Mechanism of inhibition of Ca2+-transport activity of sarcoplasmic reticulum Ca2+-ATPase by anisodamine

The mechanism of inhibition of Ca2+-transport activity of rabbit sarcoplasmic reticulum Ca 2+-ATPase (SERCA) by anisodamine (a drug isolated from a medicinal herb Hyoscyamuns niger L) was investigated by using ANS (1-anilino-8-naphthalenesulfonate) fluorescence probe, intrinsic fluorescence quenching and Ca 2+-transport activity assays. The number of ANS binding sites for apo Ca2+-ATPase was determined as 8, using a multiple-identical binding site model. Both anisodamine and Ca2+ at millimolar level enhanced the ANS binding fluorescence intensities. Only anisodamine increased the number of ANS molecules bound by SERCA from 8 to 14. The dissociation constants of ANS to the enzyme without any ligand, with 30 mM anisodamine and with 15 mM Ca 2 were found to be 53.0 microM, 85.0 microM and 50.1 microM, respectively. Both anisodamine and Ca2+ enhanced the ANS binding fluorescenc with apparent dissociation constants of 7.6 mM and 2.3 mM, respectively, at a constant concentration of the enzyme. Binding of anisodamine significantly decreased the binding capacity of Ca2+ with the dissociation constant of 9.5 mM, but binding of Ca2+ had no obvious effect on binding of anisodamine. Intrinsic fluorescence quenching and Ca2+-transport activity assays gave the dissociation constants of anisodamine to SERCA as 9.7 and 5.4 mM, respectively, which were consistent with those obtained from ANS-binding fluorescence changes during titration of SERCA with anisodamine and anisodamine + 15 mM Ca2+, respectively. The results suggest that anisodamine regulates Ca2+-transport activity of the enzyme, by stabilizing the trans-membrane domain in an expanded, inactive conformation, at least at its annular ring region.     

The amino acid sequence of an active site peptide from the H,K-ATPase of gastric mucosa

The gastric H,K-ATPase is an active transport protein that is responsible for the maintenance of a large pH gradient across the secretory canaliculus of the mammalian parietal cell. Acid secretion across these epithelial cell membranes is coupled to the potassium-stimulated hydrolysis of ATP catalyzed by H,K-ATPase, but the mechanism of coupling between ion transport and ATP hydrolysis is unknown. In order to investigate the enzymatic mechanism of this coupling, a peptide derived from the ATP binding site of H,K-ATPase has been purified and its amino acid sequence has been determined. The peptide was identified by the incorporation of a fluorescent probe, fluorescein 5'-isothiocyanate (FITC), into the active site before trypsin digestion of the protein. The labeling of the enzyme by FITC was associated with the irreversible inhibition of enzymatic activity, and both the labeling of the tryptic peptide and inhibition of activity were prevented when the reaction was performed in the presence of ATP. At 100% inhibition of activity, 3.5 +/- 1.6 nmol of FITC were incorporated per mg of protein. The amino acid sequence of the active site peptide is His-Val-Leu-Val-Met-Lys-Gly-Ala-Pro-Glu-Gln-Leu-Ser-Ile-Arg, and FITC reacts with the lysine. This sequence is very similar to sequences of fluorescein-labeled peptides from the ATP binding sites of Na,K-ATPase and Ca2+-ATPase, and suggests that the active site structures of these ion transport ATPases are similar.     

Characterization of Ca2+ interactions with matrix metallopeptidase-12: implications for matrix metallopeptidase regulation

