Activation of the acidic isoform of phospholipase A2 from Naja mossambica mossambica venom by oleoyl imidazolide requires the cooperative action of two ionizing groups

The acidic phospholipase A2 isoform from the spitting cobra Naja mossambica mossambica is activated irreversibly by treatment with a molar equivalent of oleoyl imidazolide. The kinetics of the chemical modification of the enzyme can also be monitored by measuring the large reduction of tryptophan fluorescence, which is accompanied by a distinct red shift. The addition of a single molar equivalent of oleic acid to the enzyme produces an instantaneous reduction in fluorescence but with a barely detectable red shift, confirming that the response to oleoyl imidazolide results from covalent modification of the protein rather than hydrolysis of the reagent. The pH dependence of both activation and fluorescence reduction by oleoyl imidazolide has an optimum rate near pH 8.0. We propose that long-chain fatty acids and long-chain acyl imidazolides bind at a single activation site and that the reaction of the imidazolides involves two protein residues, one of which is a nonessential histidine residue and the other a primary amino group.     

The environment of tryptophan in pig pancreatic phospholipase A2 bound to bilayers

Binding of pig pancreatic phospholipase A2 to ternary codispersions of diacylphosphatidylcholine/lysophosphatidylcholine/fatty acid (100:22:22, mole ratio) is monitored by the increase in intrinsic fluorescence intensity of the single tryptophan residue. The fluorescence is quenched by the brominated fatty acid components in the ternary codispersions. The quenching efficiency is in the order: 11,12-dibromo- greater than 9,10-dibromo- greater than 6,7-dibromo- greater than 2-bromo fatty acid. The quenching efficiency of the 9,10-brominated derivatives of the three components in the ternary codispersions is in the order diacylphosphatidylcholine greater than fatty acid greater than lysophosphatidylcholine. Two isomers of diacylphosphatidylcholine with 9,10-dibromo substituents on chain 1 or 2 are equally efficient quenchers. While succinimide also quenches the fluorescence of the free and the membrane bound enzyme, the tryptophan residue in both systems is not accessible to 1-methylnicotinamide. These results are rationalized by a hypothesis that the acyl chains of the substrate interacts with the tryptophan residue of pig pancreatic phospholipase A2, which is readily accessible to water soluble neutral quenchers both in the free and the bound state.     

Inhibition of phospholipase A2 by cis-unsaturated fatty acids: evidence for the binding of fatty acid to enzyme.

Calcium-dependent phospholipases A2 are markedly inhibited in vitro by cis-unsaturated fatty acids (CUFAs) and to a much lesser extent by trans-unsaturated or saturated fatty acids. Thus, CUFAs may function as endogenous suppressors of lipolysis. To better understand the mechanism of inhibition, kinetic analysis, fluorescence spectroscopy and gel permeation chromatography were employed to demonstrate that CUFAs interact with a highly purified Ca(2+)-dependent phospholipase A2 from Naja mossambica mossambica venom. Arachidonate inhibited hydrolysis of both [1-14C]oleate-labelled, autoclaved Escherichia coli and [1-14C]linoleate-labelled phosphatidylethanolamine in an apparent competitive manner. When subjected to gel permeation chromatography, [3H]arachidonate, but not [3H]palmitate, comigrated with the enzyme. Arachidonic and other CUFAs increased the fluorescence intensity of the enzyme almost 2-fold in a dose-dependent fashion (50 microM = 180% of control); methyl arachidonate was without effect. Saturated fatty acids had only a modest effect on enzyme fluorescence (50 microM = 122% of control). Concentrations of arachidonate that inhibited in vitro enzymatic activity by almost 80% did not alter binding of phospholipase A2 to the E. coli substrate. Collectively, these data demonstrate that, while CUFAs selectively bind to the enzyme, they do not influence phospholipase A2-substrate interaction. Inhibition of in vitro phospholipase A2 activity by CUFAs may be mediated by the formation of an enzymatically inactive enzyme-substrate-inhibitor complex.     

