Fluorescence studies of the conformational dynamics of parvalbumin in solution: lifetime and rotational motions of the single tryptophan residue

The fluorescence properties of the single tryptophan residue in whiting parvalbumin were used to probe the dynamics of the protein matrix. Ca2+ binding caused a blue-shift in the emission (from lambda max = 339 to 315 nm) and a 2.5-fold increase in quantum yield. The fluorescence decay was nonexponential in both Ca2(+)-free and Ca2(+)-bound parvalbumin and was best described by Lorentzian lifetime distributions centered around two components: a major long-lived component at 2-5 ns and a small subnanosecond component. Raising the temperature from 8 to 45 degrees C resulted in a decrease in both the center (average) and width (dispersion) of the major lifetime distribution component, whereas the center, width, and fractional intensity of the fast component increased with temperature. Arrhenius activation energies of 1.3 and 0.3 kcal/mol were obtained in the absence and in the presence of Ca2+, respectively, from the temperature dependence of the center of the major lifetime distribution component. Direct anisotropy decay measurements of local tryptophan rotations yielded an activation energy of 2.3 kcal/mol in Ca2(+)-depleted parvalbumin and indicated a correlation between rotational rates and lifetime distribution parameters (center and width). Ca2+ binding produced a decrease in the width of the major lifetime distribution component and a decrease in tryptophan rotational mobility within the protein. There was a rough correlation between these two parameters with changes in Ca2+ and temperature, so that both measurements may be taken to indicate that the structure of Ca2(+)-bound parvalbumin was more rigid than in Ca2(+)-depleted parvalbumin.     

The binding of Ca2+ ions to pig heart NAD+-isocitrate dehydrogenase and the 2-oxoglutarate dehydrogenase complex.

1. The binding of Ca2+ ions to purified pig heart NAD+-isocitrate dehydrogenase and 2-oxoglutarate dehydrogenase, freed of contaminating Ca2+ by parvalbumin/polyacrylamide chromatography, has been studied by flow dialysis and by the use of fura-2. 2. For the 2-oxoglutarate dehydrogenase complex, 3.5 mol of Ca2+-binding sites/mol of complex were apparent, with an apparent dissociation constant (Kd value) for Ca2+ of 2.0 microM. These values were little affected by Mg2+ ions, ADP or 2-oxoglutarate. 3. By contrast, binding of Ca2+ to NAD+-isocitrate dehydrogenase (Kd = 14 microM) required ADP, isocitrate and Mg2+ ions. The number of Ca2+-binding sites associated with NAD+-isocitrate dehydrogenase was then 0.9 mol/mol of tetrameric enzyme. 4. The 2-oxoglutarate dehydrogenase complex bound ADP (as ADP3-) to a group of tight-binding sites (Kd = 3.1 microM) with a stoichiometry, 3.3 mol/mol of complex, similar to that for the binding of Ca2+; a variable number of much weaker sites (Kd = 100 microM) for ADP3- was also apparent.     

Localization of a fibrinogen calcium binding site between gamma-subunit positions 311 and 336 by terbium fluorescence

Calcium is required for effective fibrin polymerization. The high affinity Ca2+ binding capacity of fibrinogen was directly localized to the gamma-chain by autoradiography of nitrocellulose membrane blots of fibrinogen subunits incubated with 45Ca2+. Terbium (Tb3+) competitively inhibited 45Ca2+ binding to fibrinogen during equilibrium dialysis, accelerated fibrin polymerization, and limited fibrinogen fragment D digestion by plasmin. The intrinsic fluorescence of Ca2+-depleted fibrinogen was maximally enhanced by Ca2+ and Tb3+, but not by Mg2+, at about 3 mol of cation/mol of fibrinogen. Protein-bound Tb3+ fluorescence at 545 nm was maximally enhanced by resonance energy transfer from tryptophan (excitation at 290 nm) at about 2 mol of Tb3+mol of fibrinogen and about 1 mol of Tb3+/mol of plasmic fragment D94 (Mr 94,000). Fibrinogen fragments D78 (Mr 78,000) and E did not show effective enhancement of Tb3+ fluorescence, suggesting that the Ca2+ site is located within gamma 303 to gamma 411, the peptide which is absent in fragment D78 but present in D94. When CNBr fragments of the carboxyamidated gamma-subunit were assayed for enhancement of Tb3+ fluorescence, peptide CBi (gamma 311-336) bound 1 mol of Tb3+/mol of CBi. Thus, the Ca2+ site is located within this peptide. The sequence between gamma 315 and gamma 329 is homologous to the calmodulin and parvalbumin Ca2+ binding sites.     