Matrix metallopeptidase-12 (MMP-12) binds three calcium ions and a zinc ion, in addition to the catalytic zinc ion. These ions are thought to have a structural role, stabilizing the active conformation of the enzyme. To characterize the importance of Ca2+ binding for MMP-12 activity and the properties of the different Ca2+ sites, the activity as a function of [Ca2+] and the effect of pH was investigated. The enzymatic activity was directly correlated to calcium binding and a Langmuir isotherm for three binding sites described the activity as a function of [Ca2+]. The affinities for two of the binding sites were quantified at several pH values. At pH 7.5, the KD was 0.1 mM for the high-affinity binding site, 5 mM for the intermediate-affinity binding site and >100 mM for the low-affinity binding site. For all three sites, the affinity for calcium decreased with reduced pH, in accordance with the loss of interactions upon protonation of the calcium-co-ordinating aspartate and glutamate carboxylates at acidic pH. The pKa values of the calcium binding sites with the highest and intermediate affinities were determined to be 4.3 and 6.5 respectively. Optimal pH for catalysis was above 7.5. The low-, intermediate- and high-affinity binding sites were assigned on the basis of analysis of three-dimensional-structures of MMP-12. The strong correlation between MMP-12 activity and calcium binding for the physiologically relevant [Ca2+] and pH ranges studied suggest that Ca2+ may be involved in controlling the activity of MMP-12.     

Mast cell-lysosomal cationic protein interaction: effects of metabolic inhibitors and decay of activated cells on enhanced fluorescence of anilinonaphthalene sulfonate

It has been shown earlier that the interactions of the isolated rat peritoneal mast cells with cationic protein from rabbit neutrophil lysosomes (band 2 protein) can be studied using anilinonaphthalene sulfonate (ANS) as a fluorescent probe. In the present communication, binding of ANS dye to the mast cells interacting of histamine release by metabolic inhibitors was found to have no effect on enhancement of ANS fluorescence. On the other hand, inhibition of histamine release at high concentration of Ca2+ (14.4 mM) was accompanied by the decrease in enhance fluorescence. In the presence of 7.2 mM of Sr2+, the release of histamine was enhanced with small but significant increase in ANS fluorescence. The cells heated to 42 degrees C partially lost their capacity to release histamine without the loss of enhanced fluorescence. The mast cells interacting with B2 at 10 degrees C for various time intervals showed time-dependent loss in histamine releasing capacity with concomitant loss in enhanced fluorescence. These studies suggest that the enhancement of ANS fluorescence is associated with the early events of the cell membrane caused by interaction of B2 with the cells. The extracellular cations significantly influence this early event.     

Binding of ions and hydrophobic probes to alpha-lactalbumin and kappa-casein as determined by analytical affinity chromatography

The technique of analytical affinity chromatography was extended to characterize binding of ions and hydrophobic probes to proteins. Using the immobilized protein mode of chromatography, alpha-lactalbumin and kappa-casein were covalently attached to 200-nm-pore-diameter controlled-pore glass beads and accommodated for high-performance liquid chromatography. The existence of a high affinity binding site (Kdiss = 0.16 microM) (site I) for calcium ion in alpha-lactalbumin was confirmed by chromatography of [45Ca2+]. In addition, chromatography of the hydrophobic probes, 1-(phenylamino)-8-naphthalene-sulfonate (ANS)2 and 4,4'-bis[1-(phenylamino)-8-naphthalenesulfonate (bis-ANS) indicated that Ca2+ bound to a second site (presumably the zinc site or site II) with weaker affinity. Dissociation constants obtained for apo-alpha-lactalbumin were about 80 microM for ANS and 4.7 microM for bis-ANS in the absence of sodium ion. Addition of Ca2+ initially caused a reduction in surface hydrophobicity (lowered affinity for the probe dyes) followed by an increase at higher Ca2+ concentrations (greater than 0.5 mM), suggesting that occupancy of site II restores an apo-like conformation to the protein. Moreover, the effect of Zn2+ was similar to that observed in the higher Ca2+ concentration range, whereas Na+ apparently bound to site I. A calcium binding site of moderate affinity also exists in kappa-casein (Kdiss = 15.6 microM). A cluster of negative charges, probably including the orthophosphate group, most likely comprise this binding site. By preventing self-association, analytical affinity chromatography permits microscale characterization of ligand equilibria in proteins that are unaffected by protein-protein interactions.     

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.     

