Acanthamoeba Actin Research Articles

Ca2+ bound to the high affinity divalent cation-binding site of actin enhances actophorin-induced depolymerization of muscle F-actin but inhibits actophorin-induced depolymerization of Acanthamoeba F-actin.

The cation tightly bound to actin, Mg2+ or Ca2+, affects the ability of actophorin to accelerate depolymerization of filaments and bind to monomers of actin prepared from rabbit skeletal muscle and Acanthamoeba castellanii. Actophorin interacted similarly with muscle and Acanthamoeba Mg2(+)-F-actin but depolymerized muscle Mg2(+)-F-actin more efficiently. Muscle Ca2(+)-F-actin depolymerized about 5 times more rapidly than Mg2(+)-F-actin in the presence of actophorin but Acanthamoeba Ca2(+)-F-actin was highly resistant to actophorin. Muscle actin subunits dissociated more rapidly than Acanthamoeba actin subunits from copolymers of muscle and Acanthamoeba Ca2(+)-actin upon addition of actophorin although Acanthamoeba actin dissociated much more rapidly from copolymers than from its homopolymer. The Kd of the 1:1 complex between actophorin and monomeric actin was somewhat lower for muscle Mg2(+)-ATP-G-actin than for both Acanthamoeba Mg2(+)-ATP-G-actin and muscle Ca2(+)-ATP-G-actin. The data for the interactions of actophorin with Acanthamoeba Ca2(+)-ATP-G-actin or muscle and amoeba Mg2(+)- and Ca2(+)-ADP-G-actin were incompatible with the formation of 1:1 actin: actophorin complexes and, thus, Kd values could not be calculated. While it may not be surprising that actophorin would interact differently with Mg2(+)- and Ca2(+)-actin, it is unexpected that the nature of the tightly bound cation would have such dramatically opposite effects on the ability of actophorin to depolymerize muscle and Acanthamoeba F-actin. Differential severing by actophorin, with Acanthamoeba Ca2(+)-actin being almost totally resistant, is sufficient to explain the results but other possibilities cannot be ruled out.

Rabbit Skeletal Muscle Actin Behaves Differently Than Acanthamoeba Actin When Added to Solube Extracts of Acanthamoeba castellanii

Cold extracts of Acantharnoeba castellanii in polymerizing buffer contain 32 μM unpolymerized actin of which about 20% polymerizes (as measured by ultracentrifugation) when the extract is warmed to 22°C. As quantified by the increase in fluorescence of pyrene-labeled actin, 16% of muscle G-actin and 46% of Acanthamoeba G-actin polynterized when 0.8 μM of each was added to warm extracts of Acanthamoeba. Added muscle F-actin (1.2 μM) rapidly and totally depolymerized and then partially repolymerized whereas 1.2 μM added Acanthamoeba F-actin was stable indefinitely. Furthermore, muscle actin subunits were completely removed from copolymers of muscle and Acanthamoeba F-actin while all the amoeba actin remained polymerized when the copolymers contained at least 50% amoeba actin. These results suggest that exogenous tracer actin may not be an accurate indicator of the dynamics of endogenous actin in extracts and cells.

The covalent structure of Acanthamoeba actobindin.

Actobindin is a protein from Acanthamoeba castellanii with bivalent affinity for monomeric actin. Because it can bind two molecules of actin, actobindin is a substantially more potent inhibitor of the early phase of actin polymerization than of F-actin elongation. The complete amino acid sequence of 88 residues has been deduced from the determined sequences of overlapping peptides obtained by cleavage with trypsin, Staphylococcus V8 protease, endoproteinase Asp-N, and CNBr. Actobindin contains 2 trimethyllysine residues and an acetylated NH2 terminus. About 76% of the actobindin molecule consists of two nearly identical repeated segments of approximately 33 residues each. This could explain actobindin's bivalent affinity for actin. The circular dichroism spectrum of actobindin is consistent with 15% alpha-helix and 22% beta-sheet structure. A hexapeptide with sequence LKHAET, which occurs at the beginning of each of the repeated segments of actobindin, is very similar to sequences found in tropomyosin, muscle myosin heavy chain, paramyosin, and Dictyostelium alpha-actinin. A longer stretch in each repeated segment is similar to sequences in mammalian and amoeba profilins. Interestingly, the sequences around the trimethyllysine residues in each of the repeats are similar to the sequences flanking the trimethyllysine residue of rabbit reticulocyte elongation factor 1 alpha, but not to the sequences around the trimethyllysine residues in Acanthamoeba actin and Acanthamoeba profilins I and II.