Effects of trifluoperazine on calcium binding by calmodulin. A microcalorimetric study

Microcalorimetric titrations of calmodulin with Ca2+ and trifluoperazine (TFP) at various molar ratios have been carried out at 25 degrees C and at pH 7.0. Ca2+ binding to calmodulin produces heat (-delta H) in the presence of TFP, while heat is absorbed in the absence of TFP. The total heat produced by Ca2+ binding to all four sites is increased at increasing TFP-to-calmodulin ratios, attaining a plateau at about 7. These results indicate that at the higher ratios, the enthalpy changes (delta H) associated with Ca2+ binding are affected by TFP molecules bound at both high- and low-affinity sites. In addition, the Ca2+ binding reaction of the calmodulin-TFP complex is driven solely by a favorable enthalpy change of -27 kJ/mol of site; the entropy change (delta S) is -35 J/mol/K. These thermodynamic changes are opposite to those for TFP-free calmodulin and distinctly different from other Ca2+ binding proteins such as skeletal and cardiac troponin C and parvalbumin, where the reaction is driven by favorable changes of entropy as well as enthalpy.     

Heat capacity and entropy changes of the major isotype of the toad (Bufo) parvalbumin induced by calcium binding

The possible structural changes in the major isotype of parvalbumin from the toad (Bufo bufo japonicus) skeletal muscle caused by Ca2+ and Mg2+ binding have been analyzed by microcalorimetric titrations. Parvalbumin was titrated with Ca2+ in both the absence and presence of Mg2+ and with Mg2+ in the absence of Ca2+, at pH 7.0, and at 5 degrees, 15 degrees, and 25 degrees C. The two sites in a molecule were equivalent on Mg2(+)-Ca2+ exchange, but distinguishable on Ca2+ and Mg2+ binding. The reactions of parvalbumin with Ca2+ are exothermic at every temperature in both the absence and presence of Mg2+, but those with Mg2+ are always endothermic except for the binding to site 1 at 25 degrees C. The magnitudes of the hydrophobic and internal vibrational contributions to the heat capacity and entropy changes of parvalbumin on Ca2+ and Mg2+ binding and Mg2(+)-Ca2+ exchange have been estimated by the empirical method of Sturtevant [Sturtevant, J. M. (1977) Proc. Natl Acad. Sci. USA 74, 2236-2240]. Although no major conformational changes were noted between Ca2(+)- and Mg2(+)-bound forms of toad parvalbumin, the conformational difference was larger in Ca2+ (or Mg2+) binding to site 1 than site 2. This may indicate that the metal-free form is much less stable than any form with Ca2+ (or Mg2+) bound at one site at least. On Mg2(+)-Ca2+ exchange, the vibrational as well as hydrophobic entropy is only slightly increased in a parallel manner. In contrast, on Ca2+ (or Mg2+) binding, the hydrophobic entropy increases but the vibrational entropy decreases; the former indicates the sequestering of nonpolar groups from the surface to the interior of a molecule, and the latter suggests that the overall structures are tightened on Ca2+ (or Mg2+) binding but loosened on Mg2(+)-Ca2+ exchange. Despite the clear distinctions in the thermodynamic features, the conformational changes of toad parvalbumin are essentially the same as those of the two isotypes of bullfrog parvalbumins on Ca2+ binding and Mg2(+)-Ca2+ exchange.     