Different conformation changes induced by calcium and terbium of the porcine intestinal calcium-binding protein

The fluorescence of 1-anilino-8-naphthalenesulfonate (ANS) is progressively enhanced with increasing concentration of it, showing a proportionate blue shift of the emission maximum, by the interaction with the porcine intestinal Ca2+-binding protein (CaBP) in the absence of Ca2+. The apo-CaBP has a single binding site for ANS as determined by the fluorescence change, the apparent dissociation constant (Kd) estimated at 49.1 microM. Addition of Ca2+ or Tb3+ to the ANS-apo-CaBP system is capable of enhancing its fluorescence up to about 2- or 5-fold, respectively, causing further blue shift of the emission maximum. These metal ions do not affect the capacity of ANS binding, but Ca2+ slightly increases the Kd value. Increase of the fluorescence of the ANS-CaBP complex by increasing binding of Ca2+ to it was monophasic, while that with Tb3+ was biphasic, both saturated at the same molar ratio, 2, of added cations to the complex. Biphasic change of response has also been observed in UV absorption of the CaBP with increasing concentration of Tb3+. With a half-saturating concentration of Tb3+, Ca2+ can induce a much higher enhancement of the ANS fluorescence than excess Ca2+ alone. All these results indicate that the CaBP molecule contains a single ANS binding site and the conformation and/or microenvironment surrounding bound ANS of the protein is altered reversibly with binding of Ca2+ or Tb3+ to it and that there are differences between Ca2+- and Tb3+-induced conformation changes around the ANS-binding site and the tyrosine residue of it.     

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.     

Opposite effects of Ca(2+) and GTP binding on tissue transglutaminase tertiary structure

Tissue transglutaminase (tTG) belongs to a class of enzymes that catalyze a cross-linking reaction between proteins or peptides. The protein activity is known to be finely tuned by Ca(2+) and GTP binding. In this study we report the effects of these ligands on the enzyme structure, as revealed by circular dichroism, and steady-state and dynamic fluorescence measurements. We have found that calcium and GTP induced opposite conformational changes at the level of the protein tertiary structure. In particular the metal ions were responsible for a small widening of the protein molecule, as indicated by anisotropy decay measurements and by the binding of a hydrophobic probe such as 1-anilino-8-naphthalenesulfonic acid (ANS). Unlike Ca(2+), the nucleotide binding increased the protein dynamics, reducing its rotational correlation lifetime from 32 to 25 ns, preventing also the binding of ANS into the protein matrix. Unfolding of tTG by guanidinium hydrochloride yielded a three-state denaturation mechanism, involving an intermediate species with the characteristics of the so-called "molten globule" state. The effect of GTP binding (but not that of Ca(2+)) had an important consequence on the stability of tissue transglutaminase, increasing the free energy change from the native to the intermediate species by at least approximately 0.7 kcal/mol. Also a greater stability of tTG to high hydrostatic pressure was obtained in presence of GTP. These findings suggest that the molecular mechanism by which tTG activity is inhibited by GTP is essentially due to a protein conformational change which, decreasing the accessibility of the protein matrix to the solvent, renders more difficult the exposure of the active site.     

Divalent cation-induced changes in conformation of protein kinase C

Using physical techniques, circular dichroism and intrinsic and extrinsic fluorescence, the binding of divalent cations to soluble protein kinase C and their effects on protein conformation were analyzed. The enzyme copurifies with a significant concentration of endogenous Ca2+ as measured by atomic absorption spectrophotometry, however, this Ca2+ was insufficient to support enzyme activity. Intrinsic tryptophan fluorescence quenching occurred upon addition to the soluble enzyme of the divalent cations, Zn2+, Mg2+, Ca2+ or Mn2+, which was irreversible and unaffected by monovalent cations (0.5 M NaCl). Far ultraviolet (200-250 nm) circular dichroism spectra provided estimations of secondary structure and demonstrated that the purified enzyme is rich in alpha-helices (42%) suggesting a rather rigid structure. At Ca2+ or Mg2+ concentrations similar to those used for fluorescence quenching, the enzyme undergoes a conformational transition (42-24% alpha-helix, 31-54% random structures) with no significant change in beta-sheet structures (22-26%). Maximal effects on 1 microM enzyme were obtained at 200 microM Ca2+ or 100 microM Mg2+, the divalent cation binding having a higher affinity for Mg2+ than for Ca2+. The Ca2(+)-induced transition was time-dependent, while Mg2+ effects were immediate. In addition, there was no observed energy transfer for protein kinase C with the fluorescent Ca2(+)-binding site probe, terbium(III). This study suggests that divalent cation-induced changes in soluble protein kinase C structure may be an important step in in vitro analyses that has not yet been detected by standard biochemical enzymatic assays.     

