Inhibition of recA protein promoted ATP hydrolysis. 1. ATP gamma S and ADP are antagonistic inhibitors

ADP and adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S) inhibit recA protein promoted ATP hydrolysis by fundamentally different mechanisms. In both cases, at least two modes of inhibition are observed. For ADP, the first mode is competitive inhibition. The second mode is manifested by dissociation of recA protein from DNA. These are readily distinguished in a comparison of ATP hydrolyses that are activated by (a) DNA and (b) high (approximately 2 M) salt concentrations. Competitive inhibition with a significant degree of cooperativity is observed under both sets of conditions, although the DNA-dependent activity is more sensitive to ADP than the high-salt reaction. The reaction in the presence of poly(deoxythymidylic acid) or duplex DNA ceases when about 60% of the available ATP is hydrolyzed, reflecting an ADP-mediated dissociation of recA protein from the DNA that is governed by the ADP/ATP ratio. In contrast, ATP hydrolysis proceeds nearly to completion at high salt concentrations. At high concentrations of ATP and ATP gamma S, ATP gamma S also acts as a competitive inhibitor. At low concentrations of ATP gamma S and ATP, however, ATP gamma S activates ATP hydrolysis. These patterns are observed for recA-mediated ATP hydrolysis with either high salt concentrations or a poly(deoxythymidylic acid) [poly(dT)] cofactor, although the activation is observed at much lower ATP and ATP gamma S concentrations when poly(dT) is used. ATP gamma S can also relieve the inhibitory effect of ADP under some conditions. ATP gamma S and ADP are antagonistic inhibitors, reinforcing the idea that they stabilize different conformations of the protein and suggesting that these conformations are mutually exclusive. The ATP gamma S (ATP) conformation is active in ATP hydrolysis. The ADP conformation is inactive.     

ADP-mediated dissociation of stable complexes of recA protein and single-stranded DNA

The complete exchange of strands between circular single-stranded and full length linear duplex DNAs promoted by the recA protein of Escherichia coli is dependent upon the hydrolysis of ATP and is strongly stimulated by the single-stranded DNA binding protein (SSB). In the presence of SSB, stable complexes of recA protein and single-stranded DNA are formed as an early step in the reaction. These complexes dissociate when the ADP/ATP ratio approaches a value of 0.6-1.5, depending upon reaction conditions. Thus, ATP hydrolysis never proceeds to completion but stops when 40-60% of the input ATP has undergone hydrolysis. recA protein can participate in a second round of strand exchange upon regeneration of the ATP. While 100-200 mol of ATP are hydrolyzed/mol of heteroduplex base pair formed under standard reaction conditions in the presence of SSB, this value is reduced to 16 at levels of ADP lower than that required to dissociate the complexes. ATP hydrolysis appears to be completely irreversible since efforts to detect exchange reactions using 18O probes have been unsuccessful.     

recA protein-promoted ATP hydrolysis occurs throughout recA nucleoprotein filaments

When recA protein binds cooperatively to single-stranded DNA to form filamentous nucleoprotein complexes, it becomes competent to hydrolyze ATP. No correlation exists between the ends of such complexes and the rate of ATP hydrolysis. ATP hydrolysis is not, therefore, restricted to the terminal subunits on cooperatively bound recA oligomers, but occurs throughout the complex. Similarly, during recA protein-promoted branch migration (during DNA strand exchange), ATP hydrolysis is not restricted to recA protein monomers at the branch point. DNA cofactors of lengths varying from 16 bases to over 12,000 bases support ATP hydrolysis. The maximum value of kcat at infinite DNA concentration is about 29/min independent of the length of the DNA cofactor. The apparent dissociation constant, however, is a strong function of DNA length, providing evidence for a minimum site size of 30-50 bases for efficient binding of recA protein.     

Exchange of recA protein between adjacent recA protein-single-stranded DNA complexes

We have examined the exchange of recA protein between stable complexes formed with single-stranded DNA (ssDNA) and (a) other complexes and (b) a pool of free recA protein. We have also examined the relationship of ATP hydrolysis to these exchange reactions. Exchange was observed between two different recA X ssDNA complexes in the presence of ATP. Complete equilibration between two sets of complexes occurred with a t1/2 of 3-7 min under a set of conditions previously found to be optimal for recA protein-promoted DNA strand exchange. Approximately 200 ATPs were hydrolyzed for every detected migration of a recA monomer from one complex to another. This exchange occurred primarily between adjacent complexes, however. Little or no exchange was observed between recA X ssDNA complexes and the free recA protein pool, even after several hundred molecules of ATP had been hydrolyzed for every recA monomer present. ATP hydrolysis is not coupled to complete dissociation or association of recA protein from or with recA X ssDNA complexes under these conditions.     