The time-course of Ca2+ exchange with calmodulin, troponin, parvalbumin, and myosin in response to transient increases in Ca2+.

We have modeled the time-course of Ca2+ binding to calmodulin, troponin, parvalbumin, and myosin in response to trains of transient increases in the free myoplasmic calcium ion concentration (pCa). A simple mathematical expression was used to describe each pCa transient, the shape and duration of which is qualitatively similar to those thought to occur in vivo. These calculations assumed that all individual metal binding sites are noninteracting and that Ca2+ bind competitively to the Ca2+-Mg2+ sites of troponin, parvalbumin, and myosin. All the on-and-off rate constants for both Ca2+ and Mg2+ were obtained either from the literature or from our own research. The percent saturation of the Ca2+-Mg2+ sites with Ca2+ was found to change very little in response to each pCa transient in the presence of 2.5 X 10(-3)M Mg2+. Our analysis suggests that the Ca2+ content of these sites is a measure of the intensity and frequency of recent muscle activity because large changes in the Ca2+ occupancy of these sites can occur with repeated stimulation. In contrast, large rapid changes in the amount of Ca2+ bound to the Ca2+-specific sites of troponin and calmodulin are induced by each pCa transient. Thus, only sites of the "Ca2+-specific" type can act as rapid Ca2+-regulatory sites in muscle. Fluctuation in the total amount of Ca2+ bound to these sites in response to various types of pCa transients further suggests that in vivo only about one-half to one-third of the total steady-state myofibrillar Ca2+-binding capacity exchanges Ca2+ during any single transient.     

Salt-induced conformational changes in skeletal myosin light chains, troponin-C, and parvalbumin

Evidence for salt-induced changes in myosin light chains [dissociated by treatment with 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB)], troponin-C (TnC), and parvalbumin was obtained from chymotryptic digestion, circular dichroism, fluorescence, and difference absorption studies. High salt (0.6 M NaCl) protects the DTNB light chain from proteolysis, increases its alpha-helical content, and quenches the tryptophan fluorescence. These effects are similar to the changes induced by Ca2+ but smaller in magnitude. TnC is affected by monovalent cations in a similar manner. Changes in the alpha-helical content resemble the effect of Ca2+. The enhancement of tyrosine fluorescence reflects conformational changes in the Ca2+-Mg2+ binding sites. The increase in the fluorescence of dansylaziridine-labeled TnC suggests perturbation of Ca2+-specific sites by salt. Cancellation of this effect by Mg2+ binding to the high-affinity sites is indicative of site-site interactions. In Whiting parvalbumin, salt-induced a perturbation of tryptophan absorption similar in nature to the Ca2+ effect.     

Fluorescence studies of the calcium binding to whiting (Gadus merlangus) parvalbumin

The calcium binding by parvalbumin of whiting (Gadus merlangus) has been studied using tryptophanyl fluorescence characteristics. Titration of Ca2+-free parvalbumin with Ca2+ leads to a very pronounced blue shift, narrowing and intensification of the fluorescence spectrum. These spectral changs proceed in two stages reflecting the existence of at least three forms which can be interpreted as (a) the protein without Ca2+, (b) with one Ca2+ and (c) with two bound Ca2+ ions/molecule. The fluorescence of these forms has been identified and the fluorescence spectra measured at varied Ca2+ concentrations were resolved into three components corresponding to these spectral forms. The dependence of the relative concentration of the three fomrs on Ca2+ concentrations agree well with the two-step binding of Ca2+ to parvalbumin: Protein + Ca in equilibrium K1 protein x Ca; Protein x Ca + Ca in equilibrium K2 Ca x protein x Ca. The equilibrium binding constants K1 and K2 obtained by the computer fit are approximately 5 X 10(8) M-1 and 6 X 10(6) M-1. This scheme and the K1 and K2 value are in a good agreement with the independent experimental data resulting from EGTA titration of Ca2+-saturated parvalbumin and pH titratin of parvalbumin in the presence of EGTA and CA2+.     

Conformational studies on parvalbumins by circular dichroism.