Conformational changes induced by binding of divalent cations to calregulin

Scatchard analysis of equilibrium dialysis studies have revealed that in the presence of 3.0 mM MgCl2 and 150 mM KCl, calregulin has a single binding site for Ca2+ with an apparent dissociation constant (apparent Kd) of 0.05 microM and 14 binding sites for Zn2+ with apparent Kd(Zn2+) of 310 microM. Ca2+ binding to calregulin induces a 5% increase in the intensity of intrinsic fluorescence and a 2-3-nm blue shift in emission maximum. Zn2+ binding to calregulin causes a dose-dependent increase of about 250% in its intrinsic fluorescence intensity and a red shift in the emission maximum of about 11 nm. Half-maximal wavelength shift occurs at 0.4 mol of Zn2+/mol of calregulin, and 100% of the wavelength shift is complete at 2 mol of Zn2+/mol of calregulin. In the presence of Zn2+ and calregulin the fluorescence intensity of the hydrophobic fluorescent probe 8-anilino-1-napthalenesulfonate (ANS) was enhanced 300-400% with a shift in emission maximum from 500 to 480 nm. Half-maximal Zn2+-induced shift in ANS emission maximum occurred at 1.2 mol of Zn2+/mol of calregulin, and 100% of this shift occurred at 6 mol of Zn2+/mol of calregulin. Of 12 cations tested, only Zn2+ and Ca2+ produced changes in calregulin intrinsic fluorescence, and none of these metal ions could inhibit the Zn2+-induced red shift in intrinsic fluorescence emission maximum. Furthermore, none of these cations could inhibit or mimic the Zn2+-induced blue shift in ANS emission maximum. These results suggest that calregulin contains distinct and specific ligand-binding sites for Ca2+ and Zn2+. While Ca2+ binding results in the movement of tryptophan away from the solvent, Zn2+ causes a movement of tryptophan into the solvent and the exposure of a domain with considerable hydrophobic character.     

Amino acid substitutions of the NH2-terminal Ala1 of porcine pancreatic phospholipase A2: a monolayer study

Previously it has been shown that the binding of porcine pancreatic phospholipase A2 to lipid-water interfaces is governed by the pK of the alpha-NH3+ group of the N-terminal alanine. Chemically modified phospholipases A2 in which the N-terminal Ala has been replaced by D-Ala or in which the polypeptide chain has been elongated with DL-Ala no longer display activity toward micellar substrate. The activity of DL-Ala-1-, [D-Ala1]-, and [Gly1]phospholipases A2 on substrate monolayers, which allow a continuous change in the packing density of the lipid molecule, was investigated. At pH 6 [Gly1]phospholipase A2 behaves like the native enzyme on lecithin monolayers. DL-Ala1- and [D-Ala1]phospholipases A2, although they are active in this system, showed a weaker lipid penetration capacity at this pH. Studies on the pH and Ca2+ ion dependency of the pre-steady-state kinetics and of the activity of these radiolabeled proteins showed that [D-Ala1]phospholipase A2 does not possess a second low-affinity site for Ca2+ ions in contrast to the native phospholipase A2. This second low-affinity Ca2+ binding site, which is also absent in [Gly1]phospholipase A2, is induced in the latter enzyme by the presence of lipid-water interfaces.     

