrane lamina of resting cytoskeletons and at the ends of some filaments in the lamellipodial networks and filopodial bundles of activated cytoskeletons. Addition of monomeric actin to myosin subfragment 1-labeled activated cytoskeletons leads to new (undecorated) filament growth off the ends of filaments in the filopodial bundles and the lamellipodial network. The simplest explanation for these findings is that gelsolin caps the barbed ends of the filaments in the resting platelet. Uncapping some of these filaments after activation leads to filopodial bundles.(ABSTRACT TRUNCATED AT 400 WORDS)     

Role of actin binding protein phosphorylation in platelet cytoskeleton assembly

Actin binding protein from human blood platelets is shown to exist in the resting platelet as a phosphorylated protein and contains two residues of phosphate per 260,000 kd. Removal of one-half of these residues with E. coli alkaline phosphatase results in the loss of its ability to crosslink F-actin into a low speed sedimentable complex (its cytoskeleton) and to bind to an F-actin affinity column. Thus, phosphorylation-dephosphorylation of ABP may be an important regulatory mechanism by which the platelet regulates its shape via its cytoskeletal structure.     

Regulating cellular actin assembly

Cellular actin assembly is tightly regulated. The study of pathogen motility has led to the identification of several cellular factors that are critical for controlling this process. Pathogens such as Listeria require Ena/VASP and Arp2/3 proteins to translate actin polymerization into movement. Recent work has extended these observations and uncovered some similarities and surprising differences in the way cells and pathogens utilize the actin cytoskeleton.     

Mechanisms of actin disassembly

The actin cytoskeleton is constantly assembling and disassembling. Cells harness the energy of these turnover dynamics to drive cell motility and organize cytoplasm. Although much is known about how cells control actin polymerization, we do not understand how actin filaments depolymerize inside cells. I briefly describe how the combination of imaging actin filament dynamics in cells and using in vitro biochemistry progressively altered our views of actin depolymerization. I describe why I do not think that the prevailing model of actin filament turnover—cofilin-mediated actin filament severing—can account for actin filament disassembly detected in cells. Finally, I speculate that cells might be able to tune the mechanism of actin depolymerization to meet physiological demands and selectively control the stabilities of different actin arrays.     

Microtubule tips redirect actin assembly

In fission yeast, a protein complex that rides on the plus end of growing microtubules regulates establishment of new sites of actin cable assembly, necessary for cell growth, from one to both ends of the rod-shaped cells. Martin et al. describe a direct molecular link between the microtubule tip complex and the formin for3p, the nucleator for assembly of actin cables, which is necessary for this regulatory switch.     

Molecular details of formin-mediated actin assembly

Formins are a large family of multi-domain polypeptides that form homodimers. The highly conserved formin homology 2 (FH2) domain and its neighboring formin homology 1 (FH1) domain, which are surrounded by regulatory domains, cooperate in rapidly assembling profilin-actin into long filaments while remaining continuously associated with the fast-growing barbed end. Recent biochemical, biophysical, theoretical and structural studies have concluded that diverse formins are mechanistically similar, but that the rates of various assembly states differ quantitatively, and have shed light on the mechanism of formin auto-regulation and activation by Rho GTPases.     

Mechanisms of platelet production

The precise mechanism by which platelets are formed from megakaryocytes (MK) remains unclear, despite numerous studies which have been performed during this century. Models have been proposed that attempt to account for platelet formation from disruption of elongated processes of MK cytoplasm, designated proplatelets, or by fragmentation of MK cytoplasm. MK demarcation membranes are hypothesized by some investigators to delineate platelet territories in the MK cytoplasm, and by others to act as a membrane reservoir for MK process formation. Platelet production has been variously speculated to occur primarily in the bone marrow or lung. Each theory or model has attempted to elucidate the phenomenon of size heterogeneity of circulating platelets and the changes that occur under conditions of altered thrombopoiesis. In this article, we have analyzed and compared the characteristics of previously proposed models for platelet production and suggested additional techniques for future studies of thrombopoiesis.     