Structural variations of two parvalbumins, Whiting III and Pike III, in various denaturing conditions, have been studied by circular dichroism. CD signals are depressed from 4 urea. For Pike III, acidic pH, sodium dodecyl sulfate or complete removal of Ca2+ show little effect in the far ultraviolet region but rather strong effects in the near ultraviolet. For Whiting III similar results are obtained at acidic pH. Carboxymethylated Whiting III (0.15 Ca2+/mol) shows, on the contrary, decreased CD signals in the far and in the near ultraviolet spectra. Addition of Ca2+ fully restores the native CD spectra in both proteins. Ca2+ binding produces structural modifications which are found to vary according to parvalbumin and which seem in any case different from those described for troponin C.     

Interaction of copper nd zinc cations with calcium-binding proteins

Interactions of the calcium binding proteins, parvalbumin from cod muscles, alpha-lactalbumin from cow milk and calmodulin from bovine brain, with Cu2+ and Zn2+ ions have been studied by intrinsic fluorescence and microcalorimetry methods. It was revealed that parvalbumin binds one Cu2+ ion per molecule with association constant from 10(5) to 10(6) M-1. Zn2+ ions seem to compete for the same site which does not coincide with the two Ca2+ and Mg2+ binding sites. alpha-Lactalbumin contains from 2 to 4 Cu2+ and Zn2+ binding sites, the number and affinities of which depend on Ca2+ concentration. Calmodulin has similar Cu2+ and Zn2+ binding sites. The binding of Cu2+ and Zn2+ ions to parvalbumin and alpha-lactalbumin changes the shape and position of their thermal denaturation transitions. The results obtained together with the literature data show that the ability to interact with Cu2+ and Zn2+ ions is a property inherent to many calcium-binding proteins, which may play a physiological role for some of them.     

Ca2+-dependent regulation of cyclic-AMP phosphodiesterase by parvalbumin.

Carp parvalbumin has been shown to activate rat brain phosphodiesterase in a Ca2+-dependent manner. The concentration of Ca2+ required for half-maximal stimulation is 1.4 X 10(-7) M, whereas rat testis Ca2+-dependent regulator (CDR) of phosphodiesterase required 1.2 X 10(-6) M Ca2+. The difference in the slopes of the two curves demonstrated that the activation induced by parvalbumin was not the result of a small contamination by CDR. In addition, it has been shown that Ca2+ binding to parvalbumin parallels its activation of phosphodiesterase. These data suggest that Ca2+ must bind to a single specific metal binding site before phosphodiesterase can be fully activated.     

Molecular characterization of synaptophysin, a major calcium-binding protein of the synaptic vesicle membrane.

Synaptophysin, a mol. wt 38 000 glycopolypeptide of the synaptic vesicle membrane, was solubilized using Triton X-100 and purified by immunoaffinity or ion-exchange chromatography. From gel permeation and sucrose-density centrifugation in H2O/D2O, a Stokes radius of 7.3 nm, a partial specific volume of 0.830 and a total mol. wt of 119 000 were calculated for the native protein. Cross-linking of synaptic vesicles with glutaraldehyde, dimethylsuberimidate, or Cu2+ -o-phenantroline, resulted in the formation of a mol. wt 76 kd dimer of synaptophysin. Crosslinking of the purified protein in addition produced tri- and tetrameric adducts of the polypeptide. Native synaptophysin thus is a homooligomeric protein. Synaptophysin is N-glycosylated, since cultivation of the rat phaeochromocytoma cell line PC12 in the presence of tunicamycin reduced its mol. wt by about 6 kd. Upon transfer to nitrocellulose and incubation with 45Ca2+, synaptophysin behaved as one of the major calcium-binding proteins of the synaptic vesicle membrane. Pronase treatment of intact synaptic vesicles abolished this 45Ca2+ binding indicating that the Ca2+ binding site of synaptophysin must reside on a cytoplasmic domain of the transmembrane polypeptide. Based on these data, we propose that synaptophysin may play an important role in Ca2+-dependent neurotransmitter release.     

