Effect of DNAase I on muscle tropomyosin polymerization

DNAase I, an endonuclease which interacts with G-actin, also affects tropomyosin polymerization. With chicken pectoralis or bovine cardiac ventricle tropomyosin, DNAase I both prevents tropomyosin from polymerizing and disrupts already formed tropomysin filaments. DNAase I and filament tropomyosin can also form a precipitable complex. In the electron microscope, the complex is observed as irregularly margined stellate-shaped structures with a maximum size of 9 micron. Isolated DNAase I-tropomyosin stellate complex consists of a 2:1 molar ratio of DNAase I and tropomyosin, suggesting that each tropomyosin subunit can bind DNAase I.     

Dissociation of the DNAse-I . actin complex by formamide

Rabbit skeletal muscle actin labeled with 125 iodine by an enzymic method is shown to be capable of polymerization and to bind to matrix-bound pancreatic DNAse I like unlabeled G-actin. It was used to demonstrate that actin can be released from DNAse-I-agarose by 35--40% formamide. Actin which was only shortly exposed to this solvent was able to bind again to DNAse I and to form filaments indicating that it has been recovered functionally intact from the affinity matrix.     

Solubilization of native actin monomers from human erythrocyte membranes

Up to 50% of the actin in erythrocyte membranes can be solubilized at low ionic strength in a form capable of inhibiting DNAse I, in the presence of 0.4 mM ATP and 0.05 mM calcium. In the absence of calcium and ATP, actin is released but is apparently rapidly denatured. Solubilization of G-actin increases with temperature up to 37 degrees C. At higher temperatures, actin is released rapidly but quickly loses its ability to inhibit DNAse I.     

Carcinoembryonic antigen cell adhesion molecule 1 directly associates with cytoskeleton proteins actin and tropomyosin

CEA cell adhesion molecule 1 (CEACAM1), a type 1 transmembrane and homotypic cell adhesion protein belonging to the carcinoembryonic antigen (CEA) gene family and expressed on epithelial cells, is alternatively spliced to produce four major isoforms with three or four Ig-like ectodomains and either long (CEACAM1-L) or short (CEACAM1-S) cytoplasmic domains. When murine MC38 (methylcholanthrene-induced adenocarcinoma 38) cells were transfected with human CEACAM1-L and stimulated with sodium pervanadate, actin was found to co-localize with CEACAM1-L at cell-cell boundaries but not in untreated cells. When CEACAM1-L was immunoprecipitated from pervanadate-treated MC38/CEACAM1-L cells and the associated proteins were analyzed by two-dimensional gel analysis and mass spectrometry, actin and tropomyosin, among other proteins, were identified. Whereas a glutathione S-transferase (GST) fusion protein containing the l-isoform (GST-Cyto-L) bound poorly to F-actin in a co-sedimentation assay, the S-isoform fusion protein (GST-Cyto-S) co-sedimented with F-actin, especially when incubated with G-actin during polymerization (K(D) = 7.0 microm). Both GST-Cyto-S and GST-Cyto-L fusion proteins bind G-actin and tropomyosin by surface plasmon resonance studies with binding constants of 0.7 x 10(-8) and 1.0 x 10(-7) m for GST-Cyto-L to G-actin and tropomyosin, respectively, and 3.1 x 10(-8) and 1.3 x 10(-7) m for GST-Cyto-S to G-actin and tropomyosin, respectively. Calmodulin or EDTA inhibited binding of the GST-Cyto-L fusion protein to G-actin, whereas calmodulin and G-actin, but not EDTA, stimulated binding to tropomyosin. A biotinylated 14-amino acid peptide derived from the juxtamembrane portion of the cytoplasmic domain of CEACAM1-L associated with both G-actin and tropomyosin with K(D) values of 1.3 x 10(-5) and 1.8 x 10(-5) m, respectively. These studies demonstrate the direct interaction of CEACAM1 isoforms with G-actin and tropomyosin and the direct interaction of CEACAM1-S with F-actin.     

Simultaneous localization and quantification of relative G and F actin content: optimization of fluorescence labeling methods.

