On the interaction of muscle actin with gadolinium.

The polymerization of G-actin is prevented by concentrations of gadolinium (GdIII) that exceed the ATP present. Since the susceptibility of G-actin to enzymatic proteolysis is slightly decreased upon addition of GdIII, and the digestibility of F-actin is markedly increased with the same treatment, it appears that actin undergoes GdIII-induced conformational changes. The altered states of actin formed inhibit the GdIII-ATPase activity of myosin, but in all cases, the effect of GdIII on actin is reversed by removal of the trivalent ion with ATP. The reversible changes in conformation induced by GdIII create a state of actin which has properties unlike those of G-actin, F-monomer or F-actin.     

Tolrestat对高糖所致肾小球系膜细胞肌动蛋白去组装的影响

研究了醛糖还原酶抑制剂Tolrestat对高浓度葡萄糖(HG)所致肾小球系膜细胞(MC)肌动蛋白(actin)组装的影响。结果证明,与正常浓度葡萄糖(NG)相比,在HG培养的MC,F-actin失去束状外观呈不规则网状,显示F-actin部分去组装;F-actin荧光强度降低,G-actin荧光强度升高和F-/G-actin荧光强度比值下降。Tolrestat加入培养后,明显防止HG引起的F-actin去组装及F-和G-actin荧光强度的变化。提示多元醇通路激活在HG引起的MCactin去组装改变中起一定作用。     

Conformational state of thin myofilament proteins in normal and chronically failing heart

Circular dichroism (CD) spectra of myocardial G-actin significantly differ from those of F-actin, and the spectra of G- and F-actins differ from those of myocardial tropomyosin, native tropomyosin and alpha-actinin. In heart failure in man and experimental animals, characterized by a significantly decreased ability of the contractile protein system to generate force, considerable changes in the tertiary structure of Straub G-actin are observed. During polymerization a monomer of this actin is included in F-actin as a promoter without corresponding conformational changes of a part of G-actin globule; G-actin from the failing myocardium loses its conformational mobility. According to CD data the secondary protein structure is not altered. CD spectra analysis with regard to the regions of aromatic amino acid residue localization in active sites of actin suggests that the sites of actin-myosin and actin-actin interactions do not assume the conformation necessary for normal functioning of thin filaments.     

Inhibition of muscle tropomyosin polymerization by DNAse I

Tropomyosin polymerization is inhibited by DNAse I, an endonuclease which also interacts with G-actin. A 1:4 molar ratio of DNAse I to adult chicken pectoralis muscle tropomyosin almost completely prevents the increased viscosity of tropomyosin under polymerizing ionic conditions. While G-actin binding to DNAse I inhibits the DNAse I hydrolysis of DNA, tropomyosin does not affect this enzymatic activity. G-actin-DNAse I interaction is also not altered by tropomyosin.     

Cytochemical dopamine visualization as a method for estimation of globular actin content in cytosol of living cells

The possibility to reveal globular (G-) actin in cell cytosole by means of microscopy has been studied. The applicability of this method was in particular evaluated for diagnostics of malignant cells, whose main pathocytological feature is an anomalously high content of G-actin in cytosol. The cells of a common origin but with different states of cytosolic actin were analyzed by means of cytochemical reaction for biogenic amines using Falck-Hillarp method after 40-h incubation of the cells in dopamine-containing cultivation medium. Mouse embryo cell line BALB/3T3, clone A31 with differentiated actin cytoskeleton were used as a control cell line. The same cells infected with pathogenic virus SV-40 (cell line 3T3B-SV40) exhibited a malignant phenotype; their cytosol mainly consisted of G-actin. Manifold increase in fluorescence intensity of cytosol and karyoplasms, the loci with the highest G-actin concentration, was revealed in malignant cells in comparison with their healthy prototype. Thus, it was shown that G-actin of malignant cells is a diagnostic target for dopamine, which, as it was earlier shown, penetrates into the cytosol, polymerizes G-actin, incorporating into the filaments as integral component in the 100:1 ratio, and thus fluorescently labels G-actin due to conversion into isoquinoline by reaction with formaldehyde. Besides, dopamine exhibited a strong cytotoxicity that considerably reduced the viability of malignant cells. The data suggest that the content of Gactin in cytosol of living cells can be quantitatively estimated by fluorescence intensity of cytosol following incubation of the cells in dopamine-containing medium.     