Amino acid sequence of alpha chain of sarcoplasmic calcium binding protein obtained from shrimp tail muscle

The isotypes of sarcoplasmic Ca2+ binding protein (SCP) were purified from shrimp tail muscle. SCP exists in a dimeric form. One sample of shrimp contained only alpha A chain, whereas another contained alpha B and beta chains, and a heterodimer of alpha B beta which was not analyzed precisely. The amino acid sequences of the two alpha chains were determined. The two alpha chains are composed of 190 and 192 amino acid residues, respectively. The sequences of the two alpha chains differed in only four amino acids out of 192 residues. The sequences indicate that the alpha chain has three Ca2+-binding sites which are common to EF-hand type Ca2+-binding protein. In the absence of added Ca2+ and Mg2+, the amounts of bound Ca2+ in alpha A, alpha B, and beta chains were 3.0, 3.3, and 2.4 mol/22,000 g protein, respectively. Thus, it is suggested that all three isotypes of shrimp SCP have three Ca2+-binding sites which have high affinity to Ca2+. The sequence homology of shrimp SCP with other EF-hand type Ca2+-binding proteins is very low. The protein having the greatest homology with this SCP was cod parvalbumin; the sequence homology is 18%.     

Static and kinetic studies on carp muscle parvalbumins

Fluorescence titration and fluorescence stopped-flow studies were performed on carp muscle parvalbumin components 1, 2, 3, and 5 (the latter three components were modified with a SH-directed fluorescent reagent, dansyl-L-cysteine). Apparent binding constants (Kapp) of Ca2+ to these components decrease in the order of component 2 (Kapp = 2.8 +/- 0.9 X 10(8) M-1) greater than component 1 (Kapp = 1.25 +/- 0.25 X 10(8) M-1) greater than component 3 = component 5 (Kapp = 4.0 +/- 0.5 X 10(7) M-1) in 30 mM KCl, 50 mM Na-cacodylate-HCl, pH 7.0 at 20 degrees C. The rate constant of the conformational change of parvalbumin induced by Ca2+ binding or removal decreases in the order of component 2 greater than component 1 greater than component 5 greater than or equal to component 3; that is, component 2 undergoes the fastest conformational change and component 3 the slowest in response to the rapid free Ca2+ concentration ([Ca2+]) change in the protein solution. The fluorescence titration curves and [Ca2+]-dependences of the rate constants are analyzed by a simple two-state model, (partially unfolded state) k1 in equilibrium k2 (folded state). It is shown that the equilibrium constant K = k1/k2 depends on the second power of [Ca2+], the rate constant k1 on the first power of [Ca2+] and k2 on the inverse first power of [Ca2+], respectively.     

Ca2+ bindings of pig cardiac myosin, subfragment-1, and g2 light chain.

Ca2+ binding to pig cardiac myosin, subfragment-1 (S-1), and g2 light chain were investigated by the equilibrium dialysis method. Two different S-1s, one of which can bind Ca2+ and another which cannot, were prepared. In order to calculate the free Ca2+ concentrations adequately, the amounts of Ca2+ included in various chemicals and proteins were measured by atomic absorption spectroscopy. Ca2+ contamination was greatest in KCl among the chemicals tested. In addition, the Ca2+ strongly bound to myosin and S-1 was released in the presence of Mg2+. When Mg2+ was not added, the Ca2+-binding constant of myosin was 4 x 10(5) M-1 and the maximum binding number was 1.8 mol per mol of myosin. Cooperativity between the 2 Ca2+ bindings could not be demonstrated. Mg2+ strongly inhibited the Ca2+ binding: at a free Ca2+ concentration of 1 x 10(-5) M, 1.3 mol Ca2+ was bound to myosin in the absence of Mg2+, but 0.6 and 0.2 mol were bound in the presence of 0.3 and 4.5 mM Mg2+, respectively. The Ca2+-binding constant of S-1, which contained a 15,000 dalton component, was 8.6 x 10(5) M-1, and the maximum binding number was 0.7 mol per mol of S-1. The 15,000 dalton component could be exchanged with extraneous g2. S-1 which lacked the 15,000 component could not bind Ca2+ at free Ca2+ concentrations less than 0.1 mM. The Ca2+ binding to free g2 light chain was about 100 times weaker than the binding to myosin, as indicated previously for skeletal myosin (Okamoto, Y. & Yagi, K. (1976) J. Biochem. 80, 111--120). The Ca2+-binding constant was obtained as 4.1 x 10(3) M-1 in the absence of added Mg2+. Phosphorylation of g2 light chain did not affect the Ca2+ binding to the free g2 light chain or to myosin. Ca2+ binding to cardiac native tropomyosin was also measured.     