葡萄糖淀粉酶色氨酸残基及底物结合位点的研究

 本文用N-溴代琥珀酰亚胺(NBS)对葡萄糖淀粉酶进行特异性修饰,当酶分子表面有3个色氨酸残基被修饰后,酶活力完全丧失。用邹氏图解法测得酶活性中心有一个色氨酸残基是必需的。如果在酶液中加入不同的底物再用NBS氧化,用荧光发射和荧光猝灭光谱检测表明,底物对酶分子有不同程度的保护作用。在被测试的三种底物中,这种保护能力依为糊精>淀粉>麦芽糖。     

Structural determinants of the intrinsic fluorescence emission in notexin and phospholipase A2 enzymes

Fluorescence measurements of the homologous proteins, notexin and PLA₂ enzymes fromNaja naja atra, Naja nigricollis, and Hemachatus haemachatus venoms, showed that the wavelength of maximum emission and the quantum yield of their intrinsic fluorescence emission spectra were different. To verify the factors which affected their fluorescence characteristics, the dynamics of tryptophan residues in those homologous proteins were studied by quenching with acrylamide, iodide, and cesium. The degrees of exposure of tryptophanyl groups in notexin and PLA₂ enzymes assessed by acrylamide quenching were found to be the major factor that determined their fluorescence characteristics. However, the positively charged groups surrounding tryptophan residues of PLA₂ enzymes fromN. naja atra andN. nigricollis venoms might affect the quantum yield of their fluorophores. Tryptophan residues of notexin were in an environment with less fluctuation, which did not allow free diffusion of ionic quencher. This might render its typtophan residues to fluoresce at a shorter wavelength. These results suggested that the structural determinants affecting the intrinsic fluorescence emission of homologous proteins can be easily assessed by quenching studies.     

Structural determinants of the intrinsic fluorescence emission in notexin and phospholipase A2 enzymes

Fluorescence measurements of the homologous proteins, notexin and PLA₂ enzymes fromNaja naja atra, Naja nigricollis, and Hemachatus haemachatus venoms, showed that the wavelength of maximum emission and the quantum yield of their intrinsic fluorescence emission spectra were different. To verify the factors which affected their fluorescence characteristics, the dynamics of tryptophan residues in those homologous proteins were studied by quenching with acrylamide, iodide, and cesium. The degrees of exposure of tryptophanyl groups in notexin and PLA₂ enzymes assessed by acrylamide quenching were found to be the major factor that determined their fluorescence characteristics. However, the positively charged groups surrounding tryptophan residues of PLA₂ enzymes fromN. naja atra andN. nigricollis venoms might affect the quantum yield of their fluorophores. Tryptophan residues of notexin were in an environment with less fluctuation, which did not allow free diffusion of ionic quencher. This might render its typtophan residues to fluoresce at a shorter wavelength. These results suggested that the structural determinants affecting the intrinsic fluorescence emission of homologous proteins can be easily assessed by quenching studies.     

Activation of bee venom phospholipase A2 by oleoyl imidazolide produces a thiol- and proteinase-resistant conformation

Assay methods for bee venom phospholipase A2 are presented which respond to different aspects of enzymic behaviour and which allow basal activity, fatty acid activation and acyl-group activation to be distinguished. The stability of the enzyme to thiols and proteinases is dramatically increased by activation with the selective acylating agent, oleoyl imidazolide. These results support the model of activation by conformation change. Limited-fixation studies indicate that enzyme conformation is determined by interaction with the substrate. The oleoyl-enzyme is partially inactivated by trypsin, but its electrophoretic mobility is unchanged. This protective effect is highly selective and only one other component of the venom is protected against trypsin by oleoyl imidazolide. Combination of trypsin and thiol treatment produces a large fragment of the activated enzyme which could be used for structural studies of the activation site.     

