Divalent cation-, nucleotide-, and polymerization-dependent changes in the conformation of subdomain 2 of actin.

Conformational changes in subdomain 2 of actin were investigated using fluorescence probes dansyl cadaverine (DC) or dansyl ethylenediamine (DED) covalently attached to Gln41. Examination of changes in the fluorescence emission spectra as a function of time during Ca2+/Mg2+ and ATP/ADP exchange at the high-affinity site for divalent cation-nucleotide complex in G-actin confirmed a profound influence of the type of nucleotide but failed to detect a significant cation-dependent difference in the environment of Gln41. No significant difference between Ca- and Mg-actin was also seen in the magnitude of the fluorescence changes resulting from the polymerization of these two actin forms. Evidence is presented that earlier reported cation-dependent differences in the conformation of the loop 38-52 may be related to time-dependent changes in the conformation of subdomain 2 in DED- or DC-labeled G-actin, accelerated by substitution of Mg2+ for Ca2+ in CaATP-G-actin and, in particular, by conversion of MgATP- into MgADP-G-actin. These spontaneous changes are associated with a denaturation-driven release of the bound nucleotide that is promoted by two effects of DED or DC labeling: lowered affinity of actin for nucleotide and acceleration of ATP hydrolysis on MgATP-G-actin that converts it into a less stable MgADP form. Evidence is presented that the changes in the environment of Gln41 accompanying actin polymerization result in part from the release of Pi after the hydrolysis of ATP on the polymer. A similarity of this change to that accompanying replacement of the bound ATP with ADP in G-actin is discussed.     

Differences in G-actin containing bound ATP or ADP: the Mg2+-induced conformational change requires ATP

The role of adenosine 5'-triphosphate (ATP) in the Mg2+-induced conformational change of rabbit skeletal muscle G-actin has been investigated by comparing actin containing bound ADP with actin containing bound ATP. As previously described [Frieden, C. (1982) J. Biol. Chem. 257, 2882-2886], N-acetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine-labeled G-actin containing ATP undergoes a time-dependent Mg2+-induced fluorescence change that reflects a conformational change in the actin. Addition of Mg2+ to labeled G-actin containing ADP gives no fluorescence change, suggesting that the conformational change does not occur. The fluorescence change can be restored on the addition of ATP. Examination of the time courses of these experiments suggests that ATP must replace ADP prior to the Mg2+-induced change. The Mg2+-induced polymerization of actin containing ADP is extraordinarily slow compared to that of actin containing ATP. The lack of the Mg2+-induced conformational change, which is an essential step in the Mg2+-induced polymerization, is probably the cause for the very slow polymerization of actin containing ADP. On the other hand, at 20 degrees C, at pH 8, and in 2 mM Mg2+, the elongation rate from the slow growing end of an actin filament, measured by using the protein brevin to block growth at the fast growing end, is only 4 times slower for actin containing ADP than for actin containing ATP.     

Divalent cation binding to the high- and low-affinity sites on G-actin

Metal binding to skeletal muscle G-actin has been assessed by equilibrium dialysis using 45Ca2+ and by kinetic measurements of the increase in the fluorescence of N-acetyl-N'-(5-sulfo-1-naphthyl)-ethylenediamine-labeled actin. Two classes of cation binding sites were found on G-actin which could be separated on the basis of their Ca2+ affinity: a single high-affinity site with a Kd considerably less than 1 microM and three identical moderate-affinity binding sites with a Kd of 18 microM. The data for the Mg2+-induced fluorescence enhancement of actin labeled with N-acetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine support a previously suggested mechanism [Frieden, C. (1982) J. Biol. Chem. 257, 2882-2886] in which Ca2+ is replaced by Mg2+ at the moderate affinity site(s), followed by a slow actin isomerization. This isomerization occurs independently of Ca2+ release from the high-affinity site. The fluorescence data do not support a mechanism in which this isomerization is directly related to Ca2+ release from the high-affinity site. Fluorescence changes of labeled actin associated with adding metal chelators are complex and do not reflect the same change induced by Mg2+ addition. Fluorescence changes in the labeled actin have also been observed for the addition of Cd2+ or Mn2+ instead of Mg2+. It is proposed actin may undergo a host of subtle conformational changes dependent on the divalent cation bound. We have also developed a method by which progress curves of a given reaction can be analyzed by nonlinear regression fitting of kinetic simulations to experimental reaction time courses.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence for the direct interaction between tightly bound divalent metal ion and ATP on actin. Binding of the lambda isomers of beta gamma-bidentate CrATP to actin