Previous studies of fluorescence probes for labeling the monomeric actin pool have demonstrated lack of specificity. We have used quantitative analytical methods to assess the sensitivity and specificity of rhodamine DNAse I as a probe for monomeric (G) actin. The G-actin pool of attached or suspended fibroblasts was stabilized by ice-cold glycerol and MgCl2. Formaldehyde fixation was used to clamp the filamentous (F) actin pool. G- and F-actins were stained by rhodamine DNAse I and FITC-phalloidin, respectively. Confocal microscopy indicated that the G- and F-actins were spatially separate in substrate-attached cells. Flow cytometry and fluorescence spectrophotometry demonstrated low co-labeling of the separate actin pools, although measureable background binding of rhodamine DNAse I was detectable. Estimates of the extent of actin polymerization after trypsinization demonstrated reciprocal changes of monomeric and filamentous actins, consistent with the formation of a perinuclear array of F-actin. The labeling and quantitation methods were also sufficiently sensitive to detect cell type-dependent variations in actin content. Dual labeling of cells with rhodamine DNAse I and FITC-phalloidin may provide a simple and direct method to image and quantify actin rearrangement in individual cells.     

Decline of contractility during ischemia-reperfusion injury: actin glutathionylation and its effect on allosteric interaction with tropomyosin

The severity and duration of ischemia-reperfusion injury is hypothesized to play an important role in the ability of the heart subsequently to recover contractility. Permeabilized trabeculae were prepared from a rat model of ischemia-reperfusion injury to examine the impact on force generation. Compared with the control perfused condition, the maximum force (F_max) per cross-sectional area and the rate of tension redevelopment of Ca²⁺-activated trabeculae fell by 71% and 44%, respectively, during ischemia despite the availability of a high concentration of ATP. The reduction in F_max with ischemia was accompanied by a decline in fiber stiffness, implying a drop in the absolute number of attached cross bridges. However, the declines during ischemia were largely recovered after reperfusion, leading to the hypothesis that intrinsic, reversible posttranslational modifications to proteins of the contractile filaments occur during ischemia-reperfusion injury. Examination of thin-filament proteins from ischemic or ischemia-reperfused hearts did not reveal proteolysis of troponin I or T. However, actin was found to be glutathionylated with ischemia. Light-scattering experiments demonstrated that glutathionylated G-actin did not polymerize as efficiently as native G-actin. Although tropomyosin accelerated the time course of native and glutathionylated G-actin polymerization, the polymerization of glutathionylated G-actin still lagged native G-actin at all concentrations of tropomyosin tested. Furthermore, cosedimentation experiments demonstrated that tropomyosin bound glutathionylated F-actin with significantly reduced cooperativity. Therefore, glutathionylated actin may be a novel contributor to the diverse set of posttranslational modifications that define the function of the contractile filaments during ischemia-reperfusion injury. force; troponin; cooperativity     

Fluorescent staining of the actin cytoskeleton in human lymphocytes, monocytes and polymorphonuclear cells using a DNAse 1/anti-DNAse 1 immunoglobulin fluorescein conjugated system.

The actin associated with membrane-enriched extracts of leukocytes can be quantitated by DNAse 1 inhibition. Using this assay, we previously demonstrated that the actin level in monocytes was significantly higher than that in polymorphonuclear, T and B cells respectively. However, the extracellular location of the actin fraction detected by DNAse 1 inhibition (monomeric "G") remained unclear. This study using the DNAse 1/anti DNAse 1 immunoglobulin fluorescein conjugated system demonstrated that G-actin is present primarily in the cortical cell cytoplasm of leukocytes, in confirmation of our previous biochemical findings. Since the solubilized G-actin activities of membrane-rich lymphoid cell fractions, measured by DNAse 1 inhibition, are a reflection of the migratory potential, this immunofluorescent system may permit identification of the leukocytic cell subpopulations that have a potential for active circulation.     

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.     

Tropomyosin stabilizes the pointed end of actin filaments by slowing depolymerization

Tropomyosin is postulated to confer stability to actin filaments in nonmuscle cells. We have found that a nonmuscle tropomyosin isolated from the intestinal epithelium can directly stabilize actin filaments by slowing depolymerization from the pointed, or slow-growing, filament end. Kinetics of elongation and depolymerization from the pointed end were measured in fluorescence assays using pyrenylactin filaments capped at the barbed end by villin. The initial pointed end depolymerization rate in the presence of tropomyosin averaged 56% of the control rate. Elongation from the pointed filament end in the presence of tropomyosin occurred at a lower free G-actin concentration, although the on rate constant, kappa p+, was not greatly affected. Furthermore, in the presence of tropomyosin, the free G-actin concentration was lower at steady state. Therefore, nonmuscle tropomyosin stabilizes the pointed filament end by lowering the off rate constant, kappa p-.     

