The oxidation produced by hydrogen peroxide on Ca-ATP-G-actin.

We report here that in vitro exposure of monomeric actin to hydrogen peroxide leads to a conversion of 6 of the 16 methionine residues to methionine sulfoxide residues. Although the initial effect of H2O2 on actin is the oxidation of Cys374, we have found that Met44, Met47, Met176, Met190, Met269, and Met355 are the other sites of the oxidative modification. Met44 and Met47 are the methionyl sites first oxidized. The methionine residues that are oxidized are not simply related to their accessibility to the external medium and are found in all four subdomains of actin. The conformations of subdomain 1, a region critical for the functional binding of different actin-binding proteins, and subdomain 2, which plays important roles in the polymerization process and stabilization of the actin filament, are changed upon oxidation. The conformational changes are deduced from the increased exposure of hydrophobic residues, which correlates with methionine sulfoxide formation, from the perturbations in tryptophan fluorescence, and from the decreased susceptibility to limited proteolysis of oxidized actin.

The tert-butyl hydroperoxide-induced oxidation of actin Cys-374 is coupled with structural changes in distant regions of the protein.

The susceptibility of monomeric actin to both methionine and cysteine oxidation when treated with the oxidizing agent tert-butyl hydroperoxide (t-BH) was investigated. The results show that no methionine residue was susceptible to oxidation by t-BH at concentrations of 1-20 mM, while Cys-374, one of the five cysteine residues of the actin molecule, was found to be the site of the oxidative modification. Perturbations in the intrinsic tryptophan fluorescence and the decreased susceptibility to limited proteolysis by alpha-chymotrypsin and subtilisin of oxidized actin give an indication of some alterations in protein conformation in subdomain 1, and in the central segment of surface loop 39-51, in subdomain 2. Urea denaturation curves indicate a lower conformational stability for the oxidized actin. G-actin structural alterations due to Cys-374 oxidation produced by t-BH result in a decrease in the maximum rate of polymerization, an increase in both the delay time and the time required for half-maximum assembly, a decrease in the elongation rate, and enhancement of the critical monomer concentration for polymerization. The results suggest that oxidation of actin Cys-374 induces structural alterations in the conformation of at least two different distant regions of the molecule. The involvement of both the C-terminus of the actin polypeptide chain and the DNase-I-binding loop in the intermonomer interactions in the polymer could account for the altered kinetics of polymerization shown by the oxidized actin.

Effects of chlorpromazine on actin polymerization: slackening of filament elongation and filament annealing.

We have analyzed the effect of chlorpromazine (CPZ) on pure actin. We have found that CPZ quenches Trp-79 and Trp-86 fluorescence and, in agreement with an earlier report on conventional actin, inhibits actin polymerization, lowering the extent of polymerization. Moreover, novel polymerization data are presented indicating that CPZ decreases the maximum polymerization rate in a dose-dependent manner. The assembly inhibition results from the slackening of oligomer formation during the early stages of polymerisation, of filament elongation and of filament annealing. Finally, CPZ strongly inhibits actin filament network formation.

The assembly of Ni2+-actin: some peculiarities.

Nickel alters the organisation of highly dynamic cytoskeletal elements. In cultured cells Ni2+ causes microtubule aggregation and bundling as well as microfilament aggregation and redistribution. Here, we have analysed the effect(s) of Ni2+ on in vitro actin polymerisation. Using limited proteolysis by trypsin we have suggested that the regions around Arg-62 and Lys-68 change their conformation following Ni2+ binding to the single high-affinity site for divalent cations in the G-actin molecule. We have found that Ni2+ shortens the lag phase of actin polymerisation and increases the rate of assembly mainly because of an increased elongation rate. Ni2+ has no significant effect on the final plateau of actin polymerisation nor on the actin critical concentration. Electron microscopy revealed that actin filaments polymerised by 2 mM Ni2+ showed some tendency to lateral aggregation, being frequently formed by the cohesion of two or three filaments. Furthermore, they often appeared shorter than those of control as also confirmed by the larger amount of free filament ends as well as the faster depolymerisation rate than control.

Effect of replacement of the tightly bound Ca2+ by Ba2+ on actin polymerization.

