Henry J. Kinosian scite author profile

Actin is known to undergo reversible monomer-polymer transitions that coincide with various cell activities such as cell shape changes, locomotion, endocytosis and exocytosis. This dynamic state of actin filament self-assembly and disassembly is thought to be regulated by the properties of the monomeric actin molecule and in vivo by the influence of actin-associated proteins. Of major importance to the properties of the monomeric actin molecule are the presence of one tightly-bound ATP and one tightly-bound divalent cation per molecule. In vivo the divalent cation is thought to be Mg2+ (Mg-actin) but in vitro standard purification procedures result in the preparation of Ca-actin. The affinity of actin for a divalent cation at the tight binding site is in the nanomolar range, much higher than earlier thought. The binding kinetics of Mg2+ and Ca2+ at the high affinity site on actin are considered in terms of a simple competitive binding mechanism. This model adequately describes the published observations regarding divalent cation exchange on actin. The effects of the tightly-bound cation, Mg2+ or Ca2+, on nucleotide binding and exchange on actin, actin ATP hydrolysis activity and nucleation and polymerization of actin are discussed. From the characteristics that are reviewed, it is apparent that the nature of the bound divalent cation has a significant effect on the properties of actin.

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Actin Filament Barbed End Elongation with Nonmuscle MgATP−Actin and MgADP−Actin in the Presence of Profilin

Kinosian

Selden

Gershman

et al. 2002

Biochemistry

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We have quantitated the in vitro interactions of profilin and the profilin-actin complex (PA) with the actin filament barbed end using profilin and nonmuscle beta,gamma-actin prepared from bovine spleen. Actin filament barbed end elongation was initiated from spectrin seeds in the presence of varying profilin concentrations and followed by light scattering. We find that profilin inhibits actin polymerization and that this effect is much more pronounced for beta,gamma-actin than for alpha-skeletal muscle actin. Profilin binds to beta,gamma-actin filament barbed ends with an equilibrium constant of 20 microM, decreases the filament elongation rate by blocking addition of actin monomers, and increases the dissociation rate of actin monomers from the filament end. PA containing bound MgADP supports elongation of the actin filament barbed end, indicating that ATP hydrolysis is not necessary for PA elongation of filaments. Initial analysis of the energetics for these reactions suggested an apparent greater negative free energy change for actin filament elongation from PA than elongation from monomeric actin. However, we calculate that the free energy changes for the two elongation pathways are equal if the profilin-induced weakening of nucleotide binding to actin is taken into consideration.

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Ca2+ Regulation of Gelsolin Activity: Binding and Severing of F-actin

Kinosian

Newman

Lincoln

et al. 1998

Biophysical Journal

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Regulation of the F-actin severing activity of gelsolin by Ca2+ has been investigated under physiologic ionic conditions. Tryptophan fluorescence intensity measurements indicate that gelsolin contains at least two Ca2+ binding sites with affinities of 2.5 x 10(7) M-1 and 1.5 x 10(5) M-1. At F-actin and gelsolin concentrations in the range of those found intracellularly, gelsolin is able to bind F-actin with half-maximum binding at 0.14 microM free Ca2+ concentration. Steady-state measurements of gelsolin-induced actin depolymerization suggest that half-maximum depolymerization occurs at approximately 0.4 microM free Ca2+ concentration. Dynamic light scattering measurements of the translational diffusion coefficient for actin filaments and nucleated polymerization assays for number concentration of actin filaments both indicate that severing of F-actin occurs slowly at micromolar free Ca2+ concentrations. The data suggest that binding of Ca2+ to the gelsolin-F-actin complex is the rate-limiting step for F-actin severing by gelsolin; this Ca2+ binding event is a committed step that results in a Ca2+ ion bound at a high-affinity, EGTA-resistant site. The very high affinity of gelsolin for the barbed end of an actin filament drives the binding reaction equilibrium toward completion under conditions where the reaction rate is slow.

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Impact of Profilin on Actin-Bound Nucleotide Exchange and Actin Polymerization Dynamics^,

et al. 1999

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We have investigated the effects of profilin on nucleotide binding to actin and on steady state actin polymerization. The rate constants for the dissociation of ATP and ADP from monomeric Mg-actin at physiological conditions are 0.003 and 0.009 s-1, respectively. Profilin increases these dissociation rate constants to 0.08 s-1 for MgATP-actin and 1.4 s-1 for MgADP-actin. Thus, profilin can increase the rate of exchange of actin-bound ADP for ATP by 140-fold. The affinity of profilin for monomeric actin is found to be similar for MgATP-actin and MgADP-actin. Continuous sonication was used to allow study of solutions having sustained high filament end concentrations. During sonication at steady state, F-actin depolymerizes toward the critical concentration of ADP-actin [Pantaloni, D., et al. (1984)J. Biol. Chem. 259, 6274-6283], our analysis indicates that under these conditions a significant number of filaments contain terminal ADP-actin subunits. Addition of profilin to this system increases the polymer concentration and increases the steady state ATPase activity during sonication. These data are explained by the fast exchange of ATP for ADP on the profilin-ADP-actin complex, resulting in rapid ATP-actin regeneration. An important function of profilin may be to provide the growing ends of filaments with ATP-actin during periods when the monomer cycling rate exceeds the intrinsic nucleotide exchange rate of monomeric actin.

