Viscometric analysis of the gelation of Acanthamoeba extracts and purification of two gelation factors

We have studied the kinetics of the gelation process that occurs upon warming cold extracts of Acanthamoeba using a low-shear falling ball assay. We find that the reaction has at least two steps, requires 0.5 mM ATP and 1.5 mM MgCl2, and is inhibited by micromolar Ca++. The optimum pH is 7.0 and temperature, 25 degrees-30 degrees C. The rate of the reaction is increased by cold preincubation with both MgCl2 and ATP. Nonhydrolyzable analogues of ATP will not substitute for ATP either in this "potentiation reaction" or in the gelation process. Either of two purified or any one of four partially purified Acanthamoeba proteins will cross-link purified actin to form a gel, but none can account for the dependence of the reaction in the crude extract on Mg-ATP or its regulation by Ca++. This suggests that the extract contains, in addition to actin-cross-linking proteins, factors dependent on Mg-ATP and Ca++ that regulate the gelation process.     

Induction of either contractile or structural actin-based gels in sea urchin egg cytoplasmic extract

The gel formed by warming the 100,000 g supernate of isotonic extracts of sea urchin eggs to 40 degrees C is made up of actin and two additional proteins of mol wt of 58,000 and 220,000. Actin and 58,000 form a characteristic structural unit which has now been identified in the microvilli of the urchin egg and in the filopods of urchin coelomocytes. However, egg extract gels did not contract as those from other cell types do, and the aim of these experiments was to determine the reason for this lack of contraction. Although the extracts are dialyzed to a low ionic strength, myosin is present in soluble form and makes up approximately 1% of the protein of the extract. It becomes insoluble in the presence of high ATP concentrations at 0 degrees C, and the precipitate formed under these conditions consists almost entirely of myosin. This procedure provides a simple method of isolating relatively pure myosin without affecting other extract components and functions. Contraction will follow gelation in these extracts if the temperature and time of incubation used to induce actin polymerization are reduced to minimize myosin inactivation. At the optimal ATP and KCl concentration for contraction, the contracted material has an additional 250,000 component and contains very little 58,000. The conditions found to provide maximum gel yields favor the formation of the actin-58,000-220,000 structural gel, while reduced temperature and increase in KCl concentration results in a contractile gel whose composition is similar to those reported from amoeboid cell types. Both the structural protein cores found in the egg microvilli and a gel contraction related to the amoeboid motion which is seen in later urchin embryonic development can thus be induced in vitro in the same extract.     

Interconversion of structural and contractile actin gels by insertion of myosin during assembly

Extracts of the soluble cytoplasmic proteins of the sea urchin egg form gels of different composition and properties depending on the temperature used to induce actin polymerization. At temperatures that inactivate myosin, a gel composed of actin, fascin, and a 220,000-mol- wt protein is formed. Fascin binds actin into highly organized units with a characteristic banding pattern, and these actin-fascin units are the structural core of the sea urchin microvilli formed after fertilization and of the urchin coelomocyte filopods. Under milder conditions a more complex myosin-containing gel is formed, which contracts to a small fraction of its original volume within an hour after formation. What has been called "structural" gel can be assembled by combining actin, fascin, and the 220,000-mol-wt protein in 50-100 mM KCl; the aim of the experiments reported here was to determine whether myosin could be included during assembly, thereby interconverting structural and contractile gel. This approach is limited by the aggregation of sea urchin myosin at the low salt concentrations utilized in gel assembly. A method has been devised for the sequential combination of these components under controlled KCl and ATP concentrations that allows the formation of a gel containing dispersed myosin at a final concentration of 60-100 mM KCl. These gels are stable at low (approximately 10 micron) ATP concentrations, but contract to a small volume in the presence of higher (approximately 100 micron) ATP. Contraction can be controlled by forming a stable gel at low ATP and then overlaying it with a solution containing sufficient ATP to induce contraction. This system may provide a useful model for the study of the interrelations between cytoplasmic structure and motility.     

Purification from Acanthamoeba castellanii of proteins that induce gelation and syneresis of F-actin.