Rapid propagational interactions of slow binding inhibitor with RecA protein occur on the longer nucleoprotein filaments

RecA protein is a DNA-dependent ATPase. RecA protein-mediated ATP hydrolysis occurs throughout the filamentous nucleoprotein complexes of RecA and DNA. Nucleotide analog ATP[γS] may not act simply as a competitive inhibitor, leading to inhibition kinetic patterns that are informative. When a mixture of ATP and ATP[γS] is present at the beginning of reaction, a transient phase lasting several minutes is observed in which the system approaches the state characteristic of the new ATP/ATP[γS] ratio. This phase consists of a burst or lag in ATP hydrolysis, depending on whether ATP or ATP[γS] respectively, is added first. The transition phase reflects a slow conformational change in a RecA monomer or a general adjustment in the structure of RecA filaments. The RecA filaments formed on longer DNA cofactor were more sensitive, and respond more rapidly to ATP[γS] than on shorter DNA cofactors.     

Inhibition of ATPase activity of the recA protein by ATP ribose-modified analogs

The single-stranded, DNA-dependent ATPase activity of purified recA protein was found to be inhibited competitively by ribose-modified analogs of ATP, 3'-O-anthraniloyl-ATP (Ant-ATP), and 3'-O-(N-methylanthraniloyl)-ATP (Mant-ATP). The Ki values for Ant-ATP and Mant-ATP were around 7 and 3 microM at pH 7.5, respectively. The inhibitions by these analogs were much stronger than that by ADP, which is also a competitive inhibitor for the ATPase activity of the recA protein. The Ki value for ADP is 76 microM. Ant-ATP and Mant-ATP reduced the Hill coefficient for ATP hydrolysis and thus contributed to the cooperative effect of ATP.     

Transfer of recA protein from one polynucleotide to another. Effect of ATP and determination of the processivity of ATP hydrolysis during transfer

The transfer of recA protein from a fluorescently modified single-stranded DNA, containing 1,N6-ethenoadenosine and 3,N4-ethenocytosine, to polydeoxythymidylic acid (poly(dT)) was shown to occur by a complex mechanism in both the absence and presence of ADP (Menetski, J. P., and Kowalczykowski, S. C. (1987) J. Biol. Chem. 262, 2085-2092). A part of the mechanism involves the formation of a kinetic ternary intermediate. Since the binding and hydrolysis of ATP by recA protein is involved in many of the recA protein in vitro activities, we have analyzed the effect of ATP on the transfer reaction. In the presence of ATP, the transfer reaction is dependent on the concentration of the competitor single-stranded DNA, poly(dT). This result suggests that transfer does not occur by a simple dissociation mechanism. The reaction occurs via two kinetically distinct species of protein X DNA complexes with properties that are similar to those characterized for the transfer reaction in the absence of ATP. There is a complicated effect of nucleotide concentration on the rate of transfer. At low concentrations of ATP (less than 50 microM), increasing nucleotide concentration increases the rate of transfer; this is similar to the effect of ADP. However, at high concentrations of ATP (greater than 50 microM), increasing ATP concentration decreases the rate of transfer. Finally, the processivity of ATP hydrolysis during transfer was found to increase with increases in ATP concentration. Less than one ATP molecule was hydrolyzed per transfer event at low ATP concentrations (less than 20 microM) while greater than 50 molecules were hydrolyzed at high ATP concentration (greater than 250 microM). These data suggest that the rate of transfer is not directly coupled to the rate of hydrolysis.     

