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)     

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.     

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)     

Effect of pH on the mechanism of actin polymerization

The effect of pH on the Mg2+-induced polymerization of rabbit skeletal muscle G-actin at 20 degrees C was examined. Polymerization data were obtained at various initial concentrations of Mg2+, Ca2+, and G-actin between pH 6 and 7.5. The data were found to fit a kinetic mechanism for actin polymerization previously proposed at pH 8 in which Mg2+ binding at a moderate-affinity site on actin induces an isomerization of the protein enabling more favorable nucleation [Frieden, C. (1982) J. Biol. Chem. 257, 2882-2886]. The data also suggest the formation of actin dimers induced by Mg2+ binding is over 2 orders of magnitude more favorable at pH 6 than at pH 8. Little effect on trimer formation is found over this pH range. In addition, the conformation induced by nonspecific binding of metal to low-affinity sites becomes more favorable as the pH is lowered. The critical concentration for filament formation is also decreased at lower pH. The kinetic data do not support fragmentation occurring under any of the conditions examined. Furthermore, as Mg2+ exchange for Ca2+ at a high-affinity site (Kd less than 10(-9) M) fails to alter significantly the polymerization kinetics, Ca2+ release from this site appears unnecessary for either the nucleation or the elongation of actin filaments.     

High affinity divalent cation binding to actin. Effect of low affinity salt binding

Monomeric actin labeled with the fluorescent probe N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (1,5-I-AEDANS-actin) displays a fast fluorescence intensity increase immediately upon addition of salt and then a slow fluorescence intensity change concurrent with Ca2+/Mg2+ exchange at the high affinity divalent cation binding site on actin. The fast change appears to reflect competitive binding of K+ at low affinity (nonspecific) sites and of Mg2+ or Ca2+ at low and intermediate affinity sites. Binding of cation at the low affinity sites (but apparently not at the intermediate affinity sites) results in an increase in k-Ca and k-Mg and thus a decrease in affinity for divalent cations at the high affinity site. The effect of Mg2+ on k-Ca is twice that of K+ for equal fractional saturations of the low affinity binding, and the effect of K+ and Mg2+ together on k-Ca reflects competitive binding at the low affinity sites. Thus the affinity and kinetics of divalent cation binding at the high affinity site of actin are significantly affected by concurrent cation binding at low affinity sites.     

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.     

Conformational changes in subdomain 2 of G-actin: fluorescence probing by dansyl ethylenediamine attached to Gln-41.

Gln-41 on G-actin was specifically labeled with a fluorescent probe, dansyl ethylenediamine (DED), via transglutaminase reaction to explore the conformational changes in subdomain 2 of actin. Replacement of Ca2+ with Mg2+ and ATP with ADP on G-actin produced large changes in the emission properties of DED. These substitutions resulted in blue shifts in the wavelength of maximum emission and increases in DED fluorescence. Excitation of labeled actin at 295 nm revealed energy transfer from tryptophans to DED. Structure considerations and Cu2+ quenching experiments suggested that Trp-79 and/or Trp-86 serves as energy donors to DED. Energy transfer from these residues to DED on Gln-41 increased with the replacement of Ca2+ with Mg2+ and ATP with ADP. Polymerization of Mg-G-actin with MgCl2 resulted in much smaller changes in DED fluorescence than divalent cation substitution. This suggests that the conformation of loop 38-52 on actin is primed for the polymerization reaction by the substitution of Ca2+ with Mg2+ on G-actin.     

Fluorescence measurements of the binding of cations to high-affinity and low-affinity sites on ATP-G-actin

The binding of cations to ATP-G-actin has been assessed by measuring the kinetics of the increase in fluorescence of N-acetyl-N'-(5-sulfo-1-naphthyl)-ethylenediamine-labeled actin. Ca2+ and Mg2+ compete for a single high-affinity site on ATP-G-actin with KD values of 1.5-15 nM for Ca2+ and 0.1-1 microM for Mg2+, i.e. with affinities 3-4 orders of magnitude higher than previously reported (Frieden, C., Lieberman, D., and Gilbert, H. R. (1980) J. Biol. Chem. 255, 8991-8993). As proposed by Frieden (Frieden, C. (1982) J. Biol. Chem. 257, 2882-2886), the Mg-actin complex undergoes a slow isomerization (Kis = 0.03-0.1) to a higher affinity state (K'D = 4-40 nM). The replacement of Ca2+ by Mg2+ at this high-affinity site causes a slow 10% increase in fluorescence that is 90% complete in about 200 s at saturating concentrations of Mg2+. Independently, Ca2+, Mg2+, and K+ bind to low-affinity sites (KD values of 0.15 mM for Ca2+ and Mg2+ and 10 mM for K+) which causes a rapid 6-8% increase in fluorescence (complete in less than 5 s). We propose that the activation step that converts Ca-G-actin to a polymerizable species upon addition of Mg2+ is the binding of Mg2+ to the low-affinity sites and not the replacement of Ca2+ by Mg2+ at the high-affinity site.     