Maleimidobenzoyl-G-actin: structural properties and interaction with skeletal myosin subfragment-1

We have investigated various structural and interaction properties of maleimidobenzoyl-G-actin (MBS-actin), a new, internally cross-linked G-actin derivative that does not exhibit, at moderate protein concentration, the salt--and myosin subfragment 1 (S-1)-induced polymerizations of G-actin and reacts reversibly and covalently in solution with S-1 at or near the F-actin binding region of the heavy chain (Bettache, N., Bertrand, R., & Kassab, R. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 6028-6032). The far-ultraviolet CD spectrum and alpha-helix content of the MBS-actin were identical with those displayed by native G-actin. 45Ca2+ measurements showed the same content of tightly bound Ca2+ in MBS-actin as in G-actin and the EDTA treatment of the modified protein promoted the same red shift of the intrinsic fluorescence spectrum as observed with native G-actin. Incubation of concentrated MBS-actin solutions with 100 mM KCl + 5 mM MgCl2 led to the polymerization of the actin derivative when the critical monomer concentration reached 1.6 mg/mL, at 25 degrees C, pH 8.0. The MBS-F-actin formed activated the Mg2(+)-ATPase of S-1 to the same extent as native F-actin. The MBS-G-actin exhibited a DNase I inhibitor activity very close to that found with native G-actin and was not to be at all affected by its specific covalent conjugation to S-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of endothelial nitric oxide synthase by the actin cytoskeleton

In the present study, the association ofendothelial nitric oxide synthase (eNOS) with the actin cytoskeleton inpulmonary artery endothelial cells (PAEC) was examined. We found thatthe protein contents of eNOS, actin, and caveolin-1 were significantly higher in the caveolar fraction of plasma membranes than in the noncaveolar fraction of plasma membranes in PAEC. Immunoprecipitation of eNOS from lysates of caveolar fractions of plasma membranes in PAECresulted in the coprecipitation of actin, and immunoprecipitation ofactin from lysates of caveolar fractions resulted in thecoprecipitation of eNOS. Confocal microscopy of PAEC, in which eNOS waslabeled with fluorescein, F-actin was labeled with Texasred-phalloidin, and G-actin was labeled with deoxyribonuclease Iconjugated with Texas red, also demonstrated an association betweeneNOS and F-actin or G-actin. Incubation of purified eNOS with purifiedF-actin and G-actin resulted in an increase in eNOS activity. Theincrease in eNOS activity caused by G-actin was much higher than thatcaused by F-actin. Incubation of PAEC with swinholide A, an actinfilament disruptor, resulted in an increase in eNOS activity, eNOSprotein content, and association of eNOS with G-actin and in a decrease in the association of eNOS with F-actin. The increase in eNOS activitywas higher than that in eNOS protein content in swinholide A-treatedcells. In contrast, exposure of PAEC to phalloidin, an actin filamentstabilizer, caused decreases in eNOS activity and association of eNOSwith G-actin and increases in association of eNOS with F-actin. Theseresults suggest that eNOS is associated with actin in PAEC and thatactin and its polymerization state play an important role in theregulation of eNOS activity.

     

Comparisons of Endothelial Cell G- and F-Actin Distribution in Situ and in Vitro

Numerous studies have described the F-actin cytoskeleton; however, little information relevant to C-actin is available. The actin pools of bovine aortic endothelial cells were examined using in situ and in vitro conditions and fluorescent probes for G-(deoxyribonuclease I.0.3 μM) or F-actin (phalloidin, 0.2 μM). Cells in situ displayed a diffuse G-actin distribution, while F-actin was concentrated in the cell periphery and in fine stress fibers that traversed some cells. Cells of subconfluent or just confluent cultures demonstrated intense fluorescence, with many F-actin stress fibers. Postconfluent cultures resembled the condition in situ; peripheral F-actin was prominent, traversing actin stress fibers were greatly reduced and fluorescent intensity was diminished. Postconfluency had little influence on G-actin. with only an enhancement in the intensity of G-actin punctate fluorescence. When post-confluent cultures were incubated with cytochalasin D (15 min; 10^--⁴ M), F-actin networks were disrupted and actin punctate and diffuse fluorescence increased. G-actin fluorescence was not altered by the incubation. Although its unstructured nature may account for the minor changes observed, the stability of the G-actin pool in the presence of notable F-actin modulations suggested that filamentous actin was the key constituent involved in these actin cytoskeletal alterations. A separate finding illustrated that the concomitant use of actin probes with image enhancement and fluorescent microscopy could reveal simultaneously the G- and F-actin pools within the same cell.     