Isolation and characterization of one isoform of actin from cultured soybean cells

Cultured soybean cells (SB-1 cell line) were plasmolyzed and lyophilized. Extraction of the dried powder and fractionation yielded a polypeptide with the following key properties: (a) it has a molecular weight of ~45,000 and an isoelectric point of ~5.9; (b) it is immunologically cross-reactive with rabbit antibodies affinity purified against the M r 45,000 polypeptide of calf thymus actin; (c) it is eluted from a DEAE-cellulose column at the same ionic strength as Acanthamoeba actin; (d) it yields peptide maps, after limited proteolysis with V8 protease, similar if not identical to those of rabbit muscle actin; and (e) it binds specifically to deoxyribonuclease I. These molecular and binding properties indicate that we have purified one isoform of actin from Soybean Cells.

Antibodies to actin in autoimmune neutropenia

In an effort to characterize the cellular antigens recognized by anti- neutrophil antibodies in autoimmune neutropenia, we studied sera, purified immunoglobulin G (IgG) and isolated F(ab')2 from 70 neutropenic patients suspected of this diagnosis. Anti-neutrophil antibodies were found in the sera of 36 of these patients by either 125I-staph A binding or immunofluorescence cytometric techniques that detected increased binding of patients' IgG to normal neutrophils. Anti- neutrophil antibody positive sera were then evaluated for specific binding to electrophoretically separated neutrophil membrane-associated proteins by immunoblotting. A 43-Kd protein was consistently identified by eight anti-neutrophil antibody positive sera. The specificity of binding to this protein was confirmed with affinity purified IgG and F(ab')2 fragments prepared from these sera. Sera from 20 healthy normal controls and from 22 non-neutropenic, anti-neutrophil antibody negative rheumatoid arthritis patients failed to bind this protein. Separate studies identified the 43-Kd protein as actin. Purified Acanthamoeba actin comigrated with the protein and was specifically bound by anti- neutrophil antibody positive IgG. Moreover, two actin-specific monoclonal antibodies bound to the 43-Kd membrane-associated protein in immunoblots. In addition, a rabbit anti-actin antiserum not only bound to this same 43-Kd protein but also expressed anti-neutrophil antibody activity against normal human neutrophils, as did purified human anti- actin IgG prepared by affinity chromatography from the serum of one of the index patients. These studies indicate that the anti-neutrophil antibodies of certain patients with autoimmune neutropenia include autoantibodies specific for actin. The molecules on the surface of neutrophils, which have actin-like antigenic epitopes and are recognized by these anti-actin antibodies, remain to be characterized.