Effect of muscle tropomyosin on the kinetics of polymerization of muscle actin

At saturating concentrations, tropomyosin inhibited the rate of spontaneous polymerization of ATP-actin and also inhibited by 40% the rates of association and dissociation of actin monomers to and from filaments. However, tropomyosin had no effect on the critical concentrations of ATP-actin or ADP-actin. The tropomyosin-troponin complex, with or without Ca2+, had a similar effect as tropomyosin alone on the rate of polymerization of ATP-actin. Although tropomyosin binds to F-actin and not to G-actin, the absence of an effect on the actin critical concentration is probably explicable in terms of the highly cooperative nature of the binding of tropomyosin to F-actin and its very low affinity for a single F-actin subunit relative to the affinity of one actin subunit for another in F-actin.     

Fluorescent staining of the actin cytoskeleton in human lymphocytes,monocytes and polymorphonuclear cells using a DNAse 1/anti-DNAse 1 immunoglobulin fluorescein conjugated system

Summary The actin associated with membrane-enriched extracts of leukocytes can be quantitated by DNAse 1 inhibition. Using this assay, we previously demonstrated that the actin level in monocytes was significantly higher than that in polymorphonuclear, T and B cells respectively. However, the extracellular location of the actin fraction detected by DNAse 1 inhibition (monomeric G) remained unclear. This study using the DNAse 1/anti DNAse 1 immunoglobulin fluorescein conjugated system demonstrated that G-actin is present primarily in the cortical cell cytoplasm of leukocytes, in confirmation of our previous biochemical findings. Since the solubilized G-actin activities of membrane-rich lymphoid cell fractions, measured by DNAse 1 inhibition, are a reflection of the migratory potential, this immunofluorescent system may permit identification of the leukocytic cell subpopulations that have a potential for active circulation.     

Actin depolymerization in the cyclic AMP-stimulated toad bladder epithelial cell, determined by the DNAse method

Previous studies with the rhodamine phalloidin binding assay have shown that antidiuretic hormone and 8-Br-cAMP rapidly depolymerize F-actin in toad bladder epithelial cells. We have extended these studies with DNAse inhibition assay and have found that in isolated epithelial cell suspensions, G-actin increases from 37 to 56% of total actin following 8-br-cAMP stimulation. The G-actin concentration in the epithelial cell greatly exceeds its critical concentration, indicating the requirement for a G-actin sequestering protein or proteins in this system.     

Inhibition of DNAse I activity in vivo]

Immune gamma-globulins containing antibodies to bovine DNAse I inhibit activities of bovine and mouse DNAse I both in vitro and in vivo. Bovine DNAse I was used as exogenous DNAse I in the in vivo studies and was injected to mice intraperitoneally in combination with gamma-globulins. The serous fluid of mice was used as a source of endogenous DNAse I. Both in in vitro and in vivo studies immune gamma-globulins caused a practically complete inhibition of bovine DNAse I activity, whereas the activity of mouse DNAse I (endogenous) was inhibited by 60-80%. Nonimmune gamma-globulins had no inhibitory effects whatsoever.     

The role of actin in temperature-dependent gel-sol transformation of extracts of Ehrlich ascites tumor cells

Ehrlich ascites tumor cell extracts form a gel when warmed to 25 degrees C at pH 7.0 in sucrose solution, and the gel rapidly becomes a sol when cooled to 0 degrees C. This gel-sol transformation was studied quantitatively by determining the volume or the total protein of pellets of gel obtained by low-speed centrifugation. The gelation depended on nucleotide triphosphates, Mg2+, KCl, and a reducing agent. Gelation was inhibited reversibly by 0.5 microM free Ca2+, and 25--50 ng/ml of either cytochalasin B or D, but it was not affected by 10 mM colchicine. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis demonstrated that the gel was composed of six major proteins with mol wt greater than 300,000, 270,000, 89,000, 51,000, 48,000, and 42,000 daltons. The last component was identified as cell actin because it had the same molecular weight as muscle actin and bound with muscle myosin and tropomyosin. The role of actin in gelation was studied by use of actin-inhibitors. Gelation was inhibited by a chemically modified subfragment-1 of myosin, which binds with F-actin even in the presence of ATP, and by bovine pancreatic DNase I, which tightly binds with G-actin. Muscle G-actin neutralized the inhibitory effect of DNase I when added at an equimolar ratio to the latter, and it also restored gelation after its inhibition by DNase I. These findings suggest that gelation depends on actin. However, the extracts showed temperature-dependent, cytochalasin-sensitive, and Ca2+-regulated gelation as did the original extracts when the cell actin in the extracts was replaced by muscle actin, suggesting that components other than cell actin might be responsible for these characteristics of the gelation.     