Stiffening of human skin fibroblasts with age

Changes in mechanical properties are an essential characteristic of the aging process of human skin. Previous studies attribute these changes predominantly to the altered collagen and elastin organization and density of the extracellular matrix. Here, we show that individual dermal fibroblasts also exhibit a significant increase in stiffness during aging in vivo. With the laser-based optical cell stretcher we examined the viscoelastic biomechanics of dermal fibroblasts isolated from 14 human donors aged 27 to 80. Increasing age was clearly accompanied by a stiffening of the investigated cells. We found that fibroblasts from old donors exhibited an increase in rigidity of ∼60% with respect to cells of the youngest donors. A FACS analysis of the content of the cytoskeletal polymers shows a shift from monomeric G-actin to polymerized, filamentous F-actin, but no significant changes in the vimentin and microtubule content. The rheological analysis of fibroblast-populated collagen gels demonstrates that cell stiffening directly results in altered viscoelastic properties of the collagen matrix. These results identify a new mechanism that may contribute to the age-related impairment of elastic properties in human skin. The altered mechanical behavior might influence cell functions involving the cytoskeleton, such as contractility, motility, and proliferation, which are essential for reorganization of the extracellular matrix.     

Cytoskeletal Reorganization Evoked by Rho-associated kinase- and Protein Kinase C-catalyzed Phosphorylation of Cofilin and Heat Shock Protein 27, Respectively,Contributes to Myogenic Constriction of Rat Cerebral Arteries

Our understanding of the molecular events contributing to myogenic control of diameter in cerebral resistance arteries in response to changes in intravascular pressure, a fundamental mechanism regulating blood flow to the brain, is incomplete. Myosin light chain kinase and phosphatase activities are known to be increased and decreased, respectively, to augment phosphorylation of the 20-kDa regulatory light chain subunits (LC₂₀) of myosin II, which permits cross-bridge cycling and force development. Here, we assessed the contribution of dynamic reorganization of the actin cytoskeleton and thin filament regulation to the myogenic response and serotonin-evoked constriction of pressurized rat middle cerebral arteries. Arterial diameter and the levels of phosphorylated LC₂₀, calponin, caldesmon, cofilin, and HSP27, as well as G-actin content, were determined. A decline in G-actin content was observed following pressurization from 10 mm Hg to between 40 and 120 mm Hg and in three conditions in which myogenic or agonist-evoked constriction occurred in the absence of a detectable change in LC₂₀ phosphorylation. No changes in thin filament protein phosphorylation were evident. Pressurization reduced G-actin content and elevated the levels of cofilin and HSP27 phosphorylation. Inhibitors of Rho-associated kinase and PKC prevented the decline in G-actin; reduced cofilin and HSP27 phosphoprotein content, respectively; and blocked the myogenic response. Furthermore, phosphorylation modulators of HSP27 and cofilin induced significant changes in arterial diameter and G-actin content of myogenically active arteries. Taken together, our findings suggest that dynamic reorganization of the cytoskeleton involving increased actin polymerization in response to Rho-associated kinase and PKC signaling contributes significantly to force generation in myogenic constriction of cerebral resistance arteries.     