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Interdependence of Profilin, Cation, and Nucleotide Binding to Vertebrate Non-Muscle Actin

Kinosian

Selden²,

Gershman³

et al. 2000

Biochemistry

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The interaction of profilin and non-muscle beta,gamma-actin prepared from bovine spleen has been investigated under physiologic ionic conditions. Profilin binding to actin decreases the affinity of actin for MgADP and MgATP by about 65- and 13-fold, respectively. Kinetic measurements indicate that profilin binding to actin weakens the affinity of actin for nucleotides primarily due to an increased nucleotide dissociation rate constant, but the nucleotide association rate constant is also increased about 2-fold. Removal of the actin-bound nucleotide and divalent cation produces the labile intermediate species in the nucleotide exchange reaction, nucleotide free actin (NF-actin), and increases the affinity of actin for profilin about 10-fold. Profilin binds NF-actin with high affinity, K(D) = 0.013 microM, and slows the observed denaturation rate of NF-actin. Addition of ATP to NF-actin weakens the affinity for profilin and addition of Mg(2+) to ATP-actin further weakens the affinity for profilin. The high-affinity Mg(2+) of actin regulates binding of both nucleotide and profilin to actin and is important for actin interdomain coupling. The data suggest that profilin binding to actin weakens nucleotide binding to actin by disrupting Mg(2+) coordination in the actin central cleft.

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Severing of F-Actin by the Amino-Terminal Half of Gelsolin Suggests Internal Cooperativity in Gelsolin

Selden

Kinosian

Newman

et al. 1998

Biophysical Journal

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Gelsolin is a Ca2+-regulated actin-binding protein that can sever, cap, and nucleate growth from the pointed ends of actin filaments. In this study we have measured the binding of the amino-terminal half of gelsolin, G1-3, to pyrene-labeled F-actin as a function of Ca2+ concentration. The rate of binding is shown to be dependent on micromolar concentrations of Ca2+. Independent experiments demonstrate that conformational changes in G1-3 are induced by micromolar concentrations of Ca2+. Titrations of pyrene-F-actin with G1-3 and gelsolin show that the quenching of pyrene fluorescence is identical in extent and stoichiometry for both G1-3 and gelsolin. In contrast, severing of F-actin by G1-3 is found to be much less efficient than is severing by gelsolin. In experiments in which F-actin severing is quantitatively measured, the filament number is found to be proportional to the 1.35 power of the G1-3 concentration. This deviation from linearity may be explained by cooperativity; the binding of two G1-3 molecules in close proximity may lead to cooperative severing of the polymer, thus increasing the severing efficiency. This model is supported by experiments that show that the efficiency of G1-3 severing of F-actin increases with increasing G1-3:F-actin ratios. Extrapolating from these results, we conclude that G4-6, the carboxyl-terminal half of gelsolin, has an active role in the severing of F-actin by intact gelsolin. Whereas F-actin severing by G1-3 is enhanced by cooperative binding of two separate G1-3 molecules, cooperativity is inherent to intact gelsolin because the cooperative partners are covalently linked.

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Nucleotide binding to actin. Cation dependence of nucleotide dissociation and exchange rates.

Kinosian¹,

Selden²,

Estes³

et al. 1993

Journal of Biological Chemistry

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Actin filament annealing in the presence of ATP and phalloidin

Kinosian¹,

Selden²,

Estes³

et al. 1993

Biochemistry

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The re-formation of actin filaments after fragmentation by sonication in the presence of phalloidin and ATP has been found to follow second-order kinetics. The data are described by a model in which the rate of actin filament annealing is proportional to the square of the number concentration of actin filaments and the rate of fragmentation is proportional to the actin polymer concentration. In the presence of 100 mM KCl, 1 mM MgCl2, and equimolar phalloidin, the second-order rate constant for annealing of actin filaments is 2.2 x 10(6) M-1 s-1 and the first-order rate constant for fragmentation is 7 x 10(-7) s-1. In addition, the observed pseudo-first-order rate constant for annealing was found to increase with increasing ionic strength. Thus, annealing may play a major part in the length redistribution phase of actin polymerization and may be important for actin filament rearrangement in the cell.

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Henry J. Kinosian

Tightly-bound divalent cation of actin

Actin Filament Barbed End Elongation with Nonmuscle MgATP−Actin and MgADP−Actin in the Presence of Profilin

Ca2+ Regulation of Gelsolin Activity: Binding and Severing of F-actin

Impact of Profilin on Actin-Bound Nucleotide Exchange and Actin Polymerization Dynamics^,

Interdependence of Profilin, Cation, and Nucleotide Binding to Vertebrate Non-Muscle Actin

Severing of F-Actin by the Amino-Terminal Half of Gelsolin Suggests Internal Cooperativity in Gelsolin

Nucleotide binding to actin. Cation dependence of nucleotide dissociation and exchange rates.

Actin filament annealing in the presence of ATP and phalloidin

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Henry J. Kinosian

Tightly-bound divalent cation of actin

Actin Filament Barbed End Elongation with Nonmuscle MgATP−Actin and MgADP−Actin in the Presence of Profilin

Ca2+ Regulation of Gelsolin Activity: Binding and Severing of F-actin

Impact of Profilin on Actin-Bound Nucleotide Exchange and Actin Polymerization Dynamics,

Interdependence of Profilin, Cation, and Nucleotide Binding to Vertebrate Non-Muscle Actin

Severing of F-Actin by the Amino-Terminal Half of Gelsolin Suggests Internal Cooperativity in Gelsolin

Nucleotide binding to actin. Cation dependence of nucleotide dissociation and exchange rates.

Actin filament annealing in the presence of ATP and phalloidin

Contact Info

Product

Resources

About

Impact of Profilin on Actin-Bound Nucleotide Exchange and Actin Polymerization Dynamics^,