Competition between Ca2+ and Mg2+ for binding to a single high affinity site on actin has been confirmed. Occupancy of this site only by either Ca2+ or Mg2+ affects the conformation of actin and its ability to form nuclei and hydrolyze ATP. G-actin binds the beta gamma-bidentate CrATP, a substitution inert analog of metal-ATP complexes, and shows a high specificity for the lambda isomers. Binding of CrATP to ADP-actin is accompanied by the dissociation of tightly bound ADP and Ca2+. CrATP-actin shows a high tendency to form nuclei, like MgATP-actin. Polymerization of CrATP-actin is accompanied by cleavage of the gamma-phosphate, but subsequent Pi release cannot occur because the product of the reaction is the stable CrADP-Pi complex. All these results support the view that the divalent metal ion tightly bound to actin interacts with the beta- and gamma-phosphates of ATP in the nucleotide site.     

Mechanism for nucleotide exchange in monomeric actin

Rabbit skeletal muscle G-actin has been treated to obtain ADP, 1,N6-ethenoadenosine diphosphate (epsilon-ADP), or 1,N6-ethenoadenosine triphosphate (epsilon-ATP) at the nucleotide binding site and either Mg2+ or Ca2+ at high- and moderate-affinity metal binding sites. Apparent rates or rate constants for the displacement of the actin-bound nucleotides by epsilon-ATP or ATP have been obtained by stopped-flow measurements at pH 8 and 20 degrees C of the fluorescence difference between bound and free epsilon-ATP or epsilon-ADP. In the presence of Ca2+, displacement of ADP by epsilon-ATP or epsilon-ADP by ATP is a biphasic process, but in the presence of low (less than 10 microM) Mg2+ concentrations, it is a slow first-order process. At high levels of Mg2+ (greater than 50 microM), low ADP concentrations displace epsilon-ATP from G-actin as a consequence of Mg2+ binding to moderate-affinity sites on the actin. Displacement of epsilon-ATP by ATP in the presence of either Ca2+ or Mg2+ is slow at low ATP concentrations, but the rate is increased by high ATP concentrations. Using ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid, we find that nucleotide exchange is affected differently by the removal of Ca2+ from the high-affinity site compared to Ca2+ removal from moderate-affinity sites. A mechanism for the displacement reaction is proposed in which there are two forms of an actin-ADP complex and metal binding influences the ratio of these forms as well as the binding of ATP.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effects of Mg2+ at the high-affinity and low-affinity sites on the polymerization of actin and associated ATP hydrolysis

Actin contains a single high-affinity cation-binding site, for which Ca2+ and Mg2+ can compete, and multiple low-affinity cation-binding sites, which can bind Ca2+, Mg2+, or K+. Binding of cations to the low-affinity sites causes polymerization of monomeric actin with either Ca2+ or Mg2+ at the high-affinity site. A rapid conformational change occurs upon binding of cations to the low-affinity sites (G----G) which is apparently associated with the initiation of polymerization. A much slower conformational change (G----G', or G----G' if the low-affinity sites are also occupied) follows the replacement of Ca2+ by Mg2+ at the high-affinity site. This slow conformational change is reflected in a 13% increase in the fluorescence of G-actin labeled with the fluorophore 7-chloro-4-nitrobenzene-2-oxadiazole (NBD-labeled actin). The rate of the ATP hydrolysis that accompanies elongation is slower with Ca-G-actin than with Mg-G'-actin (i.e. with Ca2+ rather than Mg2+ at the high-affinity site) although their rates of elongation are similar. The slow ATP hydrolysis on Ca-F-actin causes a lag in the increase in fluorescence associated with the elongation of actin labeled with the fluorophore N-pyrene iodoacetamide (pyrenyl-labeled actin), even though there is no lag in the elongation rate, because pyrenyl-labeled ATP-F-actin subunits have a lower fluorescence intensity than pyrenyl-labeled ADP-F-actin subunits. The effects of the cation bound to the high-affinity binding site must, therefore, be considered in quantitatively analyzing the kinetics of polymerization of NBD-labeled actin and pyrenyl-labeled actin. Although their elongation rates are not very different, the rate of nucleation is much slower for Ca-G-actin than for Mg-G'-actin, probably because of the slower rate of ATP hydrolysis when Ca2+ is bound to the high-affinity site.     