Doxorubicin affects actin assembly in vitro

In vitro experiments on actin polymerization in the presence of doxorubicin show that the rate of salt-induced actin assembly is negatively affected by the drug. The decreased amount of actin monomers keeping their ability to self-interact to give F actin (microfilaments) probably explains the reduction of assembly value. Drug action is dose-dependent and various discrepancies are explained by the limitations of the techniques used.     

The actin cytoskeleton in presynaptic assembly

Dramatic morphogenetic processes underpin nearly every step of nervous system development, from initial neuronal migration and axon guidance to synaptogenesis. Underlying this morphogenesis are dynamic rearrangements of cytoskeletal architecture. Here we discuss the roles of the actin cytoskeleton in the development of presynaptic terminals, from the elaboration of terminal arbors to the recruitment of presynaptic vesicles and active zone components. The studies discussed here underscore the importance of actin regulation at every step in neuronal circuit assembly.     

Mechanism of K+-induced actin assembly

The assembly of highly purified actin from Dictyostelium discoideum amoebae and rabbit skeletal muscle by physiological concentrations of KCI proceeds through successive stages of (a) rapid formation of a distinct monomeric species referred to as KCI-monomer, (b) incorporation of KCI-monomers into an ATP-containing filament, and (c) ATP hydrolysis that occurs significantly after the incorporation event. KCI-monomer has a conformation which is distinct from that of either conventional G- or F-actin, as judged by UV spectroscopy at 210-220 nm and by changes in ATP affinity. ATP is not hydrolyzed during conversion of G-actin to KCI-monomer. KCI-monomer formation precedes filament formation and may be necessary for the assembly event. Although incorporation of KCI-monomers into filaments demonstrates lagphase kinetics by viscometry, both continuous absorbance monitoring at 232 nm and rapid sedimentation of filaments demonstrate hyperbolic assembly curves. ATP hydrolysis significantly lags the formation of actin filaments. When half of the actin has assembled, only 0.1 to 0.2 mole of ATP are hydrolyzed per mole of actin present as filaments.     

Association of actin with the platelet membrane

Human platelet membrane-actin associations were studied by means of differential extraction of purified membranes and low-shear viscometry of membrane-F-actin mixtures. As indicated by resistance to extraction with 0.6 M potassium iodide, a significant amount of platelet actin appears to be tightly associated with the membrane. When tested by falling-ball viscometry, both whole and KI-extracted membranes increased the low-shear viscosity of preformed rabbit skeletal muscle F-actin at physiologically reasonable pH and ionic conditions. This membrane-associated actin gelation activity was dependent upon low free calcium concentration (10(-8)-10(-7) M). The results are consistent with specific associations between actin and platelet membranes and may be relevant to membrane-cytoskeletal interactions believed to occur in the intact cell.     

Mechanisms of spatial segregation of actin isoforms

Actin sequences are conserved to a much greater degree than those in almost any other proteins, so that two cytoplasmic isoforms differ by only four of 374 amino acid residues. Nevertheless, the results of biochemical, immunocytochemical and molecular biology experiments demonstrate that appearance, amount and localization of actin isoforms are strongly controlled by cell machinery. Although at the early stages of cell differentiation expression of any actin gene is potentially possible, under normal physiological conditions, while differentiation proceeds, synthesis of specific actin isoforms is temporally regulated and the produced proteins are segregated spatially. Pathological situations of tissue injury or mammalian disease correlate either with up- and down-regulation of distinct actin genes returning to a fetal gene program or with a failure to sort actin isoforms. Different actin isoforms cannot substitute for each other, and changes in expression of specific actin genes are accompanied by alterations in cell structure and function suggesting that specific actin isoforms perform unique cellular functions. This article summarizes the data on segregation of actin isoforms in cell compartments and analyses the mechanisms suggested to explain spatial segregation of cytoplasmic actin isoforms within a cell.     

