Synthesis and biological evaluation of a phosphonate analog of the natural acetyl cholinesterase inhibitor cyclophostin

Two diastereomers of a phosphonate analog 6 of the AChE inhibitor cyclophostin were synthesized. The substitution reaction of phosphono allylic carbonate 10a with methyl acetoacetate gave the vinyl phosphonate 9a. Attempted hydrogenation/debenzylation gave an unexpected enolether lactone. Alternatively, selective hydrogenation, demethylation, cyclization and debenzylation gave the phosphonate analog of cyclophostin as a separable mixture of diastereomers 6. The trans phosphonate isomer was more active than the cis isomer against AChE from two sources.

Roles of metal ions in nucleases

The hydrolysis of phosphodiester bonds by metallonucleases is crucial to most aspects of nucleic acid processing. In recent years, studies of the classical restriction endonucleases have given way to the characterization of metallonucleases with widely divergent active site motifs. These developments fuel debates regarding the roles of metal ions in these enzymes. It is fortuitous that the current literature also includes the increased application of a variety of computational techniques to test the roles of metal ions in nucleic acid hydrolysis by these systems. This includes recent proposals and indirect evidence that these enzymes utilize metal ion movement in these reactions.

Uncoupling metallonuclease metal ion binding sites via nudge mutagenesis

The hydrolysis of phosphodiester bonds by nucleases is critical to nucleic acid processing. Many nucleases utilize metal ion cofactors, and for a number of these enzymes two active-site metal ions have been detected. Testing proposed mechanistic roles for individual bound metal ions has been hampered by the similarity between the sites and cooperative behavior. In the homodimeric PvuII restriction endonuclease, the metal ion dependence of DNA binding is sigmoidal and consistent with two classes of coupled metal ion binding sites. We reasoned that a conservative active-site mutation would perturb the ligand field sufficiently to observe the titration of individual metal ion binding sites without significantly disturbing enzyme function. Indeed, mutation of a Tyr residue 5.5 A from both metal ions in the enzyme-substrate crystal structure (Y94F) renders the metal ion dependence of DNA binding biphasic: two classes of metal ion binding sites become distinct in the presence of DNA. The perturbation in metal ion coordination is supported by 1H-15N heteronuclear single quantum coherence spectra of enzyme-Ca(II) and enzyme-Ca(II)-DNA complexes. Metal ion binding by free Y94F is basically unperturbed: through multiple experiments with different metal ions, the data are consistent with two alkaline earth metal ion binding sites per subunit of low millimolar affinity, behavior which is very similar to that of the wild type. The results presented here indicate a role for the hydroxyl group of Tyr94 in the coupling of metal ion binding sites in the presence of DNA. Its removal causes the affinities for the two metal ion binding sites to be resolved in the presence of substrate. Such tuning of metal ion affinities will be invaluable to efforts to ascertain the contributions of individual bound metal ions to metallonuclease function.

Unique 31P spectral response to the formation of a specific restriction enzyme-DNA complex

Protein-induced distortion is a dramatic but not universally observed feature of sequence-specific DNA interactions. This is illustrated by the crystal structures of restriction enzyme-DNA complexes: While some of these structures exhibit DNA distortion, others do not. Among the latter is Pvull endonuclease, a small enzyme that is also amenable to NMR spectroscopic studies. Here 31P NMR spectroscopy is applied to demonstrate the unique spectral response of DNA to sequence-specific protein interactions. The 31P NMR spectrum of a noncognate DNA exhibits only spectral broadening upon the addition of enzyme. However, when enzyme is added to target DNA, a number of 31P resonances shift dramatically. The magnitudes of the chemical shifts (2-3 ppm) are among the largest observed. Site-specific substitution with phosphoramidates and phosphorothioates are used analyze these effects. While such spectral features have been interpreted as indicative of DNA backbone distortions, FRET analysis indicates that this does not occur in PvuII-cognate DNA complexes in solution. The distinct 31P spectral signature observed for cognate DNA mirrors that observed for the enzyme, underscoring the unique features of cognate complex formation.