pH-induced changes in G-actin conformation and metal affinity

Metal-induced conformational changes in actin at 20 degrees C have been investigated as a function of pH using actin labeled at Cys-374 with N-(iodoacetyl)-N'-(5-sulfo-1-naphthyl)ethylenediamine. At pH 8, the addition of a high Ca2+ concentration (2 mM) to G-actin gives an instantaneous fluorescence increase while the addition of a high Mg2+ concentration gives both an instantaneous and a slow fluorescence increase. The instantaneous increase is interpreted as divalent cation binding to low-affinity, relatively nonspecific sites, while the slow response is attributed to Mg2+ binding to specific sites of moderate affinity [Zimmerle, C.T., Patane, K., & Frieden, C. (1987) Biochemistry 26, 6545-6552]. The magnitudes of both the instantaneous and slow fluorescence increases associated with Mg2+ addition to G-actin are shown here to decrease as the pH is lowered while the fluorescence of labeled G-actin in the presence of low or moderate Ca2+ concentrations (less than 200 microM) increases. The pH-dependent data suggest that protonation of a single class of residues with an approximate pK of 6.8 alters the immediate environment of the label differently depending upon the cation bound at the moderate-affinity site. The pH-dependent changes in the magnitude of the slow fluorescence response upon Mg2+ addition to Ca2+-actin are not associated with changes in the Mg2+ affinity at the moderate-affinity site but result from protonation altering the fluorescence response to Mg2+ binding. Protonation of this same class of residues is proposed to induce an actin conformation similar to that induced by cation binding at the low-affinity sites.(ABSTRACT TRUNCATED AT 250 WORDS)     

A novel actin label: a fluorescent probe at glutamine-41 and its consequences

By peptide isolation and analysis, it has been shown that the dansyl fluorophore of dansylcadaverine [N-(5-aminopentyl)-5-(dimethylamino)naphthalene-1-sulfonamide] transfers to Gln-41 of actin from rabbit skeletal muscle when the reaction is catalyzed by guinea pig liver transglutaminase. As a function of time, the degree of labeling asymptotically approaches 1 mol of dansyl/l mol of actin. About 80-85% of the attached dansyl fluorophore was found at Gln-41. Such labeled G-actin polymerizes to the same extent as control actin, but the polymerization rate is greater and the critical concentration is less than for control actin. Complete polymerization is accompanied by a 1.5-2.0-fold increase in the emission intensity of the attached fluorophore. Labeled F-actin thus obtained activates myosin subfragment 1 (S-1) Mg2+-ATPase activity with the same Kapp, and to the same Vmax, as control actin; moreover, when such labeled F-actin is cross-linked to S-1 by 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide, the resulting superactivation of Mg2+-ATPase is the same as that attained with control actin. The attributes of this label thus make it an ideal reporter of events in the N-terminal 10-kilodalton region of actin, and a new topological point for proximity mapping.     

Myosin-induced changes in F-actin: fluorescence probing of subdomain 2 by dansyl ethylenediamine attached to Gln-41.

Actin labeled at Gln-41 with dansyl ethylenediamine (DED) via transglutaminase reaction was used for monitoring the interaction of myosin subfragment 1 (S1) with the His-40-Gly-42 site in the 38-52 loop on F-actin. Proteolytic digestions of F-actin with subtilisin and trypsin, and acto-S1 ATPase measurements on heat-treated F-actin revealed that the labeling of Gln-41 had a stabilizing effect on subdomain 2 and the actin filaments. DED on Gln-41 had no effect on the values of K(m) and Vmax of the acto-S1 ATPase and the sliding velocities of actin filaments in the in vitro motility assays. This suggests either that S1 does not bind to the 40-42 site on actin or that such binding is not functionally important. The binding of monoclonal antidansyl IgG to DED-F-actin did not affect acto-S1 binding in the absence of nucleotides, indicating that the 40-42 site does not contribute much to rigor acto-S1 binding. Myosin-induced changes in subdomain 2 on actin were manifested through an increase in the fluorescence of DED-F-actin, a decrease in the accessibility of the probe to collisional quenchers, and a partial displacement of antidansyl IgG from actin by S1. It is proposed that these changes in the 38-52 loop on actin originate from S1 binding to other myosin recognition sites on actin.     