The role of aspartic acid-49 in the active site of phospholipase A2. A site-specific mutagenesis study of porcine pancreatic phospholipase A2 and the rationale of the enzymatic activity of [lysine49]phospholipase A2 from Agkistrodon piscivorus piscivorus' venom

In order to probe the role of Asp-49 in the active site of porcine pancreatic phospholipase A2 two mutant proteins were constructed containing either Glu or Lys at position 49. Their enzymatic activities and their affinities for substrate and for Ca2+ ions were examined in comparison with the native enzyme. Enzymatic characterization indicated that the presence of Asp-49 is essential for effective hydrolysis of phospholipids. Conversion of Asp-49 to either Glu or Lys strongly reduces the binding of Ca2+ ions in particular for the lysine mutant but the affinity for substrate analogues is hardly affected. Extensive purification of [Lys49]phospholipase A2 from the venom of Agkistrodon piscivorus piscivorus yielded a protein which was 4000 times less active than the basic [Asp49]phospholipase A2 from this venom. Inhibition studies with p-bromophenacyl bromide showed that this residual activity was due to a small amount of contaminating enzyme and that the Lys-49 homologue itself is inactive. The results obtained both with the porcine pancreatic phospholipase A2 mutants and with the native venom enzymes show that Asp-49 is essential for the catalytic action of phospholipase A2.     

The essentiality of His-47 and the N-terminal region for the binding of 8-anilinonaphthalene-1-sulfonate with Taiwan cobra phospholipase A2

The binding of the apolar fluorescent dye 8-anilinonaphthalene-1-sulfonate (ANS) toNaja naja atra phospholipase A₂ (PLA₂) as well as the enhancement of ANS fluorescence of the PLA₂-ANS complex decreased with increasing pH in a pH range from 3 to 9. These pH-dependent curves can be well interpreted as the perturbation of an ionizable group with pK value of 5.8, which was assigned as His-47 in the active site of PLA₂. The ionizable group with pK 5.8 was no longer observed after methylation of His-47, supporting the idea that thepH dependence of ANS binding arose from an electrostatic interaction between His-47 and the bound ANS. Removal of the N-terminal octapeptide of PLA₂ caused a precipitous drop in the capability of PLA₂ for binding with ANS and enhancing ANS fluorescence, reflecting that the integrity of the N-terminal region was essential for maintaining the hydrophobic character of the ANS-binding site. However, the nonpolarity of the ANS-binding site in the N-terminus-removed derivative was still partially retained at lowpH, but was completely lost at highpH. Evidently, the N-terminal region plays a more crucial role in ANS binding at highpH than at lowpH. These results indicate that hydrophobic interaction as well as electrostatic interaction are involved in the binding of ANS to PLA₂, and that the relative contributions of both interactions in ANS fluorescence enhancement may be different under differentpH.     

Nd3+ and Co2+ binding to sarcoplasmic reticulum CaATPase. An estimation of the distance from the ATP binding site to the high-affinity calcium binding sites

Nd3+ binding to sarcoplasmic reticulum (SR) was detected by inhibition of ATPase activity and directly by a fluorimetric assay. Both methods indicated that Nd3+ inhibited the ATPase activity by binding in the high-affinity Ca2+ binding sites. The stoichiometry of binding was about 11 nmol of Nd3+ bound per mg of SR proteins at pNd = 6.5. At higher [Nd3+], substantial nonspecific binding occurred. The association constant for Nd3+ binding to the high-affinity Ca2+ binding sites was estimated to be near 2 X 10(9) M-1. When the CaATPase was inactivated with fluorescein isothiocyanate (FITC), 5.3 nmol were bound per mg of SR protein. This fluorescent probe is known to bind in the ATP binding site. The stoichiometry of Nd3+ binding to FITC-labeled CaATPase was the same, within experimental error, as to the unlabeled CaATPase. Fluorescence energy transfer between FITC in the ATP site and Nd3+ in the Ca2+ sites was found to be very small. This donor-acceptor pair has a critical distance of 0.93 nm and the distance between the ATP site and the closest Ca2+ was estimated to be greater than 2.1 nm. Parallel measurements with FITC-labeled SR and Co2+, an acceptor with a critical distance 1.2 nm, suggested the ATP and Ca2+ binding sites are greater than 2.6 nm apart.     