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.     

Tight binding of divalent cations to monomeric actin. Binding kinetics support a simplified model

Using the fluorescent Ca2+ selective chelator Quin2 to induce and measure the dissociation of Ca2+ from actin, we have recently found that actin binds Ca2+ and Mg2+ much more tightly than previously thought (Gershman, L.C., Selden, L.A., and Estes, J.E. (1986) Biochem. Biophys. Res. Commun. 135, 607-614). In this report, we show that the kinetics of dissociation of Ca2+ from Ca-actin and Mg2+ from Mg-actin closely parallel the fluorescence changes in 1,5-I-N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (AEDANS)-actin, suggesting that the 1,5-I-AEDANS-actin fluorescence directly reflects slow first-order cation exchange rather than a slow Mg2+-induced isomerization as originally proposed by Frieden (Frieden, C. (1982) J. Biol. Chem. 257, 2882-2886). Measuring divalent cation exchange directly, we have determined the dissociation rate constants for Ca2+ (k-Ca) and Mg2+ (k-Mg), the equilibrium dissociation constants for Ca2+ (KCa), and the ratio of cation binding affinities, KMg/Kca, to actin over the pH range 7-8. We have found that k-Ca is 5-10 times greater than k-Mg and KMg is about 4 times greater than KCa. From the data we calculate the association rate constants for Ca2+ (kCa) and Mg2+ (kMg) to be about 7 X 10(6) M-1 s-1 and 2 X 10(5) M-1 s-1, respectively. kCa appears to be diffusion-limited, but kMg is significantly smaller due to the characteristics of the Mg2+ aquo ion. These findings are consistent with a simple first-order binding model for the tight binding of divalent cations to actin.     

The dependence on internal pH of Ca2+-fluxes across sarcoplasmic reticulum vesicular membranes

The interdependence of the competition between Ca2+ and hydrogen ions for the internally located low-affinity Ca2+ binding sites of sarcoplasmic reticulum vesicles and the pH-dependent splitting rate of phosphoenzyme was investigated. Sarcoplasmic reticulum vesicles were preincubated at a selected pH and passive Ca2+ loading, active Ca2+ uptake at the same pH as well as active Ca2+ uptake at a distinct pH (pH-jump method) were observed. In addition, Cai-Cao exchange in the absence and presence of ADP and ATP-ADP exchange were measured. The overall ATP splitting rate was assayed with leaky vesicles in the presence of varied Ca2+ concentration and four different pH. All experiments were carried out at Ca2+ concentrations sufficient to saturate the externally located activating high-affinity binding sites at all pH and in the absence of affecting concentrations of monovalent cations. Active Ca2+ transport (particularly evident applying the pH-jump method) is facilitated at low intravesicular pH, reflecting the favoured Ca2+ release to the intravesicular space, in contrast to the reverse pH-dependence of passive Ca2+ accumulation and the initial rate of Cai-Cao exchange, both favoured by elevated internal Ca2+ binding capacity. The rates of ATP splitting, the continuing slow rate of Cai-Cao exchange, and the ATP-ADP exchange are optimal at an intermediate proton concentration, reflecting the influence of protons on partial reaction steps occurring later in the reaction cycle and the accelerated exchange of Ca2+ at the internal low-affinity sites as well as the establishment of a new pseudo equilibrium between the possible reaction intermediates. The pool of rapidly exchangeable Ca2+ is enlarged whereas the rate of slow exchange is unaltered or diminished (pH 7.8) by ADP.     