NMR Studies of Restriction Enzyme−DNA Interactions: Role of Conformation in Sequence Specificity

Sequence specific DNA binding proteins are thought to adopt distinct conformations when binding to target (cognate) and nontarget (noncognate) sequences. There is both biochemical and crystallographic evidence that this behavior is important in mediating sequence recognition by the Mg(II)-dependent type II restriction enzymes. Despite this, there are few systematic comparisons of the structural behavior of these enzymes in various complexes. Here, (1)H-(15)N HSQC NMR spectroscopy is applied to PvuII endonuclease (2 x 18 kDa) in an effort to better understand the relationship between sequence recognition and enzyme conformational behavior. Spectra of the free enzyme collected in the absence and presence of metal ions indicate that while there is a modest backbone conformational response upon binding Ca(II), this does not occur with Mg(II). Substrate binding itself is accompanied by very dramatic spectral changes consistent with a large-scale conformational response. HSQC spectra of the enzyme bound to cognate (specific) and noncognate (nonspecific) oligonucleotides in the presence of Ca(II) are dramatically distinct, revealing for the first time the structural uniqueness of a PvuII cognate complex in solution. The strong correlation between NMR spectral overlap and crystallographic data (C(alpha) rmsd) permits characterization of the nonspecific PvuII complex as being more similar to the free enzyme than to the specific complex. Collectively, these data support the notion that it is the DNA, not the metal ion, which promotes a unique conformational response by the enzyme. It therefore follows that the principle role of metal ions in complex formation is one of driving substrate affinity and stability rather than conformationally priming the enzyme for substrate binding and sequence recognition. These results not only provide valuable insights into the mechanism of protein-DNA interactions but also demonstrate the utility of NMR spectroscopy in structure-function studies of these representative nucleic acid systems.

Lanthanide spectroscopic studies of the dinuclear and Mg(II)-dependent PvuII restriction endonuclease

Type II restriction enzymes are homodimeric systems that bind four to eight base pair palindromic recognition sequences of DNA and catalyze metal ion-dependent phosphodiester cleavage. While Mg(II) is required for cleavage in these enzymes, in some systems Ca(II) promotes avid substrate binding and sequence discrimination. These properties make them useful model systems for understanding the roles of alkaline earth metal ions in nucleic acid processing. We have previously shown that two Ca(II) ions stimulate DNA binding by PvuII endonuclease and that the trivalent lanthanide ions Tb(III) and Eu(III) support subnanomolar DNA binding in this system. Here we capitalize on this behavior, employing a unique combination of luminescence spectroscopy and DNA binding assays to characterize Ln(III) binding behavior by this enzyme. Upon excitation of tyrosine residues, the emissions of both Tb(III) and Eu(III) are enhanced severalfold. This enhancement is reduced by the addition of a large excess of Ca(II), indicating that these ions bind in the active site. Poor enhancements and affinities in the presence of the active site variant E68A indicate that Glu68 is an important Ln(III) ligand, similar to that observed with Ca(II), Mg(II), and Mn(II). At low micromolar Eu(III) concentrations in the presence of enzyme (10-20 microM), Eu(III) excitation (7)F(0) --> (5)D(0) spectra yield one dominant peak at 579.2 nm. A second, smaller peak at 579.4 nm is apparent at high Eu(III) concentrations (150 microM). Titration data for both Tb(III) and Eu(III) fit well to a two-site model featuring a strong site (K(d) = 1-3 microM) and a much weaker site (K(d) approximately 100-200 microM). Experiments with the E68A variant indicate that the Glu68 side chain is not required for the binding of this second Ln(III) equivalent; however, the dramatic increase in DNA binding affinity around 100 microM Ln(III) for the wild-type enzyme and metal-enhanced substrate affinity for E68A are consistent with functional relevance for this weaker site. This discrimination of sites should make it possible to use lanthanide substitution and lanthanide spectroscopy to probe individual metal ion binding sites, thus adding an important tool to the study of restriction enzyme structure and function.

Binding and conformational analysis of phosphoramidate-restriction enzyme interactions

Phosphoramidates are modified deoxyoligonucleotides that feature nitrogen in place of the 3'-oxygen of a phosphodiester linkage. Noted for stability against nuclease activity, these linkages are of both mechanistic and therapeutic interest. While a number of studies characterizing the properties of oligonucleotides composed entirely of phosphoramidate linkages have been published, little is known about how singly substituted phosphoramidate substitutions affect the thermodynamics and structure of protein-oligonucleotide interactions. We chose to investigate these interactions with PvuII endonuclease, the DNA binding behavior of which is well-characterized. Oligonucleotide duplexes containing a phosphoramidate substitution at the scissile phosphates were resistant to cleavage by the enzyme, even after extended incubations. However, the enzyme was able to cleave the native strand in a native:phosphoramidate heteroduplex at a rate comparable to that observed with the native substrate. Ca(II)-stimulated PvuII binding for a phosphoramidate-substituted oligonucleotide is comparable to that of the native duplex (K(d) approximately 200 pM). K(d) values obtained in the presence of Mg(II) are somewhat weaker (K(d) approximately 10 nM). Under metal-free conditions, the enzyme exhibited a remarkable approximately 50-fold greater affinity for the modified oligonucleotide relative to the native substrate (5 vs 240 nM). While (31)P NMR spectra indicate increased chemical shift dispersion in the free phosphoramidate duplex, the spectrum of the enzyme-bound duplex is similar to that of the native duplex. (1)H-(15)N HSQC analysis indicates that enzyme conformations in the presence of these oligonucleotides are also comparable. The tight binding of the phosphoramidate duplex under metal-free conditions and its resistance to cleavage are attributed to local conformational adjustments propagating from the O-->N substitution.