Interaction of 8-anilinonaphthalene 1-sulphonate (ANS) and human matrix metalloproteinase 7 (MMP-7) as examined by MMP-7 activity and ANS fluorescence

Human matrix metalloproteinase 7 (MMP-7) is the smallest matrix metalloproteinase. It plays important roles in tumour invasion and metastasis. 8-Anilinonaphthalene 1-sulphonate (ANS) is a fluorescent probe widely used for the analysis of proteins. It emits large fluorescence energy when its anilinonaphthalene group binds with hydrophobic regions of protein. In this study, we analysed the interaction of ANS and MMP-7. At pH 4.5-9.5, ANS inhibited MMP-7 activity in the hydrolysis of (7-methoxycoumarin-4-yl)acetyl-L-Pro-L-Leu-Gly-L-Leu-[N(3)-(2,4-dinitrophenyl)-L-2,3-diaminopropionyl]-L-Ala-L-Arg-NH(2). The inhibition was a non-competitive manner and depended on the time for pre-incubation of ANS and MMP-7. At pH 4.5-9.5, the fluorescence of ANS was not changed by the addition of MMP-7. At pH 3.5, MMP-7 lacked activity, and the fluorescence of ANS was increased by the addition of MMP-7. These results suggest that at pH 4.5-9.5, the sulphonic group of ANS binds with MMP-7 through electrostatic interaction, whereas at pH 3.5, the anilinonaphthalene group of ANS binds with MMP-7 through hydrophobic interaction.     

Membrane-bound forms of Ca2+-dependent protein modulator: Ca2+-dependent and independent binding of modulator protein to the particulate fraction from brain.

Ca2+-dependent binding of modulator protein to the particulate fraction was studied. The particulate fraction from one gram of rat brain bound in a Ca2+-dependent fashion 144 microgram of modulator protein, representing more than one third of the total soluble modulator protein in this tissue. The binding site was present in both the mitochondrial and microsomal fractions, the specific activity of the microsomes being the higher. The binding was reversible with a physiological concentration of Ca2+, and was temperature-dependent, and the site can be saturated with modulator protein (4.5 microgram modulator protein per mg of microsomal protein). Tryptic digestion of the membranes caused complete disappearance of the binding activity, but heat-treatment for 5 min at 70 degrees C caused only 40% loss of activity. The binding site may be a known or unknown enzyme(s), the activity of which is regulated by Ca2+ and modulator. Alternatively, this binding site may be a nonenzymic protein that regulates the concentration of free modulator protein in the cell.     

Tryptophan modification of phospholipase A2 enzymes and presynaptic neurotoxins from snake venoms

Three phospholipases A₂ purified from cobra venoms and two presynaptically acting neurotoxins that exhibit phospholipase A₂ activity were subjected to tryptophan modification with 2-hydroxy-5-nitrobenzyl bromide. Associated with the modification of an increasing number of Trp residues were marked decreases in enzymatic activity and lethality, whereas antigenicity remained unchanged. The degree of exposure of tryptophanyl groups as determined by acrylamide quenching was consistent with the relative reactivity toward 2-hydroxy-5-nitrobenzyl bromide, except for Hemachatushaemachatus phospholipase A₂, which showed unusually high reactivity due to its characteristic dimeric conformation. Difference spectra of Trp-modified derivatives differed from those of their native enzymes by the presence of a new positive perturbation between 350 and 500 nm, with a maximum at 415 nm. Scatchard plots revealed only one type of binding site for Ca²⁺, and the binding abilities of the modified enzymes were not impaired. At pH 8.0, all native enzymes enhanced the emission intensity of 8-anilinonaphthalene sulfonate (ANS) dramatically, and the emission intensity of the ANS-enzyme complex increased or decreased in parallel with increasing concentration of Ca²⁺ for the respective enzyme. The Trp-modified derivatives did not enhance the emission intensity of ANS at all either in the presence or absence of Ca²⁺. By means of tryptophan modification, we were able to infer that the tryptophan residues are in the vicinity of the Ca²⁺ binding site and are directly involved in the binding with ANS. This, together with the suggestion that the hydrophobic pocket that interacts with ANS might be the site of binding of the phospholipase A₂ enzyme with the substrate, suggests that the Trp residues in phospholipase A₂ enzymes and presynaptic toxins are involved in substrate binding.     