The kinetics of cytochalasin D binding to monomeric actin

It has been shown previously, using G-actin labeled with N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylene-diamine, that Mg2+ induces a conformational change in monomeric G-actin as a consequence of binding to a tight divalent cation binding site (Frieden, C. (1982) J. Biol. Chem. 257, 2882-2886). Using the same fluorescent probe, we show that, subsequent to the Mg2+-induced conformational change, cytochalasin D induces a fluorescence decrease. The data are consistent with a mechanism which proposes that, after Mg2+ binding, cytochalasin D binds and induces a second conformational change which results in overall tight binding of the cytochalasin. The initial binding of cytochalasin D to monomeric actin labeled with the fluorescent probe was found to be 200 microM, and the forward and reverse rate constants for the subsequent conformational change were 350 s-1 and 8 s-1, respectively, with an overall dissociation constant to the Mg2+-induced form of 4.6 microM. The conformational change does not occur in monomeric actin in the presence of Ca2+ rather than Mg2+, but Ca2+ competes with Mg2+ for the tight binding site on the G-actin molecule. Direct binding studies show that actin which has not been labeled with the fluorophore binds cytochalasin D more tightly. The conformational change induced by Mg2+ and cytochalasin D precedes the formation of an actin dimer.     

Labeling the (Ca(2+)-Mg2+)-ATPase of sarcoplasmic reticulum with 4-(bromomethyl)-6,7-dimethoxycoumarin: detection of conformational changes.

The (Ca(2+)-Mg2+)-ATPase of sarcoplasmic reticulum was labeled with 4-(bromomethyl)-6,7-dimethoxycoumarin. It was shown that a single cysteine residue (Cys-344) was labeled on the ATPase, with a 25% reduction in steady-state ATPase activity and no reduction in the steady-state rate of hydrolysis of p-nitrophenyl phosphate. The fluorescence intensity of the labeled ATPase was sensitive to pH, consistent with an effect of protonation of a residue of pK 6.8. Fluorescence changes were observed on binding Mg2+, consistent with binding to a single site of Kd 4 mM. Comparable changes in fluorescence intensity were observed on binding ADP in the presence of Ca2+. Binding of AMP-PCP produced larger fluorescence changes, comparable to those observed on phosphorylation with ATP or acetyl phosphate. Phosphorylation with P(i) also resulted in fluorescence changes; the effect of pH on the fluorescence changes was greater than that on the level of phosphorylation measured directly using [32P]P(i). It is suggested that different conformational states of the phosphorylated ATPase are obtained at steady state in the presence of Ca2+ and ATP and at equilibrium in the presence of P(i) and absence of Ca2+.     

Actin polymerization. The mechanism of action of cytochalasin D

Fluorescence changes using actin covalently labeled with N-(1-pyrenyl)iodoacetamide have been used to determine the effect of cytochalasin D on actin polymerization. A mechanism for the effect of cytochalasin D on actin polymerization is presented, which explains the experimental observation of a cytochalasin D-induced increase in the initial rate of polymerization and a decrease in the final extent of the reaction. Central to this mechanism is the Mg2+-dependent formation of cytochalasin D-induced dimers. The dimers serve as nuclei to enhance the polymerization rate. Binding of Mg2+ to a low affinity site on the dimer induces a conformational change which can be observed as a rapid fluorescence increase. A subsequent time-dependent fluorescence decrease observed prior to polymerization appears to represent ATP hydrolysis resulting in dissociation of the dimer and release of actin monomers containing ADP. We postulate that a slow rate of exchange of ATP for bound ADP relative to hydrolysis results in the accumulation of monomers containing ADP. As these monomers have a high critical concentration, the final extent of polymerization is reduced dramatically. The Mg2+ dependence of the final extent of polymerization in the presence of cytochalasin D is also explained in the context of this mechanism.     

Evidence that F-actin can hydrolyze ATP independent of monomer-polymer end interactions

The rate of ATP hydrolysis in solutions of F-actin at steady state in 50 mM KC1, 0.1 mM CaC12 was inhibited by AMP and ADP. The inhibition was competitive with ATP (Km of about 600 microM) with Ki values of 9 microM for AMP and 44 microM for ADP. ATP hydrolysis was inhibited greater than 95% by 1 mM AMP. AMP had no effect on the time course of actin polymerization, ATP hydrolysis during polymerization, or the critical actin concentration. Simultaneous measurements of G-actin/F-actin subunit exchange and nucleotide exchange showed that nucleotide exchange occurred much more rapidly than subunit exchange; during the experiment over 50% of the F-actin-bound nucleotide was replaced when less than 1% of the F-actin subunits had exchanged. When AMP was present it was incorporated into the polymer, preventing incorporation of ADP from ATP in solution. F-actin with bound Mg2+ was much less sensitive to AMP than F-actin with bound Ca2+. These data provide evidence for an ATP hydrolysis cycle associated with direct exchange of F-actin-bound ADP for ATP free in solution independent of monomer-polymer end interactions. This exchange and hydrolysis of nucleotide may be enhanced when Ca2+ is bound to the F-actin protomers.     