From Acanthamoeba castellanii, we have purified four proteins each of which alone causes a solution of F-actin to gel. The four active proteins have subunit molecular weights of about 23,000, 28,000, 32,000 and 38,000, respectively; the last three may be dimers in their native proteins. Together, these four proteins account for about 97% of the gelation activity of the whole extract; not more than about 3% of the total activity of the unfractionated extract can be due to a 250,000-dalton polypeptide. Another protein fraction, purified by agarose chromatography, induces shrinking (syneresis) of gels formed from F-actin and any of the gelation factors. That fraction contains a high Ca2+-, low (K+,EDTA)-ATPase and a major polypeptide of 170,000 daltons both of which bind to actin in the shrunken gel pellet. The active fraction does not contain the previously described Acanthamoeba myosin (Pollard, T. D., and Korn, E. D. (1973) J. Biol. Chem. 248, 4682-4690).     

Characterization of renatured profilin purified by urea elution from poly-L-proline agarose columns

We present evidence that native profilin can be purified from cellular extracts of Acanthamoeba, Dictyostelium, and human platelets by affinity chromatography on poly-L-proline agarose. After applying cell extracts and washing the column with 3 M urea, homogeneous profilin is eluted by increasing the urea concentration to 6-8 M. Acanthamoeba profilin-I and profilin-II can subsequently be separated by cation exchange chromatography. The yield of Acanthamoeba profilin is twice that obtained by conventional methods. Several lines of evidence show that the profilins fully renature after removal of the urea by dialysis: 1) dialyzed Acanthamoeba and human profilins rebind quantitatively to poly-L-proline and bind to actin in the same way as native, conventionally purified profilin without urea treatment; 2) dialyzed profilins form 3-D crystals under the same conditions as native profilins; 3) dialyzed Acanthamoeba profilin-I has an NMR spectrum identical with that of native profilin-I; and 4) dialyzed human and Acanthamoeba profilins inhibit actin polymerization. We report the discovery of profilin in Dictyostelium cell extracts using the same method. Based on these observations we conclude that urea elution from poly-L-proline agarose followed by renaturation will be generally useful for preparing profilins from a wide variety of cells. Perhaps also of general use is the finding that either myosin-II or alpha-actinin in crude cell extracts can be bound selectively to the poly-L-proline agarose column depending on the ionic conditions used to equilibrate the column. We have purified myosin-II from both Acanthamoeba and Dictyostelium cell extracts and alpha-actinin from Acanthamoeba cell extracts in the appropriate buffers. These proteins are retained as complexes with actin by the agarose and not by a specific interaction with poly-L-proline. They can be eluted by dissociating the complexes with ATP and separated from actin by gel filtration if necessary.     

Acanthamoeba cofactor protein is a heavy chain kinase required for actin activation of the Mg2+-ATPase activity of Acanthamoeba myosin I.

We have purified a cofactor protein previously shown (Pollard, T. D., and Korn, E. D. (1973) J. Biol. Chem. 248, 4691-4697) to be required for actin activation of the Mg2+-ATPase activity of Acanthamoeba myosin I. The purified cofactor protein is a novel myosin kinase that phosphorylates the single heavy chain, but neither of the two light chains, of Acanthamoeba myosin I. Phosphorylation of Acanthamoeba myosin I by the purified cofactor protein requires ATP and Mg2+ but is Ca2+-independent. The Mg2+-ATPase activity of phosphorylated Acanthamoeba myosin I is highly activated by F-actin in the absence of cofactor protein. Actin-activated Mg2+-ATPase activity is lost when phosphorylated Acanthamoeba myosin I is dephosphorylated by platelet phosphatase. Phosphorylation and dephosphorylation have no effect on the (K+,EDTA)-ATPase and Ca2+-ATPase activities of Acanthamoeba myosin I. These results show that cofactor protein is an Acanthamoeba myosin I heavy chain kinase and that phosphorylation of the heavy chain of this myosin is required for actin activation of its Mg2+-ATPase activity.     