Properties of the high-affinity single-stranded DNA binding state of the Escherichia coli recA protein

The properties of the high-affinity single-stranded DNA (ssDNA) binding state of Escherichia coli recA protein have been studied. We find that all of the nucleoside triphosphates that are hydrolyzed by recA protein induce a high-affinity ssDNA binding state. The effect of ATP binding to recA protein was partially separated from the ATP hydrolytic event by substituting calcium chloride for magnesium chloride in the binding buffer. Under these conditions, the rate of ATP hydrolysis is greatly inhibited. ATP increases the affinity of recA protein for ssDNA in a concentration-dependent manner in the presence of both calcium and magnesium chloride with apparent Kd values of 375 and 500 microM ATP, respectively. Under nonhydrolytic conditions, the molar ratio of ATP to ADP has an effect on the recA protein ssDNA binding affinity. Over an ATP/ADP molar ratio of 2-3, the affinity of recA protein for ssDNA shifts cooperatively from a low-to a high-affinity state.     

The formation of plectonemic joints by the recA protein of Escherichia coli. Requirement for ATP hydrolysis

Formation of D-loops during the exchange of strands between a circular single-stranded DNA and a completely homologous linear duplex proceeds optimally when the duplex DNA is added to the complex of recA protein and single-stranded DNA formed in the presence of single-stranded DNA-binding protein and ATP. D-loops are undetectable when 200 microM adenosine 5'-O-(thiotriphosphate) is substituted for ATP. D-loops can be formed in the presence of adenosine 5'-O-(thiotriphosphate) if recA protein is the last component added to the reaction. However, these D-loops, which depend upon homologous sequences, are unstable upon deproteinization and are formed to a more limited extent than the structures formed with ATP. This finding indicates that D-loops formed under these conditions may be largely nonintertwined paranemic structures rather than plectonemic structures in which two of the strands are interwoven. When adenosine 5'-O-(thiotriphosphate) is added to an ongoing reaction containing ATP, formation of plectonemic structures and ATP hydrolysis is inhibited to an equivalent extent. We, therefore, conclude that ATP hydrolysis is required for the formation of plectonemic structures.     

Stable binding of recA protein to duplex DNA. Unraveling a paradox

recA protein binding to duplex DNA is a complicated, multistep process. The final product of this process is a stably bound complex of recA protein and extensively unwound double-stranded DNA. recA monomers within the complex hydrolyze ATP with an apparent kcat of approximately 19-22 min-1. Once the final binding state is achieved, binding and ATP hydrolysis by this complex becomes pH independent. The weak binding of recA protein to duplex DNA reported in previous studies does not, therefore, reflect an intrinsically unfavorable binding equilibrium. Instead, this apparent weak binding reflects a slow step in the association pathway. The rate-limiting step in this process involves the initiation rather than the propagation of DNA binding and unwinding. This step exhibits no dependence on recA protein concentration at pH 7.5. Extension or propagation of the recA filament is fast relative to the overall process. Initiation of binding is pH dependent and represents a prominent kinetic barrier at pH 7.5. ATP hydrolysis occurs only after the duplex DNA is unwound. The binding density of recA protein on double-stranded DNA is approximately one monomer/4 base pairs. A model for this process is presented. These results provide an explanation for several paradoxical observations about recA protein-promoted DNA strand exchange. In particular, they demonstrate that there is no thermodynamic requirement for dissociation of recA protein from the heteroduplex DNA product of strand exchange.     

ATP activates dnaA protein in initiating replication of plasmids bearing the origin of the E. coli chromosome

ATP is bound to dnaA protein with high affinity (KD = 0.03 microM) and hydrolyzed slowly to ADP in the presence of DNA. ADP is also bound tightly to dnaA protein and exchanges with ATP very slowly. The ATP form is active in replication; the ADP form is not. A unique conformation of oriC, formed in an early initiation stage, depends on dnaA protein being in the ATP form. The subsequent entry of dnaB protein to form a prepriming complex also requires ATP binding and is blocked by bound ADP. Inasmuch as hydrolysis of ATP is far slower than these initiation reactions and since the poorly hydrolyzable analogue ATP gamma S can replace ATP, the ATP function appears to be allosteric. The extraordinary affinity of ATP for dnaA protein, its slow hydrolysis to ADP, the profound inhibition of dnaA functions by ADP, and the very slow exchange of ADP all point to a possible regulatory role for these nucleotides in the cell cycle.     