Tryptophan residue essential for activity of Naja naja atra phospholipase A2

When Naja naja atra phospholipase A2, which contains three tryptophan residues at the 18th, 19th, and 61st positions, was oxidized with N-bromosuccinimide at pH 4.0, its activity decreased in a convex manner with increase in the extent of oxidation of tryptophan residues. The curve shape showed that the tryptophan residue oxidized last is most responsible for the activity. The order of accessibilities of the three tryptophan residues, which was analyzed according to the method reported previously (Mohri et al. (1876) J. Biochem. 100, 883-893), was Trp-61 greater than Trp-19 greater than Trp-18. Thus, Trp-18 was evaluated to be essential for activity. Difference spectra of phospholipase A2 produced by titrating with laurylphosphorylcholine in the presence of Ca2+, which are due in large part to perturbation of the tryptophan residue(s), were retained with phospholipase A2 derivatives containing 1.2 and 2.0 mol of tryptophan residues oxidized but not with the derivative containing 3.0 mol of tryptophan residues oxidized. Such observations led us to assume that Trp-18 is involved in the specific site that interacts with phospholipid.     

Effect of phosphate ions on the fluorescence of tryptophan derivatives. Implications in fluorescence investigation of protein-nucleic acid complexes

In order to test the ability of phosphate groups to quench the fluorescence of tryptophan in protein-nucleic acid complexes we have studied the effect of various phosphate ions on the fluorescence of tryptophan derivatives. Unsubstituted and monoalkyl monoanions (H2PO4- and CH3OPO3H-) quench the fluorescence of all investigated indole derivatives while the dimethyl anion (CH3O)2 PO2- does not. This suggests that quenching of tryptophan fluorescence by phosphate monoanions requires the presence of an acidic OH group and could be due to a proton transfer from the phosphate ion to the indole chromophore. Trianions (PO4 3-4) which are strong proton acceptors quench the fluorescence of all tryptophan derivatives except N(1)methyl tryptophan. This result strongly supports our proposal that quenching of tryptophan fluorescence by phosphate trianions occurs through deprotonation of the NH indole group. Bianions (HPO '4(7), and CH3O PO3 2-3) quench the fluorescence of several indole derivatives including N-acetyl tryptophanamide but have no effect on tryptophan or N(1)-methyl tryptophan. From our results we conclude that phosphate groups of nucleic acids are not able to quench the fluorescence of tryptophyl residues in protein-nucleic acid complexes except if an accessible residue is located near a phosphorylated polynucleotide chain end.     

Decay-associated fluorescence spectra and the heterogeneous emission of alcohol dehydrogenase

A procedure is described for using nanosecond time resolved fluorescence decay data to obtain decay-associated fluorescence spectra. It is demonstrated that the individual fluorescence spectra of two or more components in a mixture can be extracted without prior knowledge of their spectral shapes or degree of overlap. The procedure is also of value for eliminating scattered light artifacts in the fluorescence spectra of turbid samples. The method was used to separate the overlapping emission spectra of the two tryptophan residues in horse liver alcohol dehydrogenase. Formation of a ternary complex between the enzyme, NAD+, and pyrazole leads to a decrease in the total tryptophan fluorescence. It is shown that the emission of both tryptophan residues decreases. The buried tryptophan (residue 314) undergoes dynamic quenching with no change in the spectral distribution. Under the same conditions, the fluorescence intensity of tryptophan (residue 15) decreases without a change in decay time but with a red shift of the emission spectrum. There is also a decrease in tryptophan fluorescence intensity when the free enzyme is acid denatured (succinate buffer, pH 4.1). The denatured enzyme retains sufficient structure to provide different microenvironments for different tryptophan residues as reflected by biexponential decay and spectrally shifted emission spectra (revealed by decay association). The value of this technique for studies of microheterogeneity in biological macromolecules is discussed.     