Investigation of restriction enzyme cofactor requirements: a relationship between metal ion properties and sequence specificity

Restriction enzymes are important model systems for understanding the mechanistic contributions of metal ions to nuclease activity. These systems are unique in that they combine distinct functions which have been shown to depend on metal ions: high-affinity DNA binding, sequence-specific recognition of DNA, and Mg(II)-dependent phosphodiester cleavage. While Ca(II) and Mn(II) are commonly used to promote DNA binding and cleavage, respectively, the metal ion properties that are critical to the support of these functions are not clear. To address this question, we assessed the abilities of a series of metal ions to promote DNA binding, sequence specificity, and cleavage in the representative PvuII endonuclease. Among the metal ions tested [Ca(II), Sr(II), Ba(II), Eu(III), Tb(III), Cd(II), Mn(II), Co(II), and Zn(II)], only Mn(II) and Co(II) were similar enough to Mg(II) to support detectable cleavage activity. Interestingly, cofactor requirements for the support of DNA binding are much more permissive; the survey of DNA binding cofactors indicated that Cd(II) and the heavier and larger alkaline earth metal ions Sr(II) and Ba(II) were effective cofactors, stimulating DNA binding affinity 20-200-fold. Impressively, the trivalent lanthanides Tb(III) and Eu(III) promoted DNA binding as efficiently as Ca(II), corresponding to an increase in affinity over 1000-fold higher than that observed under metal-free conditions. The trend for DNA binding affinity supported by these ions suggests that ionic radius and charge are not critical to the promotion of DNA binding. To examine the role of metal ions in sequence discrimination, we determined specificity factors [K(a)(specific)/K(a)(nonspecific)] in the presence of Cd(II), Ba(II), and Tb(III). Most interestingly, all of these ions compromised sequence specificity to some degree compared to Ca(II), by either increased affinity for a noncognate sequence, decreased affinity for the cognate sequence, or both. These results suggest that while amino acid-base contacts are important for specificity, the properties of metal ion cofactors at the catalytic site are also critical for sequence discrimination. This insight is invaluable to our efforts to understand and subsequently design sequence-specific nucleases.

Multiple metal ions drive DNA association by PvuII endonuclease

Restriction enzymes serve as important model systems for understanding the role of metal ions in phosphodiester hydrolysis. To this end, a number of laboratories have reported dramatic differences between the metal ion-dependent and metal ion-independent DNA binding behaviors of these systems. In an effort to illuminate the underlying mechanistic details which give rise to these differences, we have quantitatively dissected these equilibrium behaviors into component association and dissociation rates for the representative PvuII endonuclease and use these data to assess the stoichiometry of metal ion involvement in the binding process. The dependence of PvuII cognate DNA on Ca(II) concentration binding appears to be cooperative, exhibiting half-saturation at 0.6 mM metal ion and yielding an n(H) of 3.5 +/- 0.2 per enzyme homodimer. Using both nitrocellulose filter binding and fluorescence assays, we observe that the cognate DNA dissociation rate (k(-)(1) or k(off)) is very slow (10(-)(3) s(-)(1)) and exhibits a shallow dependence on metal ion concentration. DNA trap cleavage experiments with Mg(II) confirm the general irreversibility of DNA binding relative to cleavage, even at low metal ion concentrations. More dramatically, the association rate (k(1) or k(on)) also appears to be cooperative, increasing more than 100-fold between 0.2 and 10 mM Ca(II), with an optimum value of 2.7 x 10(7) M(-)(1) s (-)(1). Hill analysis of the metal ion dependence of k(on) indicates an n(H) of 3.6 +/- 0.2 per enzyme dimer. This value is consistent with the involvement in DNA association of two metal ions per subunit active site, a result which lends new strength to arguments for two-metal ion mechanisms in restriction enzymes.