Actin-gelsolin interactions. Evidence for two actin-binding sites

We have used a fluorescence enhancement of actin labeled with 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-actin) to study the interactions between rabbit skeletal muscle G-actin and either purified platelet gelsolin or a 130-kDa binary complex of platelet actin and gelsolin that is stable in EGTA and can be purified from human platelets. We have delineated four binding reactions. The exchange of Mg2+ for Ca2+ on the divalent cation-binding site of NBD-actin gives a small fluorescence increase. Binding of monomeric NBD-actin to the binary complex results in a 2.5-fold increase in the emission at 530 nm in the presence of Ca2+ and a 2-fold increase in the presence of EGTA. Titration experiments show that, under nonpolymerizing conditions, one additional actin is bound to the 130-kDa species to form a ternary complex. This binding is Ca2+-sensitive. Purified gelsolin does not appear to bind to NBD-actin in the presence of EGTA, as determined by fluorescence enhancement, gel filtration, or sedimentation measurements, but the addition of Ca2+ promotes rapid binding with a 1.6-1.7-fold enhancement of the emission intensity. A comparison of the relative fluorescence yields/NBD-actin molecule for a binary complex of gelsolin and one NBD-actin, a ternary complex of gelsolin and two NBD-actin molecules, and a ternary complex with an unlabeled actin in the EGTA-stable site and an NBD-actin in the second site indicates that the first NBD-actin, in the EGTA-stable site, does not give a fluorescence increase on binding but the second one does. Finally, we have demonstrated that one molecule of 45Ca2+ is "trapped" when the binary complex is formed and cannot be removed by EGTA. A summary model for these reactions is presented that indicates the interaction between actin and gelsolin is not a freely reversible Ca2+-controlled reaction.     

Rapid exchange of actin-bound nucleotide in perfused rat heart

In the rat heart the actin-bound nucleotide contained both ATP and ADP. The ratio of bound ATP to bound ADP depended on the functional state of the heart; it was higher in hearts stopped reversibly in diastole (low Ca(2+), high Mg(2+), or high K(+)), than in stimulated (inotropic agents or pacing) hearts. Immunoblotting and gel electrophoresis showed the existence of G-actin (30% of total actin) in the cytoplasm of the heart. Pure actin was isolated from rat hearts: in G-actin the bound nucleotide readily exchanged with ATP or ADP, and in F-actin the bound nucleotide did not exchange with ATP or ADP. The free and bound nucleotides were separated in the intact heart by extraction with 75% methanol at -15 degrees C. In rat hearts perfused with (32)P-labeled orthophosphate the actin-bound nucleotide rapidly exchanged with the cytoplasmic ATP. The full exchange of the bound ATP was immediate, whereas the full exchange of the bound ADP was slower. The full exchange of the bound ATP was independent of the heartbeat frequency, whereas the full exchange of the bound ADP was frequency dependent. The data suggest that the transformation of actin monomer-ATP to actin polymer-ADP is a part of the normal contraction-relaxation cycle of the rat heart.     

Cofilin and DNase I affect the conformation of the small domain of actin

Cofilin binding induces an allosteric conformational change in subdomain 2 of actin, reducing the distance between probes attached to Gln-41 (subdomain 2) and Cys-374 (subdomain 1) from 34.4 to 31.4 A (pH 6.8) as demonstrated by fluorescence energy transfer spectroscopy. This effect was slightly less pronounced at pH 8.0. In contrast, binding of DNase I increased this distance (35.5 A), a change that was not pH-sensitive. Although DNase I-induced changes in the distance along the small domain of actin were modest, a significantly larger change (38.2 A) was observed when the ternary complex of cofilin-actin-DNase I was formed. Saturation binding of cofilin prevents pyrene fluorescence enhancement normally associated with actin polymerization. Changes in the emission and excitation spectra of pyrene-F actin in the presence of cofilin indicate that subdomain 1 (near Cys-374) assumes a G-like conformation. Thus, the enhancement of pyrene fluorescence does not correspond to the extent of actin polymerization in the presence of cofilin. The structural changes in G and F actin induced by these actin-binding proteins may be important for understanding the mechanism regulating the G-actin pool in cells.     