On the inhibition of [Na+,K+]-ATPases by the components of Naja mossambica mossambica venom: evidence for two distinct rat brain [Na+,K+]-ATPase activities

We have compared the effects of highly purified preparations of cardiotoxins and phospholipases A2 from Naja mossambica mossambica venom on rat brain [Na+,K+]-ATPase activity. The results were the following: (i) micromolar concentrations of cardiotoxin preparations were required to inhibit [Na+,K+]-ATPase activity to the extent achieved by picomolar concentrations of phospholipases A2; i.e., the inhibitory effect of cardiotoxins appeared to be related to the contamination of the preparations by trace amounts of phospholipase A2; (ii) comparing phospholipases A2 from varied origins, a correlation was observed between [Na+,K+]-ATPase inhibition, isoelectric point, and toxicity for mice; (iii) when rat brain membranes were used, incubation for extended times with the most basic N. mossambica mossambica phospholipase A2 resulted in a biphasic [Na+,K+]-ATPase inhibition, suggesting that two distinct [Na+,K+]-ATPases were affected differentially. In contrast, incubation of rat brain membranes with either porcine pancreatic phospholipase A2, notexin, or beta-bungarotoxin and also incubation of erythrocyte membranes with the most basic N. mossambica mossambica phospholipase A2 produced monophasic [Na+,K+]-ATPase inhibitions. We discuss a possible specific action of toxic, basic phospholipase A2 on one of the [Na+,K+]-ATPase isoforms of excitable membranes.     

The chemical modification of the essential groups of beta-N-acetyl-D-glucosaminidase from Turbo cornutus Solander

The chemical modification of beta-N-acetyl-D-glucosaminidase (EC3.2.1.30) from Turbo cornutus Solander has been first studied. The results demonstrate that the sulfhydryl group of cysteine residues and the hydroxyl group of serine residues are not essential to the enzyme's function. The modification of indole group of tryptophan of the enzyme by N-bromosuccinimide (NBS) can lead to the complete inactivation, accompanying the absorption decreasing at 278 nm and the fluorescence intensity quenching at 335 nm, indicating that tryptophan is essential residue to the enzyme. The modification of amino group of lysine residue by formaldehyde and trinitrobenzenesulfonic acid also inactivates the enzyme completely. The results show that lysine and tryptophan are probably situated in the active site of the enzyme. The modification of the imidazole residue and carboxyl group leads to inactivate incompletely, indicating they are not the composing groups of the enzyme active center, and they are essential for maintaining the enzyme's conformation which is necessary for the catalytic activity of the enzyme.     

Probing the role of C-1 ester group in Naja naja phospholipase A2-phospholipid interactions using butanetriol-containing phosphatidylcholine analogues.

To understand the role of the ester moiety of the sn-1 acyl chain in phospholipase A2-glycerophospholipid interactions, we introduced an additional methylene residue between the glycerol C1 and C2 carbon atoms of phosphatidylcholines, and then studied the kinetics of hydrolysis and the binding of such butanetriol-containing phospholipids with Naja naja phospholipase A2. Hydrolysis was monitored by using phospholipids containing a NBD-labelled sn-2 acyl chain and binding was ascertained by measuring the protein tryptophan fluorescence. The hydrolysis of butanetriol-containing phospholipids was invariably slower than that of the glycerol-containing phospholipids. In addition, the enzyme binding with the substrate was markedly decreased upon replacing the glycerol residue with the 1,3,4-butanetriol moiety in phosphatidylcholines. These results have been interpreted to suggest that the sn-1 ester group in glycerophospholipids could play an important role in phospholipase A2-phospholipid interactions.     

Ca2+ binding effects on the C2 domain conformation of human cytosolic phospholipase A2

It has been reported that the cooperative binding of calcium ions indicated a local conformational change of the human cytosolic phospholipase A2 (cPLA2) C2 domain (Nalefski et al., (1997) Biochemistry 36, 12011-12018). However its structural evidence is less known (Malmberg et al., (2003) Biochemistry 42, 13227-13240). In this letter, life-time decay and fluorescence quenching techniques were employed to compare the calcium-induced conformational changes. The life-time decay parameters and fluorescence quenching constant changes were small between the apo- and holo-C2 domains when tryptophan residue was excited at 295 nm. In contrast, the quenching constant change was large, from 0.52 M(-1) for the apo-C2 to 8.8 M(-1) for the holo-C2 domain, when tyrosine residues were excited at 284 nm. Our results provide new information on amino acid side chain orientation change at calcium binding loop 3, which is necessary for Ca2+ binding regulated membrane targeting of human cytosolic phospholipase A2.     