Conformational changes in actin resulting from Ca2+/Mg2+ exchange as detected by proton NMR spectroscopy

Skeletal muscle actin can be maintained in a monomeric form in very low ionic strength solutions as well as in high concentrations (0.6 M) of MgCl2 or CaCl2. 400-MHz 1H-NMR spectra revealed characteristic changes which show that the conformation of actin alters by exchanging Ca2+ for Mg2+ in the single high-affinity cation binding site. When all low-affinity cation binding sites are filled (in the presence of high concentrations of Ca2+ or Mg2+), the spectra show that actin conformation differs from that in low-ionic-strength buffer. A comparison of actin in 0.6 M CaCl2 and 0.6 M MgCl2 revealed that the environment of only a small number of protons is affected by the exchange. A new proposal for the essential steps involved in actin polymerization is presented.     

High and low affinity Ca2+ binding to the sarcoplasmic reticulum: use of a high-affinity fluorescent calcium indicator.

The fluorescent calcium indicator, calcein, has been used as a high-affinity indicator of Ca2+ in the aqueous phase at physiological pH in the study of high-affinity calcium binding to sarcoplasmic reticulum (SR). The binding constant of the indicator at physiological pH is 10(3)-10(4) M-1 and increases with increasing pH. The binding mechanism of the indicator with Ca2+ and Mg2+ is described. Application of calcein as an aqueous indicator of Ca2+ binding to the SR at room temperature has revealed two classes of binding sites: one with high capacity and low affinity (ca. 820 nmol/mg protein, Kd = 1.9 mM), and another with low capacity and higher affinity (ca. 35 nmol/mg protein, Kd = 17.5 micronM). The divalent cation specificity of the low-affinity site is low and Ca2+/Mg2+ specificity of the high-affinity site is high. Quantitative studies of the bindings indicate that the high-affinity site residues in the Ca2+ ATPase (carrier) protein and represents complexation in the active site of the carrier and that the low-affinity site residues in the nonspecific acidic binding proteins. The contribution of Donnan equilibrium effects to the measured binding is shown to be insignificant. Stopped flow kinetic studies of Ca2+ passive binding with calcein and arsenazo III dyes have demonstrated that the binding to high-affinity site is very fast and that the overall binding reaction with the low-affinity site is slow, with a time course of about 4 s. Our analysis has shown that at least part of the low-affinity acidic proteins are within the SR matrix and that Ca2+ can reach them only by transversing the membrane via the Ca2+ carrier (Ca2+ ATPase). A model of the SR is proposed that accounts for several functional properties of the organelle in terms of its known protein composition and topological organization.     

Ruthenium red affects the intrinsic fluorescence of the calcium-ATPase of skeletal sarcoplasmic reticulum.

We have studied the effect of Ruthenium red on the sarcoplasmic reticulum Ca(2+)-ATPase. Ruthenium red does not modify the Ca2+ pumping activity of the enzyme, despite its interaction with cationic binding sites on sarcoplasmic reticulum vesicles. Two pools of binding sites were distinguished. One pool (10 nmol/mg) is dependent upon the presence of micromolar Ca2+ and may therefore represent the high-affinity Ca2+ transport sites of the Ca(2+)-ATPase. However, Ruthenium red only slightly competes with Ca2+ on these sites. The other pool (15-17 nmol/mg) is characterized as low-affinity cation binding sites of sarcoplasmic reticulum, distinct from the Mg2+ site involved in the ATP binding to the Ca(2+)-ATPase. The interaction of Ruthenium red with these low-affinity cation binding sites, which may be located either on the Ca(2+)-ATPase or on surrounding lipids, decreases tryptophan fluorescence level of the protein. As much as 25% of the tryptophan fluorescence of the Ca(2+)-ATPase is quenched by Ruthenium red (with a dissociation constant of 100 nM), tryptophan residues located near the bilayer being preferentially affected.     

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.     

Calcium-binding properties of cardiac and skeletal troponin C as determined by circular dichroism and ultraviolet difference spectroscopy.