G-actin has a single tight-binding (high-affinity) site for divalent cations per mole of protein, whose occupancy is important for the stability of the molecule. Different tightly bound divalent cations differently influence the polymerization properties of actin. The tightly bound metal ion easily exchanges for free exogenous cations. Moreover, biochemical and structural evidence demonstrates that actin, in both the G- and F-forms, assumes different conformations depending on the metal ion bound with high affinity in the cleft between two main domains of the molecule. In this work, we used proteolytic susceptibility to detect possible local conformational alterations of the actin molecule following a brief incubation of Ca-G-actin with barium chloride and ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid. We found that substitution of Ba2+ for the tightly bound Ca2+ affects the regions around Arg-62 and Lys-68 in subdomain 2 of G-actin, as judged from inhibition of tryptic cleavage at these residues. Using the fluorescent chelator Quin-2, we observed that about 0.95 mol of Ba2+ is released per 1 mol of actin. We also examined the effect of replacement of the tightly bound Ca2+ by Ba2+ on actin polymerization. With respect to Ca-actin, Ba-actin shows an increased polymerization rate, mainly due to its enhanced nucleation and a higher critical concentration.

G-actin conformational change and polymerization induced by paraquat.

Paraquat (1,1'-dimethyl-4,4'-bipyridilium dichloride) is a broad-spectrum herbicide that is highly toxic to animals (including man), the major lesion being in the lung. In mammalian cells, paraquat causes deep alterations in the organization of the cytoskeleton, marked decreases in cytoskeletal protein synthesis, and alterations in cytoskeletal protein composition; therefore, the involvement of the cytoskeleton in cell injury by paraquat was suggested. We previously demonstrated that monomeric actin binds paraquat; moreover, prolonged actin exposure to paraquat, in depolymerizing medium, induces the formation of actin aggregates, which are built up by F-actin. In this work we have shown that the addition of paraquat to monomeric actin results in a strong quenching of Trp-79 and Trp-86 fluorescence. Trypsin digestion experiments demonstrated that the sequence 61-69 on actin subdomain 2 undergoes paraquat-dependent conformational changes. These paraquat-induced structural changes render actin unable to completely inhibit DNase I. By using intermolecular cross-linking to characterize oligomeric species formed during paraquat-induced actin assembly, we found that the herbicide causes the formation of actin oligomers characterized by subunit-subunit contacts like those occurring in oligomers induced by polymerizing salts (i.e., between subdomain 1 on one actin subunit and subdomain 4 on the adjacent subunit). Furthermore, the oligomerization of G-actin induced by paraquat is paralleled by ATP hydrolysis.

Actin assembly by cadmium ions.

Cadmium is a highly toxic metal entering cells by a variety of mechanisms. Its toxic action is far from being completely understood, although specific interaction with the cellular calcium metabolism has been indicated. Metal ions that influence intracellular Ca2+ concentrations or compete with Ca2+ for protein binding sites may exert an effect on actin filaments, whose assembly and disassembly are both regulated by a number of calcium-dependent factors. Cadmium is such a metal. Much evidence demonstrates that cadmium interferes with the dynamics of actin filaments in various types of cells. Here we show that, at high (0.8-1.0 mM) concentrations, CdCl2 causes actin denaturation. At such Cd2+ concentrations, actin precipitates (really actin, as shown by SDS-PAGE, see Fig. 1B) in the form of irregular, disordered clots, clearly appreciable by electron microscopy. Denaturation seems to be reversible since, after Cd2+ removal by dialysis, the polymerizability of sedimented actin is restored almost completely. On the other hand, at concentrations ranging from 0.25 to 0.6 mM, CdCl2 is more effective as an actin polymerizing agent than both MgCl2 and CaCl2. The Cd-related increase in the actin assembly rate is ascribable to an enhanced nucleation rather than to an increased monomer addition to filament growing ends. The latter, in contrast, appears quite slow. Critical concentration measurements revealed that the extent of polymerization of both Mg- and Cd-assembled actin are very close (C(c) ranges from 0.25 to 0.5 microM), while Ca-polymerized actin shows a polymerization extent markedly lower (C(c) = 4.0 microM). By both the fluorescent Ca2+ chelator Quin-2 assay and limited proteolysis of actin by trypsin and alpha-chymotrypsin, the real substitution of G-actin-bound Ca2+ by Cd2+ has been appreciated. The increase in Quin-2 fluorescence after addition of excess CdCl2 indicates that, in our experimental conditions, Ca2+ tightly-bound to actin is partially (60-70%) replaced by Cd2+, forming Cd-actin. Electrophoretic patterns after limited proteolysis reveal that the trypsin cleavage sites in the segment 61-69 of the actin polypeptide chain are less accessible in Cd-actin than in Ca-actin, although the cation-dependent effect is less pronounced in Cd-actin than in Mg-actin. Our results are consistent with some of the consequences on microfilament organization observed in Cd2(+)-treated cells; however, considering the positive effect of Cd2+ on actin polymerization in solution we have noticed that this was never observed in vivo. A different indirect effect of Cd2+ on some cellular event(s) influencing cytoplasmic actin polymerization appears to be reasonable.