Purification and some properties of skeletal muscle sarcolemma Ca2+-ATPase]

Ca2+-ATPase of skeletal muscle sarcolemma has been isolated and purified. It is prepared from salt extract of sarcolemma by ammonium sulfate fractionation and further purified by gel chromatography on Sepharose 4B. The purity of preparations was evaluated by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. It has been shown that Ca2+-ATPase possesses the same mobility as skeletal muscle myosin under gel chromatography on Sepharose 4B and the same mobility as myosin heavy chains in sodium dodecyl sulfate--polyacrylamide gel electrophoresis. Membrane protein binds to rabbit skeletal muscle actin, and this complex dissociates by ATP. Interaction with actin does not change Ca2+- or Mg2+-stimulated ATPase activity. Enzyme has only one pH optimum at 7,0-7,6. Membrane protein is highly specified to calcium--ATPase activity in the presence of Mn2+ is 10% and in the presence of Sr2+, Mg2+ or Co2+ are 3-5% of the activity in the presence of Ca2+. Other nucleoside triphosphate (UTP and ITP) are hydrolyzed at lower rates than is ATP.     

Preparation and purification of polymerized actin from sea urchin egg extracts

Isotonic extracts of the soluble cytoplasmic proteins of sea urchin eggs, containing sufficient EGTA to reduce the calcium concentration to low levels, form a dense gel on warming to 35-40 degrees C. Although this procedure is similar to that used to polymerize tubulin from mammalian brain, sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows this gel to have actin as a major component and to contain no tubulin. If such extracts are dialyzed against dilute salt solution, they no longer respond to warming, but gelation will occur if they are supplemented with 1 mM ATP and 0.020 M KCl before heating. Gelation is not temperature reversible, but the gelled material can be dissolved in 0.6-1 M KCl and these solutions contain F- actin filaments. These filaments slowly aggregate to microscopic, birefringent fibrils when 1 mM ATP is added to the solution, and this procedure provides a simple method for preparing purified actin. the supernate remaining after actin removal contains the other two components of the gel, proteins of approximately 58,000 and 220,000 mol wt. These two proteins plus actin recombine to form the original gel material when the ionic strength is reduced. This reaction is reversible at 0 degrees C, and no heating is required.     

Actin and myosin function in acanthamoeba

We have studied the functions of contractile proteins in Acanthamoeba by a combination of structural, biochemical and physiological approaches. We used electron microscopy and image processing to determine the three-dimensional structure of actin and the orientation of the molecule in the actin filament. We measured the rate constants for actin filament elongation and re-evaluated the effect of MgCl2 on the filament nucleation process. In Acanthamoeba actin polymerization is regulated, at least in part, by profilin, which binds to actin monomers, and by capping protein, which both nucleates polymerization and blocks monomer addition at the 'barbed' end of the filament. To test for physiological functions of myosin-II, we produced a monoclonal antibody that inhibits the actin-activated ATPase. When microinjected into living cells, this active-site-specific antibody inhibits amoeboid locomotion. We expect that similar experiments can be used to test for the physiological functions of the other components of the Acanthamoeba contractile system.     

Purification and characterization of an ATP-sensitive actin gelation protein from Acanthamoeba castellanii

A protein which cross-links actin filaments in a nucleotide-sensitive manner has been purified to homogeneity from Acanthamoeba castellanii. This protein, GF-210, is a slightly asymmetric molecule composed of six subunits, each with an apparent mass of 35,000 Da. As determined by the method of falling ball vicometry, GF-210 was shown to cross-link actin filaments at hexamer:actin molar ratios of 1:500, with gelation occurring at molar ratios of 1:300 and higher. Actin gels did not form in the presence of 10 microM ATP, and filament cross-linking was completely inhibited by 100 microM ATP. Although ATP was the most effective inhibitor of actin filament cross-linking, other phospho-compounds including ADP, GTP, sodium phosphate, and sodium pyrophosphate prevented gelation at concentrations lower than 1.5 mM. In contrast, 50 mM KCl was required to inhibit the formation of actin networks. Direct binding studies showed that GF-210 binds to F-actin with a KD of 1.2 microM in the absence of ATP but with a KD of 72.8 microM in the presence of 2 mM ATP. This weakening of the interaction between F-actin and GF-210 may explain the inhibition of GF-210-induced actin cross-linking by nucleotides and other phospho-compounds.     

