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。     

Interaction of actin with phalloidin: polymerization and stabilization of F-actin.

The cyclic peptide phalloidin, one of the toxic components of Amanita phalloides prevented the drop of viscosity of F-actin solutions after the addition of 0.6 M KI and inhibited the ATP splitting of F-actin during sonic vibration. The data concerning ATP splitting are consistent with the assumption (a) that only 1 out of every 3 actin units of the filaments needs to be combined with phalloidin in order to suppress the contribution of these 3 actins to the ATPase activity of the filament and (b) that all actin units of the filaments can combine with phalloidin with a very high affinity. -halloidin did not only stabilize the actin-actin bonds in the F-actin structure but it also increased the rate of polymerization of G-actin to F-actin. The ability of F-actin to activate myosin ATPase was not affected by phalloidin. The tropomyosin-troponin complex did not prevent the stabilizing effect of phalloidin on the F-actin structure.     

Phalloidin-eosin followed by photo-oxidation: a novel method for localizing F-actin at the light and electron microscopic levels.

We describe a novel high-resolution method to detect F-actin at the light and electron microscopic levels through the use of the actin-binding protein phalloidin conjugated to the fluorophore eosin, followed by photo-oxidation of diaminobenzidine. This method possesses several key advantages over antibody-based labeling and structural methods. First, phalloidin binding to F-actin can tolerate relatively high concentrations of glutaraldehyde (up to 1%) in the primary fixative, resulting in good ultrastructural preservation. Second, because both eosin and phalloidin are relatively small molecules, considerable penetration of reagents into aldehyde-fixed tissue was obtained without any permeabilization steps, allowing 3D reconstructions at the electron microscopic level. By employing a secondary fixation with tannic acid combined with low pH osmication, conditions known to stabilize actin filaments during preparation for electron microscopy, we were able to visualize individual actin filaments in some structures. Finally, we show that fluorescent phalloidin can be directly injected into neurons to label actin-rich structures such as dendritic spines. These results suggest that the fluorescent phalloidin is an excellent tool for the study of actin networks at high resolution.     

Irradiations of rabbit myofibrils with an ultraviolet microbeam. II. Phalloidin protects actin in solution but not in myofibrils from depolymerization by ultraviolet light

We tested whether phalloidin protects actin in myofibrils from depolymerization by ultraviolet light (UV). I bands in glycerinated rabbit psoas myofibrils were irradiated with a UV microbeam in the presence and absence of phalloidin. We used the retention of contractility of the irradiated I band as the assay for protection of actin by phalloidin, since previous experiments indicated that UV blocks contraction of an irradiated I band by depolymerizing the thin filaments. The I bands of myofibrils incubated in phalloidin were as sensitive to UV as control I bands, indicating that phalloidin did not protect the thin filaments. However, phalloidin did protect F-actin in solution from depolymerization by UV. This apparent contradiction between F-actin in myofibrils and F-actin in solution was resolved by observing unirradiated myofibrils that were stained with rhodamine-phalloidin. It was found that phalloidin does not bind uniformly to the thin filaments, though as the fluorescence image is observed over time the staining pattern changes until it does appear to bind uniformly. We conclude that phalloidin does not protect F-actin in myofibrils from depolymerization by UV because it does not bind uniformly to the filaments.     

Phallotoxin and actin binding assay by fluorescence enhancement.

The fluorescence of five fluorophores conjugated to phallotoxins was found to be specifically enhanced upon binding to F-actin in a polymerizing buffer. Rhodamine phalloidin had the greatest fluorescence enhancement of ninefold. The fluorescence titration of rhodamine phalloidin by actin was shown to be consistent with stoichiometric binding. The fluorescence enhancement of rhodamine phalloidin at 5 microM is linearly related to F-actin concentrations up to 2 microM and therefore can be used as an easy means of F-actin quantitation. In a competition assay, other phallotoxins reduce the fluorescence enhancement that results from the binding of rhodamine phalloidin to polymerized actin. This reduction also permits a convenient measurement of the binding constants of any competing phallotoxins.     