Antibodies to Actin in Autoimmune Neutropenia

In an effort to characterize the cellular antigens recognized by anti-neutrophil antibodies in autoimmune neutropenia, we studied sera, purified immunoglobulin G (IgG) and isolated F(ab')2 from 70 neutropenic patients suspected of this diagnosis. Anti-neutrophil antibodies were found in the sera of 36 of these patients by either 125I-staph A binding or immunofluorescence cytometric techniques that detected increased binding of patients' IgG to normal neutrophils. Anti-neutrophil antibody positive sera were then evaluated for specific binding to electrophoretically separated neutrophil membrane-associated proteins by immunoblotting. A 43-Kd protein was consistently identified by eight anti-neutrophil antibody positive sera. The specificity of binding to this protein was confirmed with affinity purified IgG and F(ab')2 fragments prepared from these sera. Sera from 20 healthy normal controls and from 22 non-neutropenic, anti-neutrophil antibody negative rheumatoid arthritis patients failed to bind this protein. Separate studies identified the 43-Kd protein as actin. Purified Acanthamoeba actin comigrated with the protein and was specifically bound by anti-neutrophil antibody positive IgG. Moreover, two actin-specific monoclonal antibodies bound to the 43-Kd membrane-associated protein in immunoblots. In addition, a rabbit anti-actin antiserum not only bound to this same 43-Kd protein but also expressed anti-neutrophil antibody activity against normal human neutrophils, as did purified human anti-actin IgG prepared by affinity chromatography from the serum of one of the index patients. These studies indicate that the anti-neutrophil antibodies of certain patients with autoimmune neutropenia include autoantibodies specific for actin. The molecules on the surface of neutrophils, which have actin-like antigenic epitopes and are recognized by these anti-actin antibodies, remain to be characterized.

Acanthamoeba actin and profilin can be cross-linked between glutamic acid 364 of actin and lysine 115 of profilin.

Acanthamoeba profilin was cross-linked to actin via a zero-length isopeptide bond using carbodiimide. The covalently linked 1:1 complex was purified and treated with cyanogen bromide. This cleaves actin into small cyanogen bromide (CNBr) peptides and leaves the profilin intact owing to its lack of methionine. Profilin with one covalently attached actin CNBr peptide was purified by gel filtration followed by gel electrophoresis and electroblotting on polybase-coated glass-fiber membranes. Since the NH2 terminus of profilin is blocked, Edman degradation gave only the sequence of the conjugated actin CNBr fragment beginning with Trp-356. The profilin-actin CNBr peptide conjugate was digested further with trypsin and the cross-linked peptide identified by comparison with the tryptic peptide pattern obtained from carbodiimide-treated profilin. Amino-acid sequence analysis of the cross-linked tryptic peptides produced two residues at each cycle. Their order corresponds to actin starting at Trp-356 and profilin starting at Ala-94. From the absence of the phenylthiohydantoin-amino acid residues in specific cycles, we conclude that actin Glu-364 is linked to Lys-115 in profilin. Experiments with the isoforms of profilin I and profilin II gave identical results. The cross-linked region in profilin is homologous with sequences in the larger actin filament capping proteins fragmin and gelsolin.

Evaluation of the binding of Acanthamoeba profilin to pyrene-labeled actin by fluorescence enhancement

We have used a fluorescence assay to measure the binding of Acanthamoeba profilin to monomeric Acanthamoeba and rabbit skeletal muscle actin labeled on cysteine-374 with pyrene iodacetamide. The wavelengths of the pyrene excitation and emission maxima are constant at 346 and 386 nm, but the fluorescence is enchanced up to 50% by profilin. The higher fluorescence is largely due to higher absorbance in the presence of profilin. The fluorescence enhancement has a hyperbolic dependence on the concentration of profilin, suggesting a single class of binding sites. Linear Scatchard plots yield an estimate of the dissociation constant, K d , of the complex of profilin with pyrenyl-actin. In low-ionic-strength buffers with 2 to 6 m m imidazole (pH 7.0) and 0.1 m m CaCl 2 the K d is 9 μ m for both muscle and Acanthamoeba actin. In 50 m m KCl the K d for the complex with Acanthamoeba actin is 16 μ m, while the K d for the complex with muscle actin is greater than 50 μ m.