Preparation and characterization of the major isotype of parvalbumin from skeletal muscle of the toad (Bufo bufo japonicus)

The major isotype of parvalbumin has been isolated from the skeletal muscle of the toad, Bufo bufo japonicus. Unlike the skeletal muscle of every frog so far examined (Rana esculenta, Rana temporaria, and Rana catesbeiana), which contains two major isotypes of parvalbumins, toad skeletal muscle has been shown to contain only one isotype, but the content of parvalbumin in toad skeletal muscle was similar to the sum of those of the two isotypes in skeletal muscles of frogs. This feature of toad skeletal muscle is advantageous to clarify the physiological role of parvalbumin. The relative molecular mass of toad parvalbumin was estimated to be 12,200 by SDS-polyacrylamide gel electrophoresis. The isoelectric point was determined to be 4.81 by polyacrylamide gel isoelectric focusing. The amino acid composition indicated that toad parvalbumin corresponds to bullfrog (R. catesbeiana) pI 4.97 parvalbumin, showing that toad parvalbumin is genetically an alpha-parvalbumin. It was also revealed by the amino acid composition that toad parvalbumin is distinctly different from any of the parvalbumins from frogs. The ultraviolet spectrum of toad parvalbumin is consistent with its amino acid composition. The ultraviolet difference spectrum of the Ca2+-loaded form vs. the metal-free form indicates that some Phe residues in the toad parvalbumin molecule are affected by a conformational change associated with Ca2+ binding. On electrophoresis in polyacrylamide gel in 14 mM Tris and 90 mM glycine, the metal-free and Mg2+-loaded forms of toad parvalbumin migrated twice as fast as the Ca2+-loaded form.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of cupric ion with parvalbumin.

Cod parvalbumin, a calcium-binding protein, possesses a specific Zn2+ (or Cu2+) binding site per molecule. This work employed fluorescence energy transfer techniques to measure the distance between the Zn2+ (Cu2+) site and the stronger Ca(2+)-binding site in parvalbumin. Specifically, the distance between Tb3+ bound at the Ca2+ site and Co2+ bound to the Zn2+ (Cu2+) binding site was 10.3 +/- 0.9 A. Lastly, the effects of Cu2+ on the physico-chemical properties of parvalbumin were studied by measuring the accessibility of protein thiol groups to 5,5'-dithio bis(2-nitrobenzoic acid) and by its affinity for the fluorescent probe 4,4'-bis[1-(phenylamino)-8-naphthalene sulfonic acid] dipotassium salt. The thiol group accessibility decreased and the affinity to the fluorescent probe increased upon complexation of Cu2+ to the protein. It appears that the binding of Cu2+ converts parvalbumin to an apo-like state.     