肌动蛋白体外自组织复合纤维结构的观察

利用原子力显微镜(atomic force microscope,AFM)和透射电子显微镜(transmission electron microscope,WEM)技术,研究了低浓度肌动蛋白在体外简单热力学体系中,形成的自组织复合纤维结构。肌动蛋白在体外通过自组织过程能够聚合形成大尺度的、离散的、复杂的聚集纤维体系,分散的单根微丝较少;在微丝稳定剂鬼笔环肽干预下,肌动蛋白通过受调控的自装配过程,主要形成分散的单根微丝,以及少量由单根微丝组成的微丝束和纤维分支等简单微丝聚集结构。     

Dynamic rearrangement of the filamentous actin network occurs during zoosporogenesis and encystment in the oomycete phytophthora cinnamomi

The organization of filamentous actin (F-actin) in living cells of the oomycete Phytophthora cinnamomi was determined during zoosporogenesis and zoospore encystment by microinjecting sporangia with fluorescently labeled phalloidin and observing resultant fluorescence by confocal microscopy. In multinucleate sporangia prior to the induction of cleavage, phalloidin labeling took the form of plaques which occurred mainly in the periphery of the sporangia. After induction of cleavage, phalloidin labeling showed that the plaques disappeared and that F-actin began to accumulate along the developing cleavage planes and around nuclei and water expulsion vacuoles. F-actin labeling was also observed near the plasma membrane in zoospores and young cysts but reverted to the plaque form in older cysts. Localization of F-actin close to the developing cleavage planes is consistent with the idea that actin microfilaments function in the positioning and expansion of the cleavage membranes. Observations of plaques of actin in living sporangia provide evidence that plaques are not aldehyde-induced fixation artifacts. Copyright 1998 Academic Press.     

Actin hydrophobic loop 262-274 and filament nucleation and elongation

The importance of actin hydrophobic loop 262-274 dynamics to actin polymerization and filament stability has been shown recently with the use of the yeast mutant actin L180C/L269C/C374A, in which the hydrophobic loop could be locked in a “parked” conformation by a disulfide bond between C180 and C269. Such a cross-linked globular actin monomer does not form filaments, suggesting nucleation and/or elongation inhibition. To determine the role of loop dynamics in filament nucleation and/or elongation, we studied the polymerization of the cross-linked actin in the presence of cofilin, to assist with actin nucleation, and with phalloidin, to stabilize the elongating filament segments. We demonstrate here that together, but not individually, phalloidin and cofilin co-rescue the polymerization of cross-linked actin. The polymerization was also rescued by filament seeds added together with phalloidin but not with cofilin. Thus, loop immobilization via cross-linking inhibits both filament nucleation and elongation. Nevertheless, the conformational changes needed to catalyze ATP hydrolysis by actin occur in the cross-linked actin. When actin filaments are fully decorated by cofilin, the helical twist of filamentous actin (F-actin) changes by ∼ 5° per subunit. Electron microscopic analysis of filaments rescued by cofilin and phalloidin revealed a dense contact between opposite strands in F-actin and a change of twist by ∼ 1° per subunit, indicating either partial or disordered attachment of cofilin to F-actin and/or competition between cofilin and phalloidin to alter F-actin symmetry. Our findings show an importance of the hydrophobic loop conformational dynamics in both actin nucleation and elongation and reveal that the inhibition of these two steps in the cross-linked actin can be relieved by appropriate factors.     