Acanthamoeba profilin binding to fluorescein-labeled actins

The binding constants of Acanthamoeba profilin to fluorescein-labeled actin from Acanthamoeba and from rabbit skeletal muscle have been determined by measuring the reduction in the actin tracer diffusion coefficients, determined by fluorescence photobleaching recovery, as a function of added profilin concentration. Data were analyzed using a two-parameter nonlinear regression analysis to determine the profilin-actin dissociation constant Kd and the profilactin diffusion coefficient, DPA. For fluorescein-labeled Acanthamoeba actin, the least-squares estimates for Kd and DPA, along with approximate single standard deviation confidence intervals, are Kd = 48 (36, 63) microM and DPA = 6.72 (6.62, 6.81) X 10(-7) cm2s-1. For fluorescein-labeled skeletal muscle actin, the corresponding values are Kd = 147 (94, 225) microM and DPA = 6.7 (6.3, 7.0) X 10(-7) cm2s-1. These dissociation constants are the first to be determined from direct physical measurement; they are in agreement with values inferred from earlier studies on the effect of profilin on the assembly of actin that had been fluorescently labeled or otherwise modified at Cys 374. These results place important restrictions on the interpretation of experiments in which fluorescently labeled actin is used as a probe of living cytoplasm or cytoplasmic extracts that include profilin.

Purification and characterization of actobindin, a new actin monomer-binding protein from Acanthamoeba castellanii.

Actobindin is a new actin-binding protein isolated from Acanthamoeba castellanii. It is composed of two possibly identical polypeptide chains of approximately 13,000 daltons, as determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis, and with isoelectric points of 5.9. In the native state, actobindin appears to be a dimer of about 25,000 daltons by sedimentation equilibrium analysis. It contains no tryptophan and probably no tyrosine. Actobindin reduces the concentration of F-actin at steady state and inhibits the rate of filament elongation to extents consistent with the formation of a 1:1 actobindin-G-actin complex in a reaction with a KD of about 5 microM. The available data do not eliminate the possibility of other stoichiometries for the complex, but they are not consistent with any significant interaction between actobindin and F-actin. Despite the similarities between the effects of actobindin and Acanthamoeba profilin on the polymerization of Acanthamoeba actin, the two proteins are quite distinct with different native and subunit molecular weights, different isoelectric points, and different amino acid compositions. Also, unlike profilin, actobindin binds as well to rabbit skeletal muscle G-actin and to pyrenyl-labeled G-actin as it does to unmodified Acanthamoeba G-actin.

Assembly of Acanthamoeba actin in the presence of Acanthamoeba profilin measured by fluorescence photobleaching recovery.

Assembly of Acanthamoeba actin, of which trace quantities had been labeled with 5-(iodoacetamido)-fluorescein, was quantified using the modulation detection method of fluorescence photobleaching recovery (FPR). This technique permits explicit determination of the fraction of labeled actin incorporated into filaments and the translational diffusion coefficients of the filaments, from which filament length can be calculated. Addition of Acanthamoeba profilin in molar ratios to actin of about 1.1:1 and 2.3:1 retarded the initial kinetics of assembly (induced by addition of 2mM Mg+2) and reduced the fraction of actin incorporated into filaments. The diffusion coefficients of filaments formed were greatly changed by the presence of profilin at short times, but the differences became increasingly smaller at longer times. After 26 hr. the filaments formed in 1.1:1 profilin were about 12% shorter and in 2.3:1 profilin were about 20% shorter than filaments formed by actin alone under the same conditions.

Lack of NH2-terminal processing of actin from Acanthamoeba castellanii.

Acanthamoeba actin is the only actin sequenced to date that has neither an NH2-terminal Ac-Asp nor Ac-Glu residue. The protein begins with an Ac-Gly-Asp and is coded for by a gene that specifies a polypeptide beginning Met-Gly-Asp. Thus, the Acanthamoeba actin gene would appear to specify a class II actin with the usual NH2-terminal Cys replaced with a Gly. Previous studies (Rubenstein, P. A., and Martin, D. J. (1983) J. Biol. Chem. 258, 11354-11360) revealed that for class II actins the Met is probably removed early in translation and the Cys is removed post-translationally as an Ac-Cys residue. Two possibilities might explain why Acanthamoeba actin is not processed in a similar fashion. Either Ac-Gly is not a substrate for the enzyme or the enzyme is absent from the organism. To test these alternatives, Acanthamoeba actin was labeled in vivo with [35S]methionine and incubated with processing enzyme from rat liver, rabbit reticulocytes, and Dictyostelium. In no case did the processing reaction occur, indicating that Ac-Gly is not recognized by the enzyme as a substrate. Furthermore, we could not reproducibly detect the presence of a processing enzyme in Acanthamoeba. We were, however, able to show the presence of such an enzyme in Dictyostelium, the first demonstration of this activity in a lower eukaryote.