Conformational changes of maize and wheat NADP-malic enzyme studied by quenching of protein native fluorescence

Quenching of tryptophan fluorescence of maize and wheat NADP-malic enzyme by KI and acrylamide was studied after denaturating proteins with guanidine hydrochloride, and subjecting them to different pH values or temperatures. Protein unfolding by guanidine hydrochloride resulted in a red shift of the fluorescence spectrum, providing further support for the motion that several of the tryptophan residues evolved from an apolar to a polar environment. Protein denaturation was accompanied by an increase in the effective dynamic quenching constant values and by loss of the enzyme's activities. Thermal denaturation gave results consistent with the ones observed for chemical denaturation suggesting that a putative intermediate is involved in the denaturation process. Finally, exposure of both enzymes at various pH values allowed us to infer the number of accessible tryptophan residues in the different oligomeric conformations. The results suggest that the aggregation process seems to be different for each enzyme. Thus, as the maize enzyme associated from monomer to tetramer, one tryptophan residue would change from a polar to an apolar environment, while the association of the wheat enzyme would cause that two tryptophan residues to be excluded from quenching. Hitherto, quenching of the tryptophan fluorescence provides a good tool for studying conformational changes of proteins. The future availability of the crystal structures of plant NADP-malic enzymes will offer a good validation point for our model and the technology used.     

Chemical, photochemical and spectroscopic characterization of an alkaline proteinase from Bacillus subtilis variant DY

Circular-dichroism and fluorescence studies indicate that the 5-dimethylaminonaphthalene-1-sulphonyl and phenylmethanesulphonyl derivatives of subtilisin DY have three-dimensional structure closely similar to that of native enzyme. The single tryptophan residue is largely accessible to the aqueous solvent, and is not directly involved in the enzyme-substrate interactions, since its photochemical modification causes only a partial inhibition of the enzyme activity. It appears very likely that the location of the single tryptophan residue in the three-dimensional structure of subtilisin DY is similar to that of the single tryptophan residue in subtilisin Carlsberg. Fluorescence-quenching experiments further indicate that the 14 tyrosine residues are also largely accessible to the aqueous solvent, and probably interact with hydrated peptide carbonyl groups. The charge environment for tryptophan and tyrosine residues in subtilisin DY, as deduced by quenching experiments with ionic species, is also discussed. In general, subtilisin DY displays strong similarities to subtilisin Carlsberg, as suggested by a comparative analysis of the amino acid composition and fluorescence properties.     

Fluorescence quenching of human orosomucoid. Accessibility to drugs and small quenching agents.

The fluorescence behaviour of human orosomucoid was investigated. The intrinsic fluorescence was more accessible to acrylamide than to the slightly larger succinimide, indicating limited accessibility to part of the tryptophan population. Although I- showed almost no quenching, that of Cs+ was enhanced, and suggested a region of negative charge proximal to an emitting tryptophan residue. Removal of more than 90% of sialic acid from the glycan chains led to no change in the Cs+, I-, succinimide or acrylamide quenching, indicating that the negatively charged region originates with the protein core. Quenching as a function of pH and temperature supported this view. The binding of chlorpromazine monitored by fluorescence quenching, in the presence and in the absence of the small quenching probes (above), led to a model of its binding domain on orosomucoid that includes two tryptophan residues relatively shielded from the bulk solvent, with the third tryptophan residue being on the periphery of the domain, or affected allotopically and near the negatively charged field.     

Fluorescence of human liver alanine aminopeptidase.