Mechanisms of spatial segregation of actin isoforms

Actin sequences are conserved to a much greater degree than those of almost any other proteins, such that two cytoplasmic isoforms differ by only 4 out of 374 amino acid residues. Nevertheless, the results of biochemical, immunocytochemical, and molecular biology experiments demonstrate that the appearance, amount, and localization of actin isoforms are strongly controlled by the cellular machinery. Although at the early stages of cell differentiation expression of any actin gene is potentially possible, under normal physiological conditions, while differentiation proceeds, synthesis of specific actin isoforms is temporally regulated and the produced proteins are segregated spatially. Pathological situations of a tissue injury or a mammalian disease correlate either with up-and down-regulation of distinct actin genes returning to a fetal gene program or with a failure to sort actin isoforms. Different actin isoforms cannot substitute for each other, and changes in the expression of specific actin genes are accompanied by alterations in cell structure and function, suggesting that specific actin isoforms perform unique cellular functions. This article summarizes the data on the segregation of actin isoforms in cell compartments and analyzes the mechanisms suggested to explain spatial segregation of cytoplasmic actin isoforms in the cell.     

Profilin connects actin assembly with microtubule dynamics

Profilin controls actin nucleation and assembly processes in eukaryotic cells. Actin nucleation and elongation promoting factors (NEPFs) such as Ena/VASP, formins, and WASP-family proteins recruit profilin:actin for filament formation. Some of these are found to be microtubule associated, making actin polymerization from microtubule-associated platforms possible. Microtubules are implicated in focal adhesion turnover, cell polarity establishment, and migration, illustrating the coupling between actin and microtubule systems. Here we demonstrate that profilin is functionally linked to microtubules with formins and point to formins as major mediators of this association. To reach this conclusion, we combined different fluorescence microscopy techniques, including superresolution microscopy, with siRNA modulation of profilin expression and drug treatments to interfere with actin dynamics. Our studies show that profilin dynamically associates with microtubules and this fraction of profilin contributes to balance actin assembly during homeostatic cell growth and affects micro­tubule dynamics. Hence profilin functions as a regulator of microtubule (+)-end turnover in addition to being an actin control element.     

Calcium control of Saccharomyces cerevisiae actin assembly.

Low levels of Ca2+ dramatically influence the polymerization of Saccharomyces cerevisiae actin in KCl. The apparent critical concentration for polymerization (C infinity) increases eightfold in the presence of 0.1 mM Ca2+. This effect is rapidly reversed by the addition of ethylene glycol bis(beta-aminoethyl ether)-N,N'-tetraacetic acid or of 0.1 mM Mg2+. Furthermore, the addition of Ca2+ to polymerized actin causes a reversible increase in the apparent C infinity. In the presence of Ca2+, at actin concentrations below the apparent C infinity, particles of 15 to 50 nm in diameter are seen instead of filaments. These particles are separated from soluble actin when Ca2+-treated filamentous actin is sedimented at high speed; both the soluble and particulate fractions retain Ca2+-sensitive polymerization. The Ca2+ effect is S. cerevisiae actin-specific: the C infinity for rabbit muscle actin is not affected by the presence of Ca2+ and S. cerevisiae actin. Ca2+ may act directly on S. cerevisiae actin to control the assembly state in vivo.     

Important role of raft aggregation in the signaling events of cold-induced platelet activation

When human platelets are chilled below 20 degrees C, they undergo cold-induced activation. We have previously shown that cold activation correlates with the main phospholipid phase transition (10-20 degrees C) and induces the formation of large raft aggregates. In addition, we found that the glycoprotein CD36 is selectively enriched within detergent-resistant membranes (DRMs) of cold-activated platelets and is extremely sensitive to treatment with methyl-beta-cyclodextrin (MbetaCD). Here, we further studied the partitioning of downstream signaling molecules within the DRMs. We found that the phospholipase Cgamma2 (PLCgamma2) and the protein tyrosine kinase Syk do not partition exclusively within the DRMs, but their distribution is perturbed by cholesterol extraction. In addition, PLCgamma2 activity increases in cold-activated cells compared to resting platelets and is entirely inhibited after treatment with MbetaCD. The Src-family protein tyrosine kinases Src and Lyn preferentially partition within the DRMs and are profoundly affected by removal of cholesterol. These kinases are non-redundant in cold-activation. CD36, active Lyn, along with inactive Src and PLCgamma2 co-localize in small raft complexes in resting platelets. Cold-activation induces raft aggregation, resulting in changes in the activity of these proteins. These data suggest a crucial role of raft aggregation in the early events of cold-induced platelet activation.