Structural effects of cofilin on longitudinal contacts in F-actin

Structural effects of yeast cofilin on skeletal muscle and yeast actin were examined in solution. Cofilin binding to native actin was non-cooperative and saturated at a 1:1 molar ratio, with K(d)相似文献   

The influence of adenosine triphosphate, adenosine diphosphate and cytochalasin B on nucleotide exchange of F-actin. Evidence that treadmilling is not involved

[14C]ATP-containing G-actin was polymerized to [14C]ADP-containing F-actin. The exchange of the filament-bound nucleotide with nucleotides of the medium was investigated by measuring the loss of radioactivity from the filaments under various conditions. Nucleotide exchange was faster in the presence of ATP than of ADP (this could be observed in the presence of Mg2+ as well as in the presence of Ca2+). Cytochalasin B had a small accelerating effect in the presence of ATP but had no effect in the presence of ADP. The kinetics of exchange remained unchanged when the filaments contained a 'cap' of actin with non-radioactive nucleotides, suggesting that nucleotide exchange was not a property of the filament ends.     

Conformational changes of actin induced by strong or weak myosin subfragment-1 binding

Movements of different areas of polypeptide chains within F-actin monomers induced by S1 or pPDM-S1 binding were studied by polarized fluorimetry. Thin filaments of ghost muscle were reconstructed by adding G-actin labeled with fluorescent probes attached alternatively to different sites of actin molecule. These sites were: Cys-374 labeled with 1,5-IAEDANS, TMRIA or 5-IAF; Lys-373 labeled with NBD-Cl; Lys-113 labeled with Alexa-488; Lys-61 labeled with FITC; Gln-41 labeled with DED and Cys-10 labeled with 1,5-IAEDANS, 5-IAF or fluorescein-maleimid. In addition, we used TRITC-, FITC-falloidin and e-ADP that were located, respectively, in filament groove and interdomain cleft. The data were analysed by model-dependent and model-independent methods (see appendixes). The orientation and mobility of fluorescent probes were significantly changed when actin and myosin interacted, depending on fluorophore location and binding site of actomyosin. Strong binding of S with actin leads to 1) a decrease in the orientation of oscillators of derivatives of falloidin (TRITC-falloidin, FITC-falloidin) and actin-bound nucleotide (e-ADP); 2) an increase in the orientation of dye oscillators located in the "front' surface of the small domain (where actin is viewed in the standard orientation with subdomains 1/2 and 3/4 oriented to the right and to the left, respectively); 3) a decrease in the angles of dye oscillators located on the "back" surface of subdomain-1. In contrast, a weak binding of S1 to actin induces the opposite effects in orientation of these probes. These data suggest that during the ATP hydrolysis cycle myosin heads induce a change in actin monomer (a tilt and twisting of its small domain). Presumably, these alterations in F-actin conformation play an important role in muscle contraction.     

Fluorescence study of the high pressure-induced denaturation of skeletal muscle actin.

Ikkai & Ooi [Ikkai, T. & Ooi, T. (1966) Biochemistry 5, 1551-1560] made a thorough study of the effect of pressure on G- and F-actins. However, all of the measurements in their study were made after the release of pressure. In the present experiment in situ observations were attempted by using epsilon ATP to obtain further detailed kinetic and thermodynamic information about the behaviour of actin under pressure. The dissociation rate constants of nucleotides from actin molecules (the decay curve of the intensity of fluorescence of epsilon ATP-G-actin or epsilon ADP-F-actin) followed first-order kinetics. The volume changes for the denaturation of G-actin and F-actin were estimated to be -72 mL x mol(-1) and -67 mL x mol(-1) in the presence of ATP, respectively. Changes in the intensity of fluorescence of F-actin whilst under pressure suggested that epsilon ADP-F-actin was initially depolymerized to epsilon ADP-G-actin; subsequently there was quick exchange of the epsilon ADP for free epsilon ATP, and then polymerization occurred again with the liberation of phosphate from epsilon ATP bound to G-actin in the presence of excess ATP. In the higher pressure range (> 250 MPa), the partial collapse of the three-dimensional structure of actin, which had been depolymerized under pressure, proceeded immediately after release of the nucleotide, so that it lost the ability to exchange bound ADP with external free ATP and so was denatured irreversibly. An experiment monitoring epsilon ATP fluorescence also demonstrated that, in the absence of Mg(2+)-ATP, the dissociation of actin-heavy meromyosin (HMM) complex into actin and HMM did not occur under high pressure.