The effects of insulin,cycloheximide and phalloidin on the content of actin and p35 in extracts prepared from the nuclear fraction of Krebs II ascites cells

The nuclear fraction isolated from Krebs II ascites cells following cell disruption by nitrogen cavitation was separated into four fractions by salt/detergent extraction: NP-40 soluble fraction, 130 mM KCl extract, DOC/Triton × 100 soluble fraction and salt/detergent treated nuclei. The protein composition of the individual fractions was studied by SDS-PAGE and the relative amounts of actin and a 35 kDa protein (p35) were measured from gel scans. There was a time-dependent shift of actin from the 130 mM KCl extract to the NP-40 soluble fraction upon storage of the nuclear fraction on ice, indicating a progressive depolymerization of microfilaments. Compared with actin there was a slower release of p35 into the NP-40 soluble fraction. The results suggest that p35 is not integrated in the microfilament network. Phalloidin, which stabilizes the microfilaments, enriched the amount of both proteins in the 130 mM KCl extracts, together with a series of other proteins in the range 50–205 kDa. The presence of phalloidin also resulted in a large increase in the actin content in both the DOC/Triton × 100 extract and the fraction containing salt/detergent treated nuclei. Incubation of cells with insulin and/or cycloheximide enriched the amount of actin in the 130 mM KCl fraction. The results show that short term incubation of cells with phalloidin, insulin or cycloheximide increases the actin content of the nuclear fraction and also affects the presence of several other proteins.     

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 Acanthamoeba actin. Kinetics, thermodynamics, and co-polymerization with muscle actin.

The kinetics and thermodynamics for the polymerization of purified Acanthamoeba actin were studied and compared to muscle actin. Polymerization was qualitatively similar for the two actins with a rate-limiting nucleation step followed by rapid polymer extension. Polymerization occurred only above a threshold critical concentration which varied with polymerization conditions for each actin. In the presence of 2 mM MgCl2, nucleation of both actins was rapid and their critical concentrations were similarly low and not detectably dependent on temperature. In 0.1 M KCl, the rates of nucleation of both actins were much slower than when Mg2+ was present and were significantly different from each other. Also, under these conditions, the critical concentrations of Acanthamoeba and muscle actin were significantly different and both varied markedly with temperature. These quantitative differences between the two actins could be attributed to differences in both their enthalpies and entropies of polymerization, Acanthamoeba actin having the more positive deltaH and delta S. Co-polymerization of the two actins was also demonstrated. Overall, however, there were no qualitative differences between Acanthamoeba and muscle actin that would suggest a unique role for the monomer-polymer equilibrium of cytoplasmic actin in cell motility.     

Isolation and partial characterization of a 110-kD dimer actin-binding protein

Two Triton-insoluble fractions were isolated from Acanthamoeba castellanii. The major non-membrane proteins in both fractions were actin (30-40%), myosin II (4-9%), myosin I (1-5%), and a 55-kD polypeptide (10%). The 55-kD polypeptide did not react with antibodies against tubulins from turkey brain, paramecium, or yeast. All of these proteins were much more concentrated in the Triton-insoluble fractions than in the whole homogenate or soluble supernatant. The 55-kD polypeptide was extracted with 0.3 M NaCl, fractionated by ammonium sulfate, and purified to near homogeneity by DEAE-cellulose and hydroxyapatite chromatography. The purified protein had a molecular mass of 110 kD and appeared to be a homodimer by isoelectric focusing. The 110-kD dimer bound to F-actin with a maximal binding stoichiometry of 0.5 mol/mol of actin (1 mol of 55-kD subunit/mol of actin). Although the 110-kD protein enhanced the sedimentation of F-actin, it did not affect the low shear viscosity of F-actin solutions nor was bundling of F-actin observed by electron microscopy. The 110-kD dimer protein inhibited the actin-activated Mg2+-ATPase activities of Acanthamoeba myosin I and myosin II in a concentration-dependent manner. By indirect immunofluorescence, the 110-kD protein was found to be localized in the peripheral cytoplasm near the plasma membrane which is also enriched in F-actin filaments and myosin I.     