Parvalbumin in non-muscle tissues of the rat. Quantitation and immunohistochemical localization

Parvalbumin, a high affinity Ca2+-binding protein, is known to be expressed only in muscles and brain in the rat. We have investigated its distribution and characteristics in other rat tissues by several biochemical and immunohistochemical methods. Evidence for the presence of parvalbumin in teeth, bone, skin, prostate, seminal vesicles, testes, and ovary is given by two-dimensional polyacrylamide gel electrophoresis, immunoblotting ("Western technique") of one-dimensional gels, and its concentration measured by reverse phase high performance liquid chromatography. The distribution within several parvalbumin-positive organs was monitored by the immunohistochemical peroxidase-antiperoxidase method. In teeth, only ameloblasts reacted with anti-rat parvalbumin serum and in bone the calcified extracellular cartilage was the target of the immunoreaction. The panniculus carnosus was the exclusive site of parvalbumin in the skin. Besides the already known parvalbumin distribution in the brain, parvalbumin is also expressed in distinct cell types of the peripheral nervous system. Leydig cells were found to be the only parvalbumin location in testes. These observations lead us to conclude that parvalbumin in contrast to the multifunctional and constitutive calmodulin must function in Ca2+-dependent processes related to specific cell types.     

Interaction of parvalbumin of pike II with calcium and terbium ions

Fluorimetric titrations of parvalbumin II (pI 4.2) of pike (Pike II) with Ca2+ and Tb3+ show the CD and EF binding sites to be non-equivalent. The intrinsic binding constants of the strong and the weak sites obtained for Ca2+ are: KsCa = 1.6.10(8) M-1; KwCa = 6.6.10(5) M-1. Differences of the order of 100% were encountered between the Tb3+ binding constants obtained with four different versions of titration. Their average values are: KsTb = 1.9.10(11) M-1; KwTb = 1.0.10(7) M-1. The distances of the strong and the weak sites from the singular Tyr-48, rs = 9.5 A and r2 = 11.5 A, were derived from F?rster-type energy transfer and proved compatible with the X-ray structure of parvalbumin III (pI 4.2) of carp (CarpIII). From the distances, it is suggested that CD is the strong and EF the weak metal-binding site of PikeII. Tb3+ was shown by CD spectroscopy to have the same structural effect on PikeII as Ca2+. Removal of the metal ions from PikeII results in a decrease of helix content as monitored by CD spectroscopy. This decrease is larger than that in CarpIII. A concomitant decrease of the fluorescence quantum yield at nearly constant decay time is indicative of mainly static quenching, probably by the non-coordinating carboxylate groups. The maximum helix content is almost completely reestablished upon binding of the first metal ion. However, small changes of the energy transfer in PikeII with one terbium ion bound to the strong site indicate fine structural rearrangements of the strong binding site when Ca2+ is bound to the weak one.     

Dinitrophenylation of rabbit skeletal sarcoplasmic reticulum ATPase protein

The ATPase (ATP phosphohydrolase (EC 3.6.1.3)) protein of rabbit skeletal sarcoplasmic reticulum rapidly incorporated three mol of 1-fluoro-2,4-dinitrobenzene per 10(5) g of protein with little change in the Ca2+-dependent ATPase activity. When 2 additional mol of the reagent were bound the Ca2+-dependent ATPase activity was inhibited. The dinitrophenyl group was located mainly in the ATPase protein and a small amount of the label was found in the proteolipid component of the ATPase preparation as judged by dissociation experiments in sodium dodecyl sulfate. Cysteine and tyrosine residues were dinitrophenylated in the modified ATPase protein. Thiolysis of the dinitrophenylated ATPase protein with 2-mercaptoethanol under various conditions did not restore the Ca2+-dependent ATPase activity. Solubilization of the ATPase protein with sodium deoxycholate increased the reactivity of the reagent and the Ca2+-dependent ATPase activity was inhibited to a greater extent. Dinitrophenylation of the ATPase protein was Ca2+-dependent; in the presence of high Ca2+ the incorporation increased by 50% and a large decrease in the Ca2+-ATPase activity was noted. The half-maximal changes for the incorporation of the reagent and the inhibition of the Ca2+-ATPase activity occurred at 3--4 microgram Ca2+-concentration, consistent with the binding of Ca2+ to high affinity sites on the ATPase protein. These results indicate that the ATPase protein as a Ca2+-free and a Ca2+-bound conformation. The reagent, 1-fluoro-2,4-dinitrobenzene reacts differentially and thus characterizes these two conformations.