Calcium titration of the conformational change in cardiac and skeletal troponin C (TN-C) was followed by circular dichroism (CD) at pH values in the range from 5.2 to 7.4. Computer analysis was used to resolve the contributions from the different classes of Ca2+ -binding sites. At pH 6.94 in skeletal TN-C, apparent affinity constants for calcium of 1.8 x 10(7) and 4.5 x 10(5) M-1 were determined for the two classes of binding sites. The more sophisticated computer analysis of the data has revealed a substantial CD contribution from the low-affinity sites (approximately 30% of the high affinity contribution at pH 6.94) and suggests that skeletal TN-C with Ca2+ bound at the low-affinity sites is in a different conformation from that when just the high-affinity sites are occupied, in agreement with a recent nuclear magnetic resonance (NMR) study on this system (Seaman, K. B., Hartshorne, D. J. & Bothener-By, A. A. (1977) Biochemistry 16,4039-4046). With the cardiac protein at pH 7.07, an apparent affinity constant for calcium of 2.0 x 10(7) M-1 was calculated while no low-affinity site at this pH was detected by CD. On the other hand, at lower pH values, such as 6.05, a CD contribution from the cardiac low-affinity Ca2+ -binding site is detected with an apparent binding constant of 3.7 +/- 0.7 x 10(4) M-1. At the lower pH values, protonation of a class of carboxyl groups in each protein which possesses a high pKa (6.2-6.3) elicits the conformational change at the high-affinity sites with a corresponding decrease in the overall magnitude of the Ca2+ -evoked changes. The expression of a conformational change upon Ca2+ binding at the level of the low-affinity sites is enchanced by protonation of a class of carboxyls with a pKa of 6.3 in cardiac TN-C and 6.7-6.8 with the skeletal homologue. In both cases, this contribution is reduced upon protonation of carboxyls with pKa less than or equal to 5.5. It was also observed that the low-affinity sites of skeletal TN-C have a much larger role to play in the total conformational change than the low-affinity sites of cardiac TN-C, a finding probably related to the inability of site 1 in the cardiac protein to bind calcium. In the cardiac protein, the Ca2+ -induced tyrosine difference-spectrum maximum is reduced from deltaepsilonM,287nm =330M-1.cm-1 to 20M-1.cm-1 by protonation of a class of groups with a pKa of 6.4, presumably the same carboxyl groups as those invoved in the CD conformational contribution from the high-affinity binding sites. No such effect was observed for the skeletal protein where deltaepsilonM,287nm was constant at 110M-1 .cm-1 over the pH range studied. The dramatic alterations in the tyrosine environment of cardiac TN-C with pH are attributed to either or both of the tyrosines located in the two high-affinity Ca2+ -binding sites (sites 3 and 4)...     

Troponin-C-mediated calcium-sensitive changes in the conformation of troponin I detected by pyrene excimer fluorescence

Troponin I (TnI) from rabbit white skeletal muscle was labeled at cysteines 48 and 64 with the fluorescent reagent N-(1-pyrene)maleimide. The fluorescence spectra of pyrene-labeled TnI (pyr-TnI) exhibit peaks characteristic of pyrene in its monomeric form and an additional peak resulting from formation of excited dimers (excimers), indicating that the labeled cysteines are close together. Formation of a pyr-TnI-TnC complex in the absence of Ca2+ has little effect on the spectrum, but when Ca2+ is bound to the low-affinity sites of TnC there is a substantial decrease in excimer and a corresponding increase in monomer fluorescence. The involvement of the low-affinity sites in the Ca2+-induced effect is consistent with the fact that Mg2+ has no effect on pyrene fluorescence. On rapid mixing of the pyr-TnI-TnC complex with Ca2+ in a stopped-flow apparatus, most of the excimer decrease is complete within the instrumental dead time, indicating a rate constant k greater than 350 s-1, which is comparable to that of the conformational change in TnC resulting from Ca2+ binding to the low-affinity sites. Rapid mixing of the Mg2-TnC-pyr-TnI complex with Ca2+ yields similar results, suggesting that the type of metal ion present at the high-affinity sites has little, if any, effect on the probe. It has been suggested previously that Cys 48 and 64 are located in a TnT-binding region of TnI (Chong P.C.S. and Hodges, R.S. (1982) J. Biol. Chem. 255, 3757). Our results suggest that a Ca2+-induced structural change in the TnI-binding region of TnC could be transmitted to TnT by affecting the TnT-binding region of TnI as part of the chain of events in the regulation of muscle contraction.     