Protection of actin against proteolysis by complex formation with deoxyribonuclease I

G-actin bound to deoxyribonuclease I (DNase I) is resistant to digestion by trypsin and chymotrypsin. In the absence of DNase I, G-actin is cleaved by these proteases to yield a 33 500 molecular weight core protein which is not degraded further. The major sites of proteolytic action in the amino acid sequence of actin have been identified as being adjacent to residues arginine-62 and lysine-68 for trypsin and leucine-57 for chymotrypsin. These residues are rendered inaccessible to proteases in the buffer by complex formation with DNase I. Digestion of G-actin with pronase from Streptomyces griseus yields fragmentation patterns that are similar to those observed with trypsin and chymotrypsin. This is likely to be because the specificities of the major constituents of pronase resemble those of trypsin and chymotrypsin. Again, complex formation with DNase I protects the otherwise vulnerable bonds in actin against proteolysis. Incubation with subtilisin Carlsberg leads to complete digestion of G-actin. No subtilisin-resistant core protein accumulates during the incubation. Protection of G-actin when complexed to DNase I is less than complete in this case but still is significant. This is interpreted in terms of the broad specificity of subtilisin and the observed fragmentation pattern of free G-actin when treated with subtilisin.     

Imaging remodeling of the actin cytoskeleton in vascular smooth muscle cells after mechanosensitive arteriolar constriction

Experiments were performed to determine whether remodeling of the actin cytoskeleton contributes to arteriolar constriction. Mouse tail arterioles were mounted on cannulae in a myograph and superfused with buffer solution. The alpha1-adrenergic agonist phenylephrine (0.1-1 micromol/l) caused constriction that was unaffected by cytochalasin D (300 nmol/l) or latrunculin A (100 nmol/l), inhibitors of actin polymerization. In contrast, each compound abolished the mechanosensitive constriction (myogenic response) evoked by elevation in transmural pressure (PTM; 10-60 or 90 mmHg). Arterioles were fixed, permeabilized, and stained with Alexa-568 phalloidin and Alexa-488 DNAse I to visualize F-actin and G-actin, respectively, using a Zeiss 510 laser scanning microscope. Elevation in PTM, but not phenylephrine (1 micromol/l), significantly increased the intensity of F-actin and significantly decreased the intensity of G-actin staining in arteriolar vascular smooth muscle cells (VSMCs). The increase in F-actin staining caused by an elevation in PTM was inhibited by cytochalasin D. In VSMCs at 10 mmHg, prominent F-actin staining was restricted to the cell periphery, whereas after elevation in PTM, transcytoplasmic F-actin fibers were localized through the cell interior, running parallel to the long axis of the cells. Phenylephrine (1 micromol/l) did not alter the architecture of the actin cytoskeleton. In contrast to VSMCs, the actin cytoskeleton of endothelial or adventitial cells was not altered by an elevation in PTM. Therefore, the actin cytoskeleton of VSMCs undergoes dramatic alteration after elevation in PTM of arterioles and plays a selective and essential role in mechanosensitive myogenic constriction.     

Tropomyosin and myosin subfragment 1 induce in thin muscle fiber filaments differing conformational changes in the C-terminal portion of the polypeptide chain of actin

Muscle fibres, free of myosin, troponin and tropomyosin, containing thin filaments reconstructed from G-actin and modified by fluorescent label 1,5-IAEDANS were used for polarized microfluorimetric studies of the effect of tropomyosin (TM) from smooth muscles, and of subfragment 1 (S1) from skeletal muscles on the structural state of F-actin. TM and S1 were shown to initiate different changes in polarized fluorescence of 1,5-IAEDANS of F-actin: TM increases, whereas S1 decreases fluorescent anisotropy. It was suggested that the structural state of F-actin may differ in the C-terminal of polypeptide chain of actin.     

Purification of an 80 kDa Ca2+-dependent actin-modulating protein, which severs actin filaments, from bovine adrenal medulla

A protein with a molecular weight of 80 kDa, which binds Ca2+-dependently to actin, was purified chromatographically from bovine adrenal medulla by using Sephacryl S-300, DEAE-Sepharose, actin-DNase I Sepharose, and Sephacryl S-200. This protein was retained on an actin-DNase I affinity column only in the presence of Ca2+, and could be eluted from this column by EGTA. The 80 kDa protein is a monomer and binds to G-actin in a Ca2+-dependent manner at an equimolar ratio. It caused fragmentation of actin filaments at more than 4 X 10(-7) M free Ca2+ concentration, as determined by low-shear viscometry and electron microscopy. Saturating amounts of tropomyosin showed a slight protective effect on the fragmentation of actin filaments by the 80 kDa protein. Considering the mode of action on actin filaments, the 80 kDa protein reported here seems to be a gelsolin-like protein. Gel electrophoresis of this protein revealed changes in mobility depending upon the concentration of Ca2+. This result also indicates that the 80 kDa protein itself is a Ca2+-binding protein.