Measurements of spatiotemporal changes in G-actin concentration reveal its effect on stimulus-induced actin assembly and lamellipodium extension

To understand the intracellular role of G-actin concentration in stimulus-induced actin assembly and lamellipodium extension during cell migration, we developed a novel technique for quantifying spatiotemporal changes in G-actin concentration in live cells, consisting of sequential measurements of fluorescent decay after photoactivation (FDAP) of Dronpa-labeled actin. Cytoplasmic G-actin concentrations decreased by ～40% immediately after cell stimulation and thereafter the cell area extended. The extent of stimulus-induced G-actin loss and cell extension correlated linearly with G-actin concentration in unstimulated cells, even at concentrations much higher than the critical concentration of actin filaments, indicating that cytoplasmic G-actin concentration is a critical parameter for determining the extent of stimulus-induced G-actin assembly and cell extension. Multipoint FDAP analysis revealed that G-actin concentration in lamellipodia was comparable to that in the cell body. We also assessed the cellular concentrations of free G-actin, profilin- and thymosin-β4-bound G-actin, and free barbed and pointed ends of actin filaments by model fitting of jasplakinolide-induced temporal changes in G-actin concentration.     

Effect of phalloidin on liver actin distribution,content, and turnover

Phalloidin increases F-actin microfilament content and actin-directed immunofluorescence in hepatocytes in vivo and also increases actin polymerization and the stability of F-actin in vitro. We studied the sensitivity of immunofluorescent staining of actin to an actin depolymerizing factor (ADF) as well as actin content, degree of polymerization, and turnover in livers of in vivo phalloidin-treated rats. Pretreatment with ADF abolished anti-actin antibody (AAA) staining of normal liver but did not modify staining of livers from phalloidin-treated animals. Plani-metric analyses of SDS-polyacrylamide gels snowed the percent actin of total protein was increased by approximately 40% and the absolute amount of actin by approximately 43%, ten days after daily phalloidin treatment (50 μg/100 gm body weight). Similar but smaller changes could be seen after one day of treatment. Ultracentrifugational analyses of liver extracts indicated no change in the amount or proportion of G-actin but a 194% increase in the proportion of F-actin in ten-day treated animals, changes also apparent in one day animals. Neither the relative fractional rate of actin synthesis nor its synthesis as a percent of total protein synthesis was altered either at one-day or ten-day post-phalloidin treatment. Dual-isotope experiments indicated that the rate of actin degradation was decreased selectively in the one- to three-day period -following drug treatment. Thus, phalloidin appears to stabilize actin against the depolymerizing actions of ADF, increases the proportion of F-actin without altering the size of the G-actin pool, and causes accumulation of actin by decreasing its relative rate of degradation.     

Structural aspects of skeletal muscle G-actin molecule as studied by proteolytic digestion: effect of nucleotide

Trypsin and chymotrypsin were used as probes of conformation of G-actin molecule. The pattern of fragments produced has been analyzed by sodium dodecyl sulfate gel electrophoresis. G-actin is known to be nonrefractory to proteolysis [Jacobson, G.R., and Rosenbusch, J.P. (1976) Proc. Natl. Acad. Sci. U.S.A. 73, 2742-2746]. It is really true that G-actin is cut easily into a 33-kDa fragment by trypsin or chymotrypsin, but only when free ATP is present in the medium. After the removal of free ATP from the medium, G-actin became more refractory to proteolysis. The amounts of degradation of G-actin depended on the ATP concentration in the medium with saturating at about 0.5 mM. epsilon-ADP also had the effect and its fluorescence spectrum was changed on the addition of G-actin. After the removal of free ATP, G-actin still bound 1 mol/mol of ATP. So, the present results suggest the presence of a second ATP interaction site on G-actin and that ATP interaction at this site induces conformational changes in G-actin molecule.     

β-Actin specifically controls cell growth, migration, and the G-actin pool

Ubiquitously expressed β-actin and γ-actin isoforms play critical roles in most cellular processes; however, their unique contributions are not well understood. We generated whole-body β-actin-knockout (Actb(-/-)) mice and demonstrated that β-actin is required for early embryonic development. Lethality of Actb(-/-) embryos correlated with severe growth impairment and migration defects in β-actin-knockout primary mouse embryonic fibroblasts (MEFs) that were not observed in γ-actin-null MEFs. Migration defects were associated with reduced membrane protrusion dynamics and increased focal adhesions. We also identified migration defects upon conditional ablation of β-actin in highly motile T cells. Of great interest, ablation of β-actin altered the ratio of globular actin (G-actin) to filamentous actin in MEFs, with corresponding changes in expression of genes that regulate the cell cycle and motility. These data support an essential role for β-actin in regulating cell migration and gene expression through control of the cellular G-actin pool.     