Two opposite effects of cofilin on the thermal unfolding of F-actin: a differential scanning calorimetric study

Differential scanning calorimetry was used to examine the effects of cofilin on the thermal unfolding of actin. Stoichiometric binding increases the thermal stability of both G- and F-actin but at sub-saturating concentrations cofilin destabilizes F-actin. At actin:cofilin molar ratios of 1.5-6 the peaks corresponding to stabilized (66-67 degrees C) and destabilized (56-57 degrees C) F-actin are observed simultaneously in the same thermogram. Destabilizing effects of sub-saturating cofilin are highly cooperative and are observed at actin:cofilin molar ratios as low as 100:1. These effects are abolished by the addition of phalloidin or aluminum fluoride. Conversely, at saturating concentrations, cofilin prevents the stabilizing effects of phalloidin and aluminum fluoride on the F-actin thermal unfolding. These results suggest that cofilin stabilizes those actin subunits to which it directly binds, but destabilizes F-actin with a high cooperativity in neighboring cofilin-free regions.     

Localization of the phalloidin and nucleotide-binding sites on actin

Phalloidin was found to block nucleotide exchange in F-actin, without interfering with nucleotide hydrolysis. This inhibition of nucleotide exchange occurs under conditions in which monomers are able to exchange. The distance separating a fluorescent chromophore attached to phalloidin from the nucleotide on actin was determined using fluorescence resonance energy-transfer spectroscopy. They are separated by less than 1.0 nm. Added confirmation of the close proximity of phalloidin to nucleotide was obtained by extracting a small peptide-ATP complex from an actin digest. The peptide comprises residues 114-118, which are from the same region as the residues that others have shown to crosslink to phalloidin [Vandekerckhove et al. (1985) EMBO J. 4, 2815-2818]. The results suggest that phalloidin has two major effects. It traps actin monomers in a conformation which appears to be distinct from G-actin and it stabilizes the structure of F-actin, an event accompanied by the trapping of ADP.     

Stoichiometry of actin and phalloidin binding: one molecule of the toxin dominates two actin subunits

Sonication of F-actin in the absence of added ATP in the solvent induces denaturation of the actin. When phalloidin is added to actin at the molar ratio of 1:2, the denaturation is completely inhibited. More directly, pelleting experiments have indicated that the binding of phalloidin to actin subunits is saturated at the same molar ratio. The protection of F-actin from heat denaturation or depolymerization with 0.6 M KI is also complete with one molecule of the toxin over two actin subunits. Therefore, it is concluded that the binding ratio of phalloidin and the actin subunit is not 1:1 but 1:2.     

Cofilin (ADF) affects lateral contacts in F-actin

The effect of yeast cofilin on lateral contacts between protomers of yeast and skeletal muscle actin filaments was examined in solution. These contacts are presumably stabilized by the interactions of loop 262-274 of one protomer with two other protomers on the opposite strand in F-actin. Cofilin inhibited several-fold the rate of interstrand disulfide cross-linking between Cys265 and Cys374 in yeast S265C mutant F-actin, but enhanced excimer formation between pyrene probes attached to these cysteine residues. The possibility that these effects are due to a translocation of the C terminus of actin by cofilin was ruled out by measurements of fluorescence resonance energy transfer (FRET) from tryptophan residues and ATP to acceptor probes at Cys374. Such measurements did not reveal cofilin-induced changes in FRET efficiency, suggesting that changes in Cys265-Cys374 cross-linking and excimer formation stem from the perturbation of loop 262-274 by cofilin. Changes in lateral interactions in F-actin were indicated also by the cofilin-induced partial release of rhodamine phalloidin. Disulfide cross-linking of S265C yeast F-actin inhibited strongly and reversibly the release of rhodamine phalloidin by cofilin. Overall, this study provides solution evidence for the weakening of lateral interactions in F-actin by cofilin.     

Cycling of actin assembly in synaptosomes and neurotransmitter release

We have investigated the regulation of actin assembly in whole mouse brain synaptosomes and how that regulation modulates neurotransmitter release. During a 30 s depolarization with high K+, filamentous actin (F-actin) levels, monitored by staining with rhodamine phalloidin, increase dramatically (up to 300% in 3 s), decrease, and increase once again. This F-actin cycling is regulated by pathways both dependent and independent of Ca2+ influx and is markedly affected by exposing synaptosomes to Li+, tetrodotoxin, and diacylglycerol. Measurement of [3H]norepinephrine release from synaptosomes containing entrapped agents that modulate actin assembly (DNAase I or phalloidin) indicates that actin depolymerization is necessary for normal release and that repolymerization limits release.     