Reinvestigation of the inhibition of actin polymerization by profilin.

In buffer containing 50 mM KCl, 1 mM MgCl2, 1 mM EGTA, 5 mM imidazole, pH 7.5, 0.1 mM CaCl2, 0.2 mM dithiothreitol, 0.01% NaN3, and 0.2 mM ATP, the KD for the formation of the 1:1 complex between Acanthamoeba actin and Acanthamoeba profilin was about 5 microM. When the actin was modified by addition of a pyrenyl group to cysteine 374, the KD increased to about 40 microM but the critical concentration (0.16 microM) was unchanged. The very much lower affinity of profilin for modified actin explains the anomalous critical concentrations curves obtained for 5-10% pyrenyl-labeled actin in the presence of profilin and the apparently weak inhibition by profilin of the rate of filament elongation when polymerization is quantified by the increase in fluorescence of pyrenyl-labeled actin. Light-scattering assays of the polymerization of unmodified actin in the absence and presence of profilin gave a similar value for the KD (about 5-10 microM) when determined by the increase in the apparent critical concentration of F-actin at steady state at all concentrations of actin up to 20 microM and by the inhibition of the initial rates of polymerization of actin nucleated by either F-actin or covalently cross-linked actin dimer. In the same buffer, but with ADP instead of ATP, the critical concentration of actin was higher (4.9 microM) and the KD of the profilin-actin complex was lower for both unmodified (1-2 microM) and 100% pyrenyl-labeled actin (4.9 microM).

Quantitative analysis of the effect of Acanthamoeba profilin on actin filament nucleation and elongation

The current view of the mechanism of action of Acanthamoeba profilin is that it binds to actin monomers, forming a complex that cannot polymerize [Tobacman, L. S., & Korn, E. D. (1982) J. Biol. Chem. 257, 4166-4170; Tseng, P., & Pollard, T. D. (1982) J. Cell Biol. 94, 213-218; Tobacman, L. S., Brenner, S. L., & Korn, E. D. (1983) J. Biol. Chem. 258, 8806-8812]. This simple model fails to predict two new experimental observations made with Acanthamoeba actin in 50 mM KC1, 1 mM MgCl2, and 1 mM EGTA. First, Acanthamoeba profilin inhibits elongation of actin filaments far more at the pointed end than at the barbed end. According, to the simple model, the Kd for the profilin-actin complex is less than 5 microM on the basis of observations at the pointed end and greater than 50 microM for the barbed end. Second, profilin inhibits nucleation more strongly than elongation. According to the simple model, the Kd for the profilin-actin complex is 60-140 microM on the basis of two assays of elongation but 2-10 microM on the basis of polymerization kinetics that reflect nucleation. These new findings can be explained by a new and more complex model for the mechanism of action that is related to a proposal of Tilney and co-workers [Tilney, L. G., Bonder, E. M., Coluccio, L. M., & Mooseker, M. S. (1983) J. Cell Biol. 97, 113-124]. In this model, profilin can bind both to actin monomers with a Kd of about 5 microM and to the barbed end of actin filaments with a Kd of about 50-100 microM. An actin monomer bound to profilin cannot participate in nucleation or add to the pointed end of an actin filament. It can add to the barbed end of a filament. When profilin is bound to the barbed end of a filament, actin monomers cannot bind to that end, but the terminal actin protomer can dissociate at the usual rate. This model includes two different Kd's--one for profilin bound to actin monomers and one for profilin bound to an actin molecule at the barbed end of a filament. The affinity for the end of the filament is lower by a factor of 10 than the affinity for the monomer, presumably due to the difference in the conformation of the two forms of actin or to steric constraints at the end of the filament.