The critical concentration of actin in the presence of ATP increases with the number concentration of filaments and approaches the critical concentration of actin.ADP

F-actin at steady state in the presence of ATP partially depolymerized to a new steady state upon mechanical fragmentation. The increase in critical concentration with the number concentration of filaments has been quantitatively studied. The data can be explained by a model in which the preferred pathway for actin association-dissociation reactions at steady state in the presence of ATP involves binding of G-actin . ATP to filaments, ATP hydrolysis, and dissociation of G-actin . ADP which is then slowly converted to G-actin . ATP. As a consequence of the slow exchange of nucleotide on G-actin, the respective amounts of G-actin . ATP and G-actin . ADP coexisting with F-actin at steady state depend on the filament number concentration. G-actin coexisting with F-actin at zero number concentration of filaments would then consist of G-actin . ATP only, while the critical concentration obtained at infinite number of filaments would be that for G-actin . ADP. Values of 0.35 and 8 microM, respectively, were found for these two extreme critical concentrations for skeletal muscle actin at 20 degrees C, pH 7.8, 0.1 mM CaCl2, 1 mM MgCl2, and 0.2 mM ATP. The same value of 8 microM was directly measured for the critical concentration of G-actin . ADP polymerized in the presence of ADP and absence of ATP, and it was unaffected by fragmentation. These results have important implications for experiments in which critical concentrations are compared under conditions that change the filament number concentrations.     

Detection of conformational changes in actin by proteolytic digestion: Evidence for a new monomeric species

When KCl is added to a solution of G-actin to induce full polymerization, a decrease in the rate at which actin undergoes enzymatic proteolysis occurs. This decrease cannot be accounted for by factors affecting the enzymes employed, but rather appears to be due to a change in the conformation of G-actin. Partially polymerized actin solutions also show a reduction in digestibility which is dependent on the F-actin content, suggesting that F-actin is essentially indigestible. Moreover, low rates of digestion were also observed at sub-critical actin concentrations, where actin in the presence of 0.1 m-KCl does not polymerize. This indicates that a confomational change occurs in G-actin before the polymerization step.At sub-critical concentrations in 0.1 m-KCl, actin is in a truly monomeric state as judged by its viscosity characteristics, its inability to enhance the rate of polymerization of G-actin and its possession of ATP as the actin-bound nucleotide. These data support the existence of a new species of actin, called F-ATP-actin monomer, which has the same physical properties and the same bound nucleotide as G-actin, but digestion characteristics like F-actin. Since F-ATP-actin monomers have the same low susceptibility to proteolysis as F-ADP-actin polymers, and because both G-ATP-actin and G-ADP-actin have similar high rates of digestion, the observed change in the conformation of actin cannot be due to the phosphorylated state of the actin-bound nucleotide. Instead, the conformational change appears to be caused by the addition of KCl to G-actin.The newly-detected monomeric species is considered to be an intermediate in the polymerization process where F-ATP-actin monomers form a population of polymerizable molecules which must reach a critical concentration before nucleation and F-actin polymer formation begin.     

The mechanism of ATP–G-actin hydrolysis in Mg<Superscript>2+</Superscript>-containing solutions

NMR proton spectra were recorded in the range of proton resonance in the nucleotide aromatic ring of monomeric ATP–G-actin and the Mg²⁺–ATP–G-actin solutions in D2O to study the mechanism of ATP–G-actin hydrolysis and its role in F-actin formation in Mg²⁺-containing solutions. The experimental data show variations in the proton chemical shifts of the H2 and H8 peaks and splitting of the H8 resonance peak of G-actin-bound ATP adenine caused by interaction with magnesium dication. The observed variations in spectra are explained by hydrolysis of monomeric ATP–G-actin to ADP–G-actin, which is regarded as the initial stage of the G-actin to F-actin transformation.     