Preliminarily investigating the polymorphism of self-organized actin filament in vitro by atomic force microscope

Actin is a major structural component of eukaryoticcytoskeleton and exists in monomer G-actin and filamen-tous F-actin. G-actin consists of 375 amino acid residueswith molecular weight 43 kD and is a highly conservedprotein expressed in most living organi…     

Influence of phallotoxins and metal ions on the rate of proteolysis of actin

The rate of proteolytic degradation of rabbit skeletal muscle actin by trypsin, alpha-chymotrypsin, and, mainly, subtilisin was followed by dual wavelength spectroscopy at 285 nm by reference at 320 nm. Phalloidin and phallacidin, two toxic bicyclic heptapeptides from the mushroom Amanita phalloides, protect F-actin against degradation by the proteolytic enzymes. G-actin, which does not combine with phalloidin when maintained in the monomeric state by working at low ionic strength, and bovine serum albumin, which also has no affinity to the toxin, are hydrolyzed at the same rates in the presence or absence of phalloidin. The proteolysis of F-actin is distinctly retarded by KCl alone, i.e., without phalloidin, whereas Mg2+ or Ca2+ as sole cations permit a rather high rate of hydrolysis. An even faster degradation of F-actin by subtilisin is observed in the presence of Mg2+ plus cytochalasin B. Adenosine diphosphate and triphosphate have no influence on the rate of the enzymatic degradation. The S sulfoxide of phalloidin, the nontoxic diastereomer of the toxic R form, exerts only a limited inhibitory effect on the enzymatic hydrolysis; secophalloidin, another nontoxic derivative, which does not bind to F-actin has practically no effect.     

Cofilin Changes the Twist of F-Actin: Implications for Actin Filament Dynamics and Cellular Function

Cofilin is an actin depolymerizing protein found widely distributed in animals and plants. We have used electron cryomicroscopy and helical reconstruction to identify its binding site on actin filaments. Cofilin binds filamentous (F)-actin cooperatively by bridging two longitudinally associated actin subunits. The binding site is centered axially at subdomain 2 of the lower actin subunit and radially at the cleft between subdomains 1 and 3 of the upper actin subunit. Our work has revealed a totally unexpected (and unique) property of cofilin, namely, its ability to change filament twist. As a consequence of this change in twist, filaments decorated with cofilin have much shorter ‘actin crossovers' (~75% of those normally observed in F-actin structures). Although their binding sites are distinct, cofilin and phalloidin do not bind simultaneously to F-actin. This is the first demonstration of a protein that excludes another actin-binding molecule by changing filament twist. Alteration of F-actin structure by cofilin/ADF appears to be a novel mechanism through which the actin cytoskeleton may be regulated or remodeled.     

Actin synthesis is not regulated by granulosa cells in mouse growing and preovulatory oocytes

The synthesis and intracellular distribution of actin were studied in isolated dictyate and metaphase II mouse oocytes by (1) sodium dodecyl sulfate-polyacrylamide gel electrophoresis of newly synthetized oocyte protein and (2) cytochemical F-actin labeling by fluorescent phalloidin. Unpermeabilized, fully grown oocytes bound phalloidin intensely at the level of the zona pellucida (ZP), such ZP-associated actin representing a significant portion of total actin found in these cells. In contrast, phalloidin binding to ZP was very low in growing oocytes and was undetectable in ovulated, metaphase II eggs. When ZP-associated actin of fully grown oocytes was removed by prolongedly exposing oocytes to α-chymotrypsin, the amount of newly synthesized actin displayed by cumulus-enclosed oocytes was reduced to a level comparable to that shown by oocytes isolated from granulosa cells. We demonstrate that ZP-associated actin belongs to granulosa cell processes that remain within the ZP as a consequence of oocyte isolation procedures. We conclude that actin synthesis of mouse oocytes is not regulated by granulosa cells.     