Catalytic Ca2+-binding site of pancreatic phospholipase A2: laser-induced Eu3+ luminescence study

7F0----5D0 excitation spectroscopy of Eu3+ has been used to study the catalytic Ca2+-binding site of pancreatic phospholipases A2. Eu3+ binds competitively with Ca2+ to the enzyme with retention of about 5% of the activity found with Ca2+. The dissociation constants for the Eu3+-enzyme complexes of bovine phospholipase A2 and porcine isophospholipase A2 are 0.22 mM and 0.16 mM, respectively. Results obtained with the porcine phospholipase A2 at neutral pH indicate aggregation of this enzyme at protein concentrations above 0.18 mM. The Eu3+ bound at the catalytic site of pancreatic phospholipase A2 is coordinated to four or five water molecules, which, in conjunction with binding constant data, suggests the involvement of two or three protein ligands. Addition of a monomeric substrate analogue to the enzyme-Eu3+ complex results in the loss of an additional water molecule from the first coordination sphere of the bound Eu3+. This result suggests an interaction between the negative charge of the polar head group of the substrate analogue and the Eu3+. Binding of the enzyme-Eu3+ complex to micelles results in a nearly complete dehydration of the Eu3+ bound to the catalytic center. In the phospholipase A2-Eu3+-micelle complex, only one H2O molecule is coordinated to Eu3+. This dehydration at the active site of phospholipase A2 in the protein-lipid complex can be an important reason for the enhanced activity of this enzyme at lipid-water interfaces.     

Tryptophan modification of phospholipase A2 enzymes and presynaptic neurotoxins from snake venoms

Three phospholipases A₂ purified from cobra venoms and two presynaptically acting neurotoxins that exhibit phospholipase A₂ activity were subjected to tryptophan modification with 2-hydroxy-5-nitrobenzyl bromide. Associated with the modification of an increasing number of Trp residues were marked decreases in enzymatic activity and lethality, whereas antigenicity remained unchanged. The degree of exposure of tryptophanyl groups as determined by acrylamide quenching was consistent with the relative reactivity toward 2-hydroxy-5-nitrobenzyl bromide, except for Hemachatushaemachatus phospholipase A₂, which showed unusually high reactivity due to its characteristic dimeric conformation. Difference spectra of Trp-modified derivatives differed from those of their native enzymes by the presence of a new positive perturbation between 350 and 500 nm, with a maximum at 415 nm. Scatchard plots revealed only one type of binding site for Ca²⁺, and the binding abilities of the modified enzymes were not impaired. At pH 8.0, all native enzymes enhanced the emission intensity of 8-anilinonaphthalene sulfonate (ANS) dramatically, and the emission intensity of the ANS-enzyme complex increased or decreased in parallel with increasing concentration of Ca²⁺ for the respective enzyme. The Trp-modified derivatives did not enhance the emission intensity of ANS at all either in the presence or absence of Ca²⁺. By means of tryptophan modification, we were able to infer that the tryptophan residues are in the vicinity of the Ca²⁺ binding site and are directly involved in the binding with ANS. This, together with the suggestion that the hydrophobic pocket that interacts with ANS might be the site of binding of the phospholipase A₂ enzyme with the substrate, suggests that the Trp residues in phospholipase A₂ enzymes and presynaptic toxins are involved in substrate binding.