Paraquat induces actin assembly in depolymerizing conditions.

The molecular mechanism (or mechanisms) at the basis of paraquat (PQ) (a widely used herbicide) toxicity is far from being fully understood. Until now, two main points of view have emerged: 1) PQ-related cell injuries could be mediated by toxic oxygen free radicals coming from the metabolism of the herbicide by the microsomal enzyme system, and/or 2) PQ, by inducing mitochondrial swelling and breakage, could cause troubles in cell energy charge, then driving the cell to death. Recently, some of cytoskeletal structures (microtubules and microfilaments) have been proposed as further PQ cell targets. The microfilament system in particular seems to be markedly affected by the herbicide, but so far no direct evidence associates PQ to actin damage. In this study, experimental data are presented concerning the direct effect of PQ on actin dynamics in solution. We demonstrate that actin selectively binds PQ; moreover, PQ induces the formation of actin sopramolecular structures in depolymerizing medium (G-buffer). Furthermore, by the interactions with F-actin cross-linking proteins (alpha-actinin and filamin), FITC-phalloidin, and myosin subfragment 1 (S1), it is demonstrated that PQ-induced actin aggregates are undoubtedly built up by F-actin. Electron micrographs showed that PQ-induced actin polymers are very short and tend to aggregate one to another. This mutual cohesion leads to the steric blockage of polymer growing ends as suggested by nucleated actin polymerization assays. Sonication, by releasing F-actin fragments from short polymer aggregates, allows actin polymer ends to regain their growing ability.

Prolonged oxidative stress on actin.

Hydrogen peroxide, coming from polymorphonuclear leukocytes, causes severe oxidative injury on actin molecules with the disarrangement of cortical actin cytoskeleton followed by plasmalemma blebbing. In this paper we demonstrate that actin oxidation does not simply develop into denaturation, but oxidative injuries on actin are specific and related to the chemical characteristics of the oxidant. Experiments on purified actin in solution have shown that actin behavior to oxidation depends on (i) the amino acidic targets of the oxidant and (ii) on the structural plasticity of the actin molecule, which differently responds to different chemical modifications. Therefore, hydrogen peroxide (that presents a broad oxidative activity) affects actin dynamics by markedly inhibiting the assembly of actin monomers, by forcing the disassembly of actin polymers, and, moreover, by affecting the interaction between oxidant-stressed actin and DNase I. Diamide (a specific thiol oxidant), in contrast, mainly lowers the actin polymerization extent, while it slightly influences the polymerization rate and results uneffective on both F-actin disassembly and actin-related DNase I inhibition. Actin response to oxidative stresses likely depends on the "structural connectivity in actin," the property allowing it to finely modulate the actin filament architecture. The potential cellular relevance of the alterations in the interaction between oxidized actin and DNase I has been briefly discussed.

H2O2-treated actin: assembly and polymer interactions with cross-linking proteins.

During inflammation, hydrogen peroxide, produced by polymorphonuclear leukocytes, provokes cell death mainly by disarranging filamentous (polymerized) actin (F-actin). To show the molecular mechanism(s) by which hydrogen peroxide could alter actin dynamics, we analyzed the ability of H2O2-treated actin samples to polymerize as well as the suitability of actin polymers (from oxidized monomers) to interact with cross-linking proteins. H2O2-treated monomeric (globular) actin (G-actin) shows an altered time course of polymerization. The increase in the lag phase and the lowering in both the polymerization rate and the polymerization extent have been evidenced. Furthermore, steady-state actin polymers, from oxidized monomers, are more fragmented than control polymers. This seems to be ascribable to the enhanced fragility of oxidized filaments rather than to the increase in the nucleation activity, which markedly falls. These facts; along with the unsuitability of actin polymers from oxidized monomers to interact with both filamin and alpha-actinin, suggest that hydrogen peroxide influences actin dynamics mainly by changing the F-actin structure. H2O2, via the oxidation of actin thiols (in particular, the sulfhydryl group of Cys-374), likely alters the actin C-terminus, influencing both subunit/subunit interactions and the spatial structure of the binding sites for cross-linking proteins in F-actin. We suggest that most of the effects of hydrogen peroxide on actin could be explained in the light of the "structural connectivity," demonstrated previously in actin.