Fluorescence of human liver alanine aminopeptidase has been attributed to tryptophan fluorescence. The fluorescence maximum is at 330 nm, 20 nm lower than that for free tryptophan, suggesting that most of the enzyme tryptophans are in a nonpolar environment and are shielded from solvent. Quenching of enzyme fluorescence by iodide, pyridine, and N-methyl nicotinamide also demonstrates that enzyme tryptophan residues are largely buried and inaccessible to solvent. Those accessible are in negatively charged environments. 8-(1'-dimethylaminonaphthalene-5'-sulfonylamido-octanoic acid (8-DNS-octanoic acid) and epsilon-DNS-L-Lys inhibit aminopeptidase. One molecule of inhibitor when bound to the enzyme quenched 57% and 63% of enzyme fluorescence, respectively. Such efficient quenching may indicate a degree of segregation of tryptophan toward the active center.     

Detection, characterization, and quenching of the intrinsic fluorescence of bovine heart cytochrome c oxidase

The intrinsic fluorescence of lauryl maltoside solubilized bovine heart cytochrome c oxidase has been determined to arise from tryptophan residues of the oxidase complex. The magnitude of the fluorescence is approximately 34% of that from n-acetyltryptophanamide (NATA). This level of fluorescence is consistent with an average heme to tryptophan distance of 30 A. The majority of the fluorescent tryptophan residues are in a hydrophobic environment as indicated by the fluorescence emission maximum at 328 nm and the differing effectiveness of the quenching agents: Cs+, I-, and acrylamide. Cesium was ineffective up to a concentration of 0.7 M, whereas quenching by the other surface quenching agent, iodide, was complex. Below 0.2 M, KI was ineffective whereas between 0.2 and 0.7 M 15% of the tryptophan fluorescence was found to be accessible to iodide. This pattern indicates that protein structural changes were induced by iodide and may be related to the chaotropic character of KI. Acrylamide was moderately effective as a quenching agent of the oxidase fluorescence with a Stern-Volmer constant of 2 M-1 compared with acrylamide quenching of NATA and the water-soluble enzyme aldolase having Stern-Volmer constants of 12 M-1 and 0.3 M-1, respectively. There was no effect of cytochrome c on the tryptophan emission intensity from cytochrome c oxidase under conditions where the two proteins form a tight, 1:1 complex, implying that the tryptophan residues near the cytochrome c binding site are already quenched by energy transfer to the homes of the oxidase. The lauryl maltoside concentration used to solubilize the enzyme did not affect the fluorescence of NATA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification and properties of the covalently bound flavin of beta-cyclopiazonate oxidocyclase.

Beta-Cyclopiazonate oxidocyclase from Penicillium cyclopium has been previously shown to contain flavin dinucleotide in covalent linkage to the protein. In the present study, a pure flavin mononucleotide peptide was isolated from the enzyme by tryptic-chymotryptic digestion, chromatography on Florisil and on diethylaminoethylcellulose, and hydrolysis with nucleotide pyrophosphatase. The flavin peptide contains 9 amino acids, including histidine in linkage to the flavin, and Asx as the N-terminal residue. The fluorescence of the flavin in the FMN peptide is profoundly quenched even at pH 3.2, where protonation of the imidazole prevents queching of the flavin fluorescence by histidine. This quenching appears to be due to interaction of the flavin with a tryptophan residue, as the quenching is abolished by oxidation of the tryptophan with performic acid. Similarly, the fluorescence of the tryptophan in the peptide is quenched, presumably by the flavin. The flavin of beta-cyclopiazonate oxidocylcase is attached, by the way of the 8alpha-methylene group, to the imidazole ring of a histidine. The aminoacylflavin isolated from the enzyme is identical in the pKa of its imidazole group, in reduction by NaBH4, and in other properties with synthetic 8alpha-(N1-histidyl)riboflavin. The pKa of the histidylriboflavin component of the oxidocyclase is 5.2 before and 5.0 after acid modification of the ribityl chain, as is found in the synthetic derivative. It is concluded that the enzyme contains the N1 isomer of histidylriboflavin and that acid hydrolysis of flavin peptides isolated from the oxidocyclase, while liberating histidylriboflavin, also causes acid modification of the ribityl chain of the flavin moiety.