Cucumber Mosaic Virus Movement Protein Severs Actin Filaments to Increase the Plasmodesmal Size Exclusion Limit in Tobacco

Plant viral movement proteins (MPs) enable viruses to pass through cell walls by increasing the size exclusion limit (SEL) of plasmodesmata (PD). Here, we report that the ability of Cucumber mosaic virus (CMV) MP to increase the SEL of the PD could be inhibited by treatment with the actin filament (F-actin)–stabilizing agent phalloidin but not by treatment with the F-actin–destabilizing agent latrunculin A. In vitro studies showed that CMV MP bound globular and F-actin, inhibited actin polymerization, severed F-actin, and participated in plus end capping of F-actin. Analyses of two CMV MP mutants, one with and one without F-actin severing activities, demonstrated that the F-actin severing ability was required to increase the PD SEL. Furthermore, the Tobacco mosaic virus MP also exhibited F-actin severing activity, and its ability to increase the PD SEL was inhibited by treatment with phalloidin. Our data provide evidence to support the hypothesis that F-actin severing is required for MP-induced increase in the SEL of PD. This may have broad implications in the study of the mechanisms of actin dynamics that regulate cell-to-cell transport of viral and endogenous proteins.     

Differential Support of Aspergillus fumigatus Morphogenesis by Yeast and Human Actins

The actin cytoskeleton is highly conserved among eukaryotes and is essential for cellular processes regulating growth and differentiation. In fungi, filamentous actin (F-actin) orchestrates hyphal tip structure and extension via organization of exocytic and endocytic processes at the hyphal tip. Although highly conserved, there are key differences among actins of fungal species as well as between mammalian and fungal actins. For example, the F-actin stabilizing molecules, phalloidin and jasplakinolide, bind to actin structures in yeast and human cells, whereas phalloidin does not bind actin structures of Aspergillus. These discrepancies suggest structural differences between Aspergillus actin filaments and those of human and yeast cells. Additionally, fungal actin kinetics are much faster than those of humans, displaying 5-fold faster nucleation and 40-fold faster nucleotide exchange rates. Limited published studies suggest that these faster actin kinetics are required for normal growth and morphogenesis of yeast cells. In the current work, we show that replacement of Aspergillus actin with yeast actin generates a morphologically normal strain, suggesting that Aspergillus actin kinetics are similar to those of yeast. In contrast to wild type A. fumigatus, F-actin in this strain binds phalloidin, and pharmacological stabilization of these actin structures with jasplakinolide inhibits germination and alters morphogenesis in a dose-dependent manner. We also show that human β-actin cannot support Aspergillus viability, even though the amino acid sequences of human and Aspergillus actins are 89.3% identical. Our findings show that minor differences in actin protein sequence account for loss of phalloidin and jasplakinolide sensitivity in Aspergillus species.     

Evidence for the concentration of F-actin and myosin in synapses and in the plasmalemmal zone of axons

Fluorescent staining with phalloidin, a specific probe for F-actin, and antibodies to non-muscle myosin from thymus was used to localize actin and myosin in brain neurons of the rat. Phalloidin and anti-myosin displayed a preferential affinity for synaptic formations in the cerebellum, the brain stem, the spinal cord and the retina. The conclusion that F-actin and myosin are concentrated in synaptic terminals was further established by simultaneous staining of isolated rat brain synaptosomes with phalloidin and anti-thymus myosin as well as by the demonstration of a selective affinity of anti-thymus myosin for a 200 000-Mr protein band in gel electrophoretograms of synaptic fractions. Apart from synaptic areas, phalloidin and anti-thymus myosin reacted also, albeit rather weakly, with a narrow circumferential layer located in the area of the plasma membrane of virtually all axons in the white matter and the spinal roots. The spatial coexistence of myosin and actin in brain synapses and axons is of particular interest in view of various dynamic functions that have been proposed for axonal and synaptic actin.