Characterization of alpha-actinin from Acanthamoeba

Characterization of a protein from Acanthamoeba that was originally called gelation protein [T.D. Pollard, J. Biol. Chem. 256:7666-7670, 1981] has shown that it resembles the actin filament cross-linking protein, alpha-actinin, found in other cells. It comprises about 1.5% of the total amoeba protein and can be purified by chromatography with a yield of 13%. The native protein has a molecular weight of 180,000 and consists of two polypeptides of 90,000 Da. The Stokes' radius is 8.5 nm, the intrinsic viscosity is 0.35 dl/dm, and the extinction coefficient at 280 mm is 1.8 X 10(5)M-1 X cm-1. Electron micrographs of shadowed specimens show that the molecule is a rod 48 nm long and 7 nm wide with globular domains at both ends and in the middle of the shaft. On gel electrophoresis in sodium dodecylsulfate the pure protein can run as bands with apparent molecular weights of 60,000, 90,000, 95,000, or 134,000 depending on the method of sample preparation. Rabbit antibodies to electrophoretically purified Acanthamoeba alpha-actinin polypeptides react with all of these electrophoretic variants in samples of purified protein and cell extracts. By indirect fluorescent antibody staining of fixed amoebas, alpha-actinin is distributed throughout the cytoplasmic matrix and concentrated in the hyaline cytoplasm of the cortex. The protein cross-links actin filaments in the presence and absence of Ca++. It inhibits slightly the time course of the spontaneous polymerization of actin monomers but has no effect on the critical concentration for actin polymerization even though it increases the apparent rate of elongation to a small extent. Like some other cross-linking proteins, amoeba alpha-actinin inhibits the actin-activated ATPase of muscle myosin subfragment-1. Although Acanthamoeba alpha-actinin resembles the alpha-actinin from other cells in shape and ability to cross-link actin filaments, antibodies to amoeba and smooth muscle alpha-actinins do not cross react and there are substantial differences in the amino acid compositions and molecular dimensions.     

Human Brain Lectin: A Soluble Lectin That Binds Actin

A biotinylated probe was used for detection of endogenous ligands of a human brain lectin on blotted human brain soluble proteins. Of the various proteins from brain extract resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, five reacted with the biotinylated probe. After elimination of saccharidic moieties by periodic treatment of the same extract, a single band with Mr approximately 43,000 was recognized by the lectin. This band was identified as actin using an anti-actin antibody. These results were confirmed by binding of biotinylated lectin to purified actin.     

Interactions of actin, myosin, and a new actin-binding protein of rabbit pulmonary macrophages. II. Role in cytoplasmic movement and phagocytosis

Actin and myosin of rabbit pulmonary macrophages are influenced by two other proteins. A protein cofactor is required for the actin activation of macrophage myosin Mg2 ATPase activity, and a high molecular weight actin-binding protein aggregates actin filaments (Stossel T.P., and J.H. Hartwig. 1975. J. Biol. Chem. 250:5706-5711)9 When warmed in 0.34 M sucrose solution containing Mg2-ATP and dithiothreitol, these four proteins interact cooperatively. Acin-binding protein in the presence of actin causes the actin to form a gel, which liquifies when cooled. The myosin contracts the gel into an aggregate, and the rate of aggregation is accelerated by the cofactor. Therefore, we believe that these four proteins also effec the temperature-dependent gelation and aggregation of crude sucrose extracts pulmonary macrophages containing Mg2-ATP and dithiothreitol. The gelled extracts are composed of tangled filaments. Relative to homogenates of resting macrophages, the distribution of actin-binding protein in homogenates of phagocytizing macrophages is altered such that 2-6 times more actin-binding protein is soluble. Sucrose extracts of phagocytizing macrophages gel more rapidly than extracts of resting macrophages. Phagocytosis by pulmonary macrophages involves the formation of peripheral pseudopods containing filaments. The findings suggest that the actin-binding protein initiates a cooperative interaction of contractile proteins to generate cytoplasmic gelation, and that phagocytosis influences the behavior of the actin-binding protein.     