N-ethylmaleimide-modified actin filaments do not bundle in the presence of alpha-actinin.

We show that the modification of actin subdomain 1 by N-ethylmaleimide (NEM), which binds Cys-374 close to the C-terminus of the molecule, inhibits the alpha-actinin-induced bundling of actin filaments. This effect is not merely related to the block of Cys-374, since N-(1-pyrenyl)iodoacetamide (pyrene-IA) is unable to prevent bundling. Considering that NEM (but not pyrene-IA) influences actin assembly, we suggest that the inhibition of the actin-alpha-actinin interaction is due to the chemical modification of actin Cys-374 which, by inducing a marked spatial reorganization of actin monomers, is able to modify both the intra- and inter-molecular interactions of this protein. Finally, NEM-modified actin filaments form bundles in the presence of polyethylene glycol 6000 since, in this case, the side by side association of actin filaments does not depend on the accessibility of binding sites nor on the formation of chemical bonds.

DXR depresses the alpha-actinin-induced formation of actin bundles.

The filament-to-filament interactions in cardiac alpha-actinin/F-actin mixtures were investigated in the presence of doxorubicin. Stoichiometrical concentrations of the drug in the assembly medium inhibit the growth of alpha-actinin/F-actin three-dimensional structures, as shown by low speed centrifugation, light scattering, A320nm, electron microscopy and low shear viscosity tests. DXR-induced short actin bundle formation could be related to the inhibition of the bundle elongation mechanism, and furthermore, could account for some morphological evidences in DXR-treated living cells. Our results support both the formation pathway of actin bundles as proposed by Stokes and DeRosier (1991), and the observations of Molinari et al. (1990) on the human CG5 cell line.

Lithium preserves F-actin from the disarrangement induced by either DNase I or cytochalasin D.

Light scattering at 546 nm, which is mainly related to the presence of rodlike particles longer than 50 nm, showed that Li+ accelerates the formation of actin filaments. Intermolecular cross-linking with N,N'-1,4-phenylene-bismaleimide proved that the observed enhancement in the light-scattering intensity is caused by the increase in the concentration of actin oligomers, which gradually elongate to form longer filaments. DNase-I-related F-actin disassembly was reduced in the presence of lithium ions, as demonstrated by fluorimetric and viscometric experiments. Li(+)-F-actin showed an apparently similar behaviour when exposed to cytochalasin D. We confirm that Li+ acts on actin polymerization by stabilizing actin nuclei and polymers. The stabilization of cytoskeletal polymers really appears as one of the mechanisms by which lithium ions influence some of the cell activities.

Alpha-actinin increases actin filament end concentration by inhibiting annealing.

The usual rate of actin polymerization is increased if one starts from actin nuclei. We have noticed that, using alpha-actinin crosslinked actin nuclei, the initial net elongation rate is further enhanced. Also initial net depolymerization rates of alpha-actinin crosslinked F-actin samples are higher than those of controls. These results should imply that alpha-actinin increases the filament end concentration of actin samples. The experiments with barbed and blocking substances (cytochalasin D and gelsolin-actin complex) confirmed such an increase. We have shown that: (1) alpha-actinin does not significantly influence actin polymerization over all; (2) alpha-actinin inhibits the recovery of the filament size in F-actin samples after sonication; and (3) the influence of alpha-actinin on actin filament end concentration is counteracted by tropomyosin. Therefore, we suggest that, upon filament shearing, alpha-actinin crosslinking inhibits the annealing of short actin polymers into longer filaments.

Interaction of cardiac alpha-actinin and actin in the presence of doxorubicin.

The therapeutic use of doxorubicin (an antitumoral antibiotic belonging to the anthracycline group) is limited by its cardiotoxicity. Adriamycin (DXR) causes myocardial subcellular damage, such as myocytolysis, disarray of actin filaments, and alterations in the Z-band with loss of sarcomeric organization. We studied the effect of stoichiometrical concentrations of DXR on the interaction between cardiac actin and alpha-actinin in solution. Doxorubicin inhibits the formation of alpha-actinin/actin tridimensional networks and bundles. The main effect of the drug seems to be on the size of the actin polymers.