Covalent modification of the recA protein from Escherichia coli with the photoaffinity label 8-azidoadenosine 5'-triphosphate

We have covalently modified the recA protein from Escherichia coli with the photoaffinity ATP analog 8-azido-[alpha-32P]ATP (N3-ATP). Covalent attachment of N3-ATP to recA protein is dependent on native protein conformation and is shown to be specific for the site of ATP hydrolysis by the following criteria. (i) Binding of the probe to recA protein is inhibited by ATP and competitive inhibitors of its ATP hydrolytic activity, e.g. adenosine 5'-O-(thiotriphosphate), ADP, and UTP, but not by adenosine; (ii) N3-ATP is efficiently hydrolyzed by recA protein in the presence of single-stranded DNA; (iii) labeling of recA protein occurs at a single site as judged by two-dimensional thin-layer peptide mapping and high-performance liquid chromatography peptide separation. We have purified and identified a tryptic fragment, spanning amino acid residues 257-280, which contains the primary site of attachment of N3-ATP. This peptide is likely to be contained within the ATP hydrolytic site of recA protein.     

Properties of ATP tightly bound to catalytic sites of chloroplast ATP synthase

Under steady state photophosphorylating conditions, each ATP synthase complex from spinach thylakoids contains, at a catalytic site, about one tightly bound ATP molecule that is rapidly labeled from medium 32Pi. The level of this bound [32P]ATP is markedly reduced upon de-energization of the spinach thylakoids. The reduction is biphasic, a rapid phase in which the [32P] ATP/synthase complex drops about 2-fold within 10 s, followed by a slow phase, kobs = 0.01/min. A decrease in the concentration of medium 32Pi to well below its apparent Km for photophosphorylation is required to decrease the amount of tightly bound ATP/synthase found just after de-energization and before the rapid phase of bound ATP disappearance. The [32P]ATP that remains bound after the rapid phase appears to be mostly at a catalytic site as demonstrated by a continued exchange of the oxygens of the bound ATP with water oxygens. This bound [32P]ATP does not exchange with medium Pi and is not removed by the presence of unlabeled ATP. The levels of tightly bound ADP and ATP arising from medium ADP were measured by a novel method based on use of [beta-32P]ADP. After photophosphorylation and within minutes after the rapid phase of bound ATP loss, the measured ratio of bound ADP to ATP was about 1.4 and the sum of bound ADP plus ATP was about 1/synthase. This ratio is smaller than that found about 1 h after de-energization. Hence, while ATP bound at catalytic sites disappears, bound ADP appears. The results suggest that during and after de-energization the bound ATP disappears from the catalytic site by hydrolysis to bound ADP and Pi with subsequent preferential release of Pi. These and related observations can be accommodated by the binding change mechanism for ATP synthase with participation of alternating catalytic sites and are consistent with a deactivated state arising from occupancy of one catalytic site on the synthase complex by an inhibitory ADP without presence of Pi.     

Interaction of recA protein with single-stranded DNA. Quantitative aspects of binding affinity modulation by nucleotide cofactors

We have investigated quantitative molecular aspects of the interaction of recA protein with single-stranded DNA, by using a fluorescent modified-DNA referred to as etheno-M13 DNA. In addition, the effects of the nucleotide cofactors ATP and ADP, and the analogues ATP-gamma-S, AMP-P-C-P, and AMP-P-N-P on this interaction have been studied. It is shown that ATP, AMP-P-N-P and, in particular, ATP-gamma-S significantly increase the affinity of recA protein for single-stranded DNA, whereas ADP and, to a lesser degree, AMP-P-C-P decrease the affinity. Binding to etheno-M13 single-stranded DNA is co-operative, with the value of the co-operativity parameter, omega, being approximately 50 under all conditions measured. The effect that ADP has on recA protein-DNA affinity is to lower the intrinsic binding constant, but it has no effect on the co-operativity of binding. In addition, the stability of the recA protein-DNA complex is very salt dependent (d log K/d log [NaC1] approximately -10) and it is the intrinsic binding affinity rather than the co-operativity of binding that is affected; thus, under all conditions observed, recA protein binds single-stranded DNA co-operatively with a value of omega = 50 +/- 10. The binding affinity is also influenced by the type of anion present, being approximately 10,000-fold higher when acetate ion is present instead of chloride ion. These data have been interpreted to suggest that recA protein forms up to five ionic interactions when it binds to single-stranded DNA and that five to six anions are displaced upon binding. The modulation of recA protein-DNA complex stability by nucleotide cofactors suggests that these cofactors play a role in the cycling of recA protein on and off single-stranded DNA, with ATP being required for DNA binding under physiological conditions and ADP serving as a "release" factor. These results are discussed in terms of a model for the role of ATP hydrolysis in a recA protein-single stranded DNA binding cycle.     