Myosin subfragment-1 interacts with two G-actin molecules in the absence of ATP

The interaction between G-actin and myosin subfragment-1 (S1) has been monitored by pyrenyl-actin fluorescence and light scattering. In low ionic strength buffer and in the absence of ATP the polymerization of G-actin induced by myosin subfragment-1 is preceded by the formation of binary GS and ternary G2S complexes in which S1 interacts tightly in rapid equilibrium (K greater than 10(7) M-1) with one and two G-actin molecules, respectively. Pyrenyl fluorescence of G-actin is enhanced 4-fold in GS and 3-fold in G2S. At concentrations of G-actin and S1 in the micromolar range and above, G2S is the predominant species at G-actin/S1 ratios equal to or greater than 1. The isomer of myosin subfragment-1 carrying the A1 light chain, S1(A1), forms a tighter ternary complex than the isomer S1(A2). Actin-bound ATP is not hydrolyzed upon formation of GS and G2S. In the presence of one molar equivalent or more of myosin subfragment-1/mol of G-actin, in low ionic strength buffer containing no nucleotides, G-actin polymerizes faster in the presence of S1(A1) than in the presence of S1(A2). The interaction of S1 with G-actin is inhibited by the binding of ATP or ADP to S1, ATP having a higher affinity for S1 than ADP. The possible structural similarity of the G2S complex to the F-acto-S1 complex in the rigor state and the potential significance of a ternary (actin)2-myosin interaction for actomyosin-based motility are discussed.     

The effects of sulfhydryl inhibitors and cytochalasin on the cytoplasmic and cytoskeletal actin of human neutrophils

To better understand the changes that occur in cytoplasmic actin during cell movement, we studied the effect of inhibitors of cell movement on the molecular conformation of actin and its incorporation into the Triton-insoluble cytoskeleton of human neutrophils. The sulfhydryl reactive compound N-ethylmaleimide caused an increase in cellular F-actin as measured by uptake of the F-actin specific fluorescent probe 7-nitrobenz-2-oxadiazole-phallacidin. However, N-ethylmaleimide reduced the amount of actin associated with the Triton-insoluble cytoskeleton. Dithiobisnitrobenzoic acid, a sulfhydryl reagent that does not cross cell membranes efficiently, did not alter the F-actin content of neutrophils. The effect of N-ethylmaleimide was blocked by the presence of dithiothreitol, a donor of sulfhydryl groups. N-ethylmaleimide did not affect the polymerization of actin in a cell-free system. Cytochalasin B did not alter F-actin content of neutrophils but did decrease actin in cytoskeletons of resting neutrophils. Cytochalasin inhibited the increase in F-actin initiated by the chemoattractant N-formylmethionylleucylphenylalanine. We propose that N-ethylmaleimide blocks the stabilization of G-actin in cytoplasm, interferes with the incorporation of F-actin polymer into the cytoskeleton, and depolymerizes the cytoskeleton. In contrast cytochalasin stabilizes G-actin in the presence of chemotactic peptide. These data suggest that reversible conversion of G-actin to F-actin and incorporation of F-actin into the Triton-insoluble cytoskeleton are important for neutrophil movement.     

Myo1c facilitates G-actin transport to the leading edge of migrating endothelial cells

Addition of actin monomer (G-actin) to growing actin filaments (F-actin) at the leading edge generates force for cell locomotion. The polymerization reaction and its regulation have been studied in depth. However, the mechanism responsible for transport of G-actin substrate to the cell front is largely unknown; random diffusion, facilitated transport via myosin II contraction, local synthesis as a result of messenger ribonucleic acid localization, or F-actin turnover all might contribute. By tracking a photoactivatable, nonpolymerizable actin mutant, we show vectorial transport of G-actin in live migrating endothelial cells (ECs). Mass spectrometric analysis identified Myo1c, an unconventional F-actin-binding motor protein, as a major G-actin-interacting protein. The cargo-binding tail domain of Myo1c interacted with G-actin, and the motor domain was required for the transport. Local microinjection of Myo1c promoted G-actin accumulation and plasma membrane ruffling, and Myo1c knockdown confirmed its contribution to G-actin delivery to the leading edge and for cell motility. In addition, there is no obvious requirement for myosin II contractile-based transport of G-actin in ECs. Thus, Myo1c-facilitated G-actin transport might be a critical node for control of cell polarity and motility.