Purification of a high molecular weight actin filament gelation protein from Acanthamoeba that shares antigenic determinants with vertebrate spectrins.

I have purified a high molecular weight actin filament gelation protein (GP-260) from Acanthamoeba castellanii, and found by immunological cross-reactivity that it is related to vertebrate spectrins, but not to two other high molecular weight actin-binding proteins, filamin or the microtubule-associated protein, MAP-2. GP-260 was purified by chromatography on DEAE-cellulose, selective precipitation with actin and myosin-II, chromatography on hydroxylapatite in 0.6 M Kl, and selective precipitation at low ionic strength. The yield was 1-2 micrograms/g cells. GP-260 had the same electrophoretic mobility in SDS as the 260,000-mol-wt alpha-chain of spectrin from pig erythrocytes and brain. Electron micrographs of GP-260 shadowed on mica showed slender rod-shaped particles 80-110 nm long. GP-260 raised the low shear apparent viscosity of solutions of Acanthamoeba actin filaments and, at 100 micrograms/ml, formed a gel with a 8 microM actin. Purified antibodies to GP-260 reacted with both 260,000- and 240,000-mol-wt polypeptides in samples of whole ameba proteins separated by gel electrophoresis in SDS, but only the 260,000-mol-wt polypeptide was extracted from the cell with 0.34 M sucrose and purified in this study. These antibodies to GP-260 also reacted with purified spectrin from pig brain and erythrocytes, and antibodies to human erythrocyte spectrin bound to GP-260 and the 240,000-mol-wt polypeptide present in the whole ameba. The antibodies to GP-260 did not bind to chicken gizzard filamin or pig brain MAP-2, but they did react with high molecular weight polypeptides from man, a marsupial, a fish, a clam, a myxomycete, and two other amebas. Fluorescent antibody staining with purified antibodies to GP-260 showed that it is concentrated near the plasma membrane in the ameba.

Polymerization of ADP-actin.

Using hexokinase, glucose, and ATP to vary reversibly the concentrations of ADP and ATP in solution and bound to Acanthamoeba actin, I measured the relative critical concentrations and elongation rate constants for ATP-actin and ADP-actin in 50 mM KCl, 1 mM MgCl2, 1 mM EGTA, 0.1 mM nucleotide, 0.1 mM CaCl2, 10 mM imidazole, pH 7. By both steady-state and elongation rate methods, the critical concentrations are 0.1 microM for ATP-actin and 5 microM for ADP-actin. Consequently, a 5 microM solution of actin can be polymerized, depolymerized, and repolymerized by simply cycling from ATP to ADP and back to ATP. The critical concentrations differ, because the association rate constant is 10 times higher and the dissociation rate constant is five times lower for ATP-actin than ADP-actin. These results show that ATP-actin occupies both ends of actin filaments growing in ATP. The bound ATP must be split on internal subunits and the number of terminal subunits with bound ATP probably depends on the rate of growth.

Amino acid sequence of Acanthamoeba actin

By amino acid sequence studies, only one form of cytoplasmic actin was detected in Acanthamoeba castellanii. Its amino acid sequence is very similar to the sequences of Dictyostelium and Physarum actins, from which Acanthamoeba actin differs in only nine and seven residues, respectively, including the deletion of the first residue. Acanthamoeba actin is unique in containing a blocked NH 2-terminal neutral amino acid (glycine), while all other actins sequenced thus far have a blocked acidic amino acid (aspartic or glutamic) at the NH 2 terminus. Acanthamoeba actin is also unique in that it contains an N ε-trimethyllysine residue at position 326. Like other actins, Acanthamoeba actin contains an N T-methylhistidine residue at position 73. The protein sequence is in complete agreement with the sequence derived from the nucleotide sequence of an expressed actin gene.