The mechanism of skeletal muscle myosin ATPase. Interaction of myosin active center with ATP and with ADP

The kinetics of the fluorescence enhancement and the transient release of H+ caused by the binding of ADP to the active center of myosin has been compared to that caused by myosin-ATP interaction. The results show that both the time courses of the fluorescence enhancement and the transient H+ release caused by ADP binding, like that caused by ATP hydrolysis in the initial burst, are monophasic exponential processes. The fact that the rates of these two processes are also equal suggests that they both reflect the same mechanistic event in the mechanism of ADP binding. The kinetics of ADP binding as measured by the fluorescence enhancement and the H+ release is different from that of ATP. This is in agreement with our previous finding that the enhancement of fluorescence and the transient release of H+, in the case of ATP, reflect the initial burst of ATP hydrolysis, whereas in the case of ADP, they represent a conformational change in the myosin-ADP complex. The magnitude of the H+ transient caused by the initial burst is approximately equal to that caused by ADP binding. The amplitude of the fluorescence enhancement caused by ADP binding is equal to one-third of that caused by the initial burst.     

Phosphoenzymes formed from Mg.ATP and Ca.ATP during pre-steady state kinetics of sarcoplasmic reticulum ATPase

We have investigated here the pre-steady state kinetics of sarcoplasmic reticulum ATPase incubated under conditions where significant amounts of Mg.ATP and Ca.ATP coexist, both of them being substrates for the ATPase. We confirmed that these two substrates are independently hydrolyzed by the ATPase, which thus apparently catalyzes Pi production by two simultaneous and separate pathways. External calcium (or the Ca2+/Mg2+ ratio) determines the extent to which Ca2+ or Mg2+ is bound at the phosphorylation site, while internal calcium controls the rate of processing of both the slow, calcium-containing and the fast, magnesium-containing phosphoenzyme. Time-dependent binding of calcium at the catalytic site is correlated with the observed burst of Pi liberation, which therefore results from reequilibration during pre-steady state of magnesium- and calcium-containing phosphoenzyme pools. Independently of direct exchange of metal at the catalytic site, ADP produced by the hydrolysis reaction contributes to reequilibration of these pools through reversal of phosphorylation by the ATP-ADP exchange pathway.     

D-loop cycle. A circular reaction sequence which comprises formation and dissociation of D-loops and inactivation and reactivation of superhelical closed circular DNA promoted by recA protein of Escherichia coli

Excess recA protein, a protein essential to general genetic recombination in Escherichia coli, promotes a sequence of formation and dissociation of D-loops from negative superhelical closed circular double-stranded DNA (form I DNA) and homologous single-stranded fragments in the presence of excess ATP, resulting in inactivation of the form I DNA without apparent damage to the DNA. The dissociation of D-loops is accompanied by hydrolysis of ATP to ADP that apparently depends on homologous DNA molecules (homology-dependent ATP hydrolysis). However, at a lower concentrations of ATP, we observed anomalous kinetics in the formation and dissociation of D-loops; as the concentration of ATP was decreased, there was a progressively smaller dissociation of D-loops and a faster resynthesis in the second phase, without changing the rate of the first formation of D-loops. This anomaly might suggest that, as the increase in the amount of ADP relative to that of ATP, dissociation form I DNA is stimulated before formation of D-loops is inhibited. We found that addition of ADP inhibited competitively both formation and dissociation of D-loops and that the latter process was more sensitive to the inhibition than was the former process. Addition of a sufficient amount of ADP to inhibit both formation and dissociation of D-loops, cessation of homology-dependent hydrolysis of ATP, or incubation at low temperature resulted in reactivation of form I DNA that had been inactivated by the sequence. In the presence of an ATP-regenerating system, we confirmed our previous result that limiting the amount of recA protein also causes anomalous kinetics in the formation and dissociation of D-loops. These observations indicate that the formation and dissociation of D-loops and the inactivation and reactivation of form I DNA make a circular reaction sequence.     