Proton nuclear magnetic resonance and electron paramagnetic resonance studies on skeletal muscle actin indicate that the metal and nucleotide binding sites are separate

The distance separating the high-affinity binding sites of actin for a divalent metal ion and nucleotide was evaluated by using high-resolution proton NMR and EPR spectroscopy. Replacement of the Ca2+ or Mg2+ bound to the high-affinity divalent cation site of G-actin by trivalent lanthanide ions such as La3+, EU3+, or Gd3+ results in an increase in the mobility of the bound ATP as observed in the NMR spectra of G-actin monomers. Little difference was observed between the spectra obtained in the presence of the diamagnetic La3+ control and the paramagnetic ions Eu3+ and Gd3+ which respectively shift and broaden the proton resonances of amino acids in the vicinity of the binding site. Analysis of the NMR spectra indicates that the metal and nucleotide binding sites are separated by a distance of at least 16 A. In the past, the metal and ATP have been widely assumed to bind as a complex. Further verification that the two sites on actin are physically separated was obtained by using an ATP analogue with a nitroxide spin-label bound at the 6' position of the purine ring. An estimate of the distance was made between the site containing the ATP analogue and the paramagnetic ion, Mn2+, bound to the cation binding site. These EPR experiments were not affected by the state of polymerization of the actin. The data obtained by using this technique support the conclusion stated above, namely, that the cation and nucleotide sites on either G- or F-actin are well separated.     

Kinetics of nucleotide and metal ion interaction with G-actin

The kinetics of interaction of Ca2+ ions and nucleotides with G-actin have been investigated by making use of the enhancement of 1,N6-ethenoadenosine 5'-triphosphate (epsilon ATP) fluorescence on binding to actin, the enhancement of 2-[[2-[bis(carboxymethyl)amino]-5-methylphenoxy] methyl]-6-methoxy-8-[bis(carboxymethyl)amino]quinoline (Quin-2) fluorescence on binding to Ca2+, and the sensitivity of the fluorescence of an N-(iodoacetyl)-N'-(5-sulfo-1-naphthyl)ethylenediamine (1,5-AEDANS) group on Cys-374 to metal ion binding. It is concluded that metal ion dissociation is the rate-limiting step in nucleotide dissociation (0.016 s-1 for Ca2+ at pH 7.2 and 21 degrees C) and that earlier conclusions that metal ion release is relatively fast and subsequent nucleotide release slow are incorrect. Results presented here and obtained by others on the metal ion concentration dependence of the effective rate of nucleotide exchange can be interpreted in the light of this conclusion in terms of a limiting rate which corresponds to that of metal ion release and an "apparent" dissociation constant for Ca2+ which is without direct physical significance. This apparent dissociation constant is more than 2 orders of magnitude greater than the real dissociation constant of Ca2+ from the Ca-actin-ATP complex, which was estimated to be 2 X 10(-9) M from a titration with Quin-2. Confirmation that the rate of Ca2+ release is rate limiting both in nucleotide dissociation reactions and in replacement of Ca2+ by Mg2+ was obtained with 1,5-AEDANS-actin, since both the replacement of Ca2+ by Mg2+ and the removal of Ca2+ to give the actin-ATP complex occurred at the same (slow) rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of temperature on the mechanism of actin polymerization

The rate of the Mg2+-induced polymerization of rabbit skeletal muscle G-actin has been measured as as function of temperature at pH 8 by using various concentrations of Mg2+, Ca2+, and G-actin. A polymerization mechanism similar to that proposed at this pH [Frieden, C. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 6513-6517] was found to fit the data from 10 to 35 degrees C. From the kinetic data, no evidence for actin filament fragmentation was found at any temperature. Dimer formation is the most temperature-sensitive step, with the ratio of forward and reverse rate constants changing 4 orders of magnitude from 10 to 35 degrees C. Over this temperature change, all other ratios of forward and reverse rate constants change 7-fold or less, and the critical concentration remains nearly constant. The reversible Mg2+-induced isomerization of G-actin monomer occurs to a greater extent with increasing temperature, measured either by using N-(iodoacetyl)-N'-(5-sulfo-1-naphthyl)ethylenediamine-labeled actin or by simulation of the full-time course of the polymerization reaction. This is partially due to Mg2+ binding becoming tighter, and Ca2+ binding becoming weaker, with increasing temperature. Elongation rates from the filament-pointed end, determined by using actin nucleated by plasma gelsolin, show a temperature dependence slightly larger than that expected for a diffusion-limited reaction.