Physical, immunochemical, and functional properties of Acanthamoeba profilin.

Acanthamoebe profilin has a native molecular weight of 11,700 as measured by sedimentation equilibrium ultracentrifugation and an extinction coefficient at 280 nm of 1.4 X 10(4) M-1cm-1. Rabbit antibodies against Acanthamoeba profilin react only with the 11,700 Mr polypeptide among all other ameba polypeptides separated by electrophoresis. These antibodies react with a 11,700 Mr polypeptide in Physarum but not with any proteins of Dictyostelium or Naeglaria. Antibody-binding assays indicate that approximately 2% of the ameba protein is profilin and that the concentration of profilin is approximately 100 mumol/liter cells. During ion exchange chromatography of soluble extracts of Acanthamoeba on DEAE-cellulose, the immunoreactive profilin splits into two fractions: an unbound fraction previously identified by Reichstein and Korn (1979, J. Biol. Chem., 254:6174-6179) and a tightly bound fraction. Purified profilin from the two fractions is identical by all criteria tested. The tightly bound fraction is likely to be attached indirectly to the DEAE, perhaps by association with actin. By fluorescent antibody staining, profilin is distributed uniformly throughout the cytoplasmic matrix of Acanthamoeba. In 50 mM KCl, high concentrations of Acanthamoeba profilin inhibit the elongation rate of muscle actin filaments measured directly by electron microscopy, but the effect is minimal in KCl with 2 MgCl2. By using the fluorescence change of pyrene-labeled Acanthamoeba actin to assay for polymerization, we confirmed our earlier observation (Tseng, P. C.-H., and T. D. Pollard, 1982, J. Cell Biol. 94:213-218) that Acanthamoeba profilin inhibits nucleation much more strongly than elongation under physiological conditions.

Structure of the actin molecule determined from electron micrographs of crystalline actin sheets with a tentative alignment of the molecule in the actin filament

Electron microscopy and image processing of negatively stained crystalline sheets induced from Acanthamoeba actin have been used to yield a three-dimensional reconstruction of the actin molecule, including data to a maximum resolution of 15 A. This model shows actin to be an asymmetric, wedge-shaped molecule. A three-dimensional reconstruction of an averaged, polar actin filament from negatively stained polylysine-induced actin filament paracrystals has also been computed. We show two possible ways in which the wedge-shaped actin molecule from the sheets can be placed into such a filament reconstruction. In both, the major intermolecular contacts are formed on complementary surfaces of the actin subunit and follow the left-handed genetic helix of the filament, a feature also found in the filament reconstruction.

Effect of Acanthamoeba profilin on the pre-steady state kinetics of actin polymerization and on the concentration of F-actin at steady state.

The interaction of Acanthamoeba actin and Acanthamoeba profilin was evaluated as a function of ionic conditions. In the presence of 2 mM MgCl2 or 1 mM MgCl2 and 50 mM KCl, profilin decreased the concentration of F-actin at steady state, and inhibited the rates of filament elongation and spontaneous nucleation and polymerization. All of the experimental data were quantitatively accounted for on the basis of a 1:1 complex between profilin and monomeric actin with a Kr between 4 and 9 microM, the same value obtained previously in the absence of MgCl2. Therefore, the Mg2+ concentration did not affect the KD of the profilin-actin complex in these experiments. On the other hand, profilin did greatly amplify the decrease in concentration of F-actin at steady state caused by lowering the Mg2+ concentration. This results from the effect of Mg2+ on the critical concentration of the actin monomer with which the profilin-actin complex is in equilibrium. When the Mg2+ concentration is lowered, the critical concentration of actin monomer increases so that more profilin-actin complex is formed. Thus, appreciably more F-actin depolymerizes than in the absence of profilin. In this way, profilin could function intracellularly to convert small changes in critical concentration into large changes in the concentration of F-actin.