Experimental evidence for the contractile activities of Acanthamoeba myosins IA and IB

The low-shear viscosity of 5-30 microM F-actin was greatly increased by the addition of 0.1-0.5 microM unphosphorylated Acanthamoeba myosins IA and IB. The increase in viscosity was about the same in 2 mM ADP as in the absence of free nucleotide but was much less in 2 mM ATP. The single-headed monomolecular Acanthamoeba myosins were as effective as an equal molar concentration of two-headed muscle heavy meromyosin and much more effective than single-headed muscle myosin subfragment-1. These results suggest that Acanthamoeba myosins IA and IB can cross-link actin filaments as proposed in the accompanying paper (Albanesi, J. P., Fujisaki, H., and Korn, E. D. (1985) J. Biol. Chem. 260, 11174-11179) to explain the actin-dependent cooperative increase in actin-activated Mg2+-ATPase activity as a function of the concentration of myosin I. Superprecipitation occurred when phosphorylated myosin IA or IB was mixed with F-actin. In addition to myosin I heavy chain phosphorylation, superprecipitation required Mg2+ and ATP. ATP hydrolysis was linear during the time course of the superprecipitation, and inhibitors of ATP hydrolysis inhibited superprecipitation. A small, dense contracted gel was formed when the reaction was carried out in a cuvette, and a birefringent actomyosin thread resulted from superprecipitation in a microcapillary. The rate and extent of superprecipitation depended on the actin and myosin I concentrations with maximum superprecipitation occurring at an actin:myosin ratio of 7:1. These results provide strong evidence for the ability of Acanthamoeba myosins IA and IB to perform contractile and motile functions.     

Actin and actin-associated proteins of rabbit liver cell

Rabbit liver actin and its associated proteins were prepared and their properties were studied. Liver cells were isolated from excised rabbit liver after perfusion in situ with calcium-free Lock's solution. Dried powder of acetone-treated liver cells was extracted with a buffer previously used to extract actin from skeletal muscle. The liver actin was recovered by adding skeletal myosin to trap actin as actomyosin and the resulting complex was purified by centrifugation. The actin was then dissociated from myosin by adding MgATP and was purified by centrifugation. This fraction showed the characteristic properties of F-actin and was composed of 42K, 53K, and 61K proteins. Further fractionation of these proteins into three components was carried out by centrifugation, DNase-1 affinity chromatography, and preparative gel electrophoresis. The 42K protein proved to be actin since it activated the myosin Mg2+-ATPase activity, interacted with DNase-1, and had a very similar amino acid composition to skeletal muscle actin. In these experiments, binding affinity among these proteins was apparent. Analysis of subcellular fractions combined with the above results indicated that the liver cell 53K and 61K proteins were not soluble fraction components in the cytosol. The physicochemical properties of 53K and 61K proteins were compared with those of gizzard desmin, a typical intermediate filament protein.     

Characterization of cytoplasmic actin isolated from Acanthamoeba castellanii by a new method.

Cytoplasmic actin has been isolated from Acanthamoeba castellanii by a new method, employing chromatography on DEAE-cellulose, that improves the yield by more than 20-fold over the previously reported method. This procedure should be particularly useful for isolating actin from cells in which it is present in relatively low concentration because the method does not depend initially on the polymerization of actin or its interaction with myosin. Systematic comparison of the properties of purified Acanthamoeba actin and rabbit skeletal muscle actin shows them to be similar in many ways: viscosity of F-actin, stoichiometry of bound nucleotide, stoichiometry of binding of muscle heavy meromyosin and myosin subfragment 1 in the absence of ATP, and ability to inhibit the KATPase activity of heavy meromyosin. The amino acid compositions of Acanthamoeba and muscle actin are also quite similar, but significant differences, especially the presence of epsilon-N-methyllysines in Acanthamoeba actin, have been confirmed. In addition to this structural difference, we find that Acanthamoeba actin is only one-third as effective as muscle actin as an activator of the MgATPase of muscle heavy meromyosin and subfragment 1. For Acanthamoeba actin, as for muscle actin, this activation exhibits hyperbolic dependence on actin concentration; i.e. the double reciprocal plot of ATPase activation versus actin concentration is linear. From these plots we find that the two actins give the same extrapolated ATPase activity at infinite actin concentration (Vmax) but differ by a factor of three in the concentration of actin needed to produce half-maximal activation (Kapp).