Resolution of conformational states of spin-labeled myosin during steady-state ATP hydrolysis

We have measured the conventional electron paramagnetic resonance (EPR) spectrum of spin-labeled myosin filaments as a function of the nucleotide occupancy of the active site of the enzyme. The probe used was 4-(2-iodoacetamido)-2,2,6,6-tetramethylpiperidine-1-oxyl (IASL), which reacts specifically with sulfhydryl 1 of the myosin head. In the absence of nucleotide, the probe remains strongly immobilized (rigidly attached to the myosin head) so that no nanosecond rotational motions are detectable. When MgADP is added to IASL-labeled myosin filaments (T = 20 degrees C), the probe mobility increases slightly. During steady-state MgADP hydrolysis (T = 20 degrees C), the probe undergoes large-amplitude nanosecond rotational motion. These results are consistent with previous studies of myosin monomers, heavy meromyosin, and myosin subfragment 1. Isoclinic points observed in overlays of sequential EPR spectra recorded during ATP hydrolysis strongly suggest that the probes fall into two motional classes, separated by approximately an order of magnitude in effective rotational correlation time. Both of the observed states are distinct from the conformation of myosin in the absence of nucleotides, and the spectrum of the less mobile population is indistinguishable from that observed in the presence of MgADP. The addition of ADP and vanadate to IASL-myosin gives rise to two motional classes virtually identical with those observed in the presence of ATP, but the relative concentrations of the spin populations are significantly different. We have quantitated the percentage of myosin in each motional state during ATP hydrolysis. The result agrees well with the predicted percentages in the two predominant chemical states in the myosin ATPase cycle. Spectra obtained in the presence of nucleotide analogues permit us to assign the conformational states to specific chemical states. We propose that the two motional classes represent two distinct local conformations of myosin that are in exchange with one another during the ATP hydrolysis reaction cycle.     

Dissociation pathway for recA nucleoprotein filaments formed on linear duplex DNA

recA protein forms stable filaments on duplex DNA at low pH. When the pH is shifted above 6.8, recA protein remains stably bound to nicked circular DNA, but not to linear DNA. Dissociation of recA protein from linear duplex DNA proceeds to a non-zero endpoint. The kinetics and final extent of dissociation vary with several experimental parameters. The instability on linear DNA is most readily explained by a progressive unidirectional dissociation of recA protein from one end of the filament. Dissociation of recA protein from random points in the filament is eliminated as a possible mechanism by several observations: (1) the requirement for a free end; (2) the inverse and linear dependence of the rate of dissociation on DNA length (at constant DNA base-pair concentration); and (3) the kinetics of exposure of a restriction endonuclease site in the middle of the DNA. Evidence against another possible mechanism, ATP-mediated translocation of the filament along the DNA, is provided by a novel effect of the non-hydrolyzable ATP analog, ATP gamma S, which generally induces recA protein to bind any DNA tightly and completely inhibits ATP hydrolysis. We find that very low, sub-saturating levels of ATP gamma S completely stabilize the filament, while most of the ATP hydrolysis continues. If these levels of ATP gamma S are introduced after dissociation has commenced, further dissociation is blocked, but re-association does not occur. These observations are inconsistent with movement of recA protein along DNA that is tightly coupled to ATP hydrolysis. The recA nucleoprotein filament is polar and the protein binds the two strands asymmetrically, polymerizing mainly in the 5' to 3' direction on the initiating strand of a single-stranded DNA tailed duplex molecule. A model consistent with these results is presented.     

Actin polymerization and ATP hydrolysis

This paper surveys several aspects of the consequences of ATP hydrolysis associated with actin polymerization, and their physiological implications. ATP hydrolysis occurs on F-actin in two subsequent reactions, cleavage of ATP followed by the slower release of P_i. The latter reaction is linked to a conformation change of the actin subunit that causes a destabilization of the actin-actin interactions in the filament, i.e., a structural change of the filament. The nature of the nucleotide bound to terminal subunits therefore affects the dynamics of actin filaments. It is shown that this regulation is different at the two ends, terminal F-ADP-P_i subunits being present at steady state at the barbed end, while F-ADP-subunits are present at the pointed end. While cleavage of ATP on F-actin is irreversible, P_i release is reversible, which allows the regulation of filament dynamics by cellular P_i. The nature of the divalent metal ion — Ca²⁺ or Mg²⁺ — tightly bound to actin, in direct interaction with ATP, also affects the conformation of actin and the rate of ATP hydrolysis, therefore regulating actin dynamics. Finally, the rate of nucleotide exchange on G-actin is relatively slow, which allows the critical concentration to increase with the number of filaments in ATP, a property largely used by the cell via the action of severing proteins.