Dissecting the metal ion dependence of DNA binding by PvuII endonuclease

Divalent cations can provide an effective means of modulating the behavior of nucleic acid binding proteins. As a result, there is strong interest in understanding the role of metal ions in the function of both nucleic acid binding proteins and their enzymes. We have applied complementary fluorescence spectroscopic and nitrocellulose filter binding assays to quantitate the role of metal ions in mediating DNA binding and sequence specificity by the representative PvuII endonuclease. At pH 7.5 in the presence of the catalytically nonsupportive Ca(II), this enzyme binds the PvuII target sequence with a K(d) of 50 pM. Under strict metal-free conditions, the enzyme exhibits a K(d) of only 300 nM for the cognate sequence, an affinity which is weak relative to those measured for other systems in the absence of metal ions. This represents a 6000-fold increase in PvuII affinity for cognate DNA upon the addition of Ca(II). The pH dependences of both metal ion-dependent and metal ion-independent DNA binding are remarkably shallow throughout the physiological range; other characterized restriction enzymes exhibit more pronounced pH dependences of DNA binding even in the absence of metal ions. Similar measurements with noncognate sequences indicate that divalent metal ions are not important to nonspecific DNA binding; K(d) values are approximately equal to 200 nM throughout the physiological pH range, a behavior shared with other endonucleases. While some of these results extend somewhat the range of expected behavior for restriction enzymes, these results indicate that PvuII endonuclease shares with other characterized systems a mechanism by which cognate affinity and sequence discrimination are most effectively achieved in the presence of divalent metal ions.

Differential effects of isomeric incorporation of fluorophenylalanines into PvuII endonuclease

Incorporation of fluorine into proteins has long served as a means of probing structure and function, yet there are few studies that examine the impact of fluorine substitution, particularly at locations distant from the active sites of enzymes. The flexibility of isomeric fluorine incorporation at Phe is used to explore subtle substitution effects on enzyme activity and conformation. The unnatural amino acids o-, m-, and p-fluorophenylalanines were incorporated biosynthetically into the representative PvuII restriction endonuclease. Interestingly, m-fluoro-Phe-PvuII endonuclease exhibits very similar conformational stability to that of the native enzyme, but it exhibits a reproducible, 2-fold higher average specific activity. Given the level of incorporation and the distribution of species, the species of modified enzyme responsible for this increase in specific activity is most likely even faster. Further, moving the fluorine atom from the meta- to the para-position of Phe results in a 4-fold decrease in specific activity and a decrease in conformational stability of 1.5 kcal/mol. Since none of the Phe residues in PvuII endonuclease lies near the DNA recognition or catalytic sites, this differential behavior alludes to the impact of subtle changes in enzyme conformation on endonuclease activity and suggests novel ways to influence catalytic behavior.

The PD...(D/E)XK motif in restriction enzymes: a link between function and conformation

The active sites of Mg(II)-dependent nucleases feature a cluster of conserved charged residues which includes both acidic (Asp and Glu) and basic (Lys) side chains. In restriction enzymes, these side chains are part of the conserved PD...(D/E)XK functional sequence motif which has been implicated as being important in metal ion binding and catalytic steps. Recent work revealing the unusual behavior of the active site variant D58A of the representative PvuII endonuclease prompted speculation that the array of charged groups in the nuclease active site may also be linked to conformational behavior [Dupureur, C. M., and Conlan, L. H. (2000) Biochemistry 39, 10921-10927]. To address this issue, we analyzed the conformational behavior of active site variants of PvuII endonuclease using both NMR spectroscopic and thermodynamic methods. NMR spectroscopic analysis via (19)F and (1)H-(15)N HSQC experiments indicates that a number of side chain and backbone amide groups are perturbed upon Ala substitution at conserved active site residues Asp58, Glu68, and Lys70. Spectral changes are particularly pronounced for the lowest-activity mutants (D58A and K70A). These changes are accompanied by perturbations in conformational stability. Ala substitution at each of these positions results in 2-5 kcal/mol of stabilization over the wild-type enzyme at pH 7.7, changes which constitute increases in DeltaG(d)(H2O) of 20-50%. The pH dependencies of mutant enzyme stabilities are distinct from those of the wild type, results which confirm that these ionizable groups strongly influence stability. Wild-type enzyme stability is correlated with the ionization of groups shown to be important to metal ion binding and orientation. Correlations between spectral changes and conformational stability indicate that the latter measurements may prove useful in the evaluation of site-directed mutant restriction enzymes. More importantly, these results indicate that structure-function relationships in restriction enzyme active sites can be complex, and that the ensemble of conserved charged residues which mediate DNA hydrolysis in Mg(II)-dependent nucleases constitutes a critical link between function and conformation.

A catalytically deficient active site variant of PvuII endonuclease binds Mg(II) ions

In efforts to understand the mechanisms of many nucleic acid enzymes, the first site-directed mutations are made at conserved acidic active residues. Almost without exception, the low or null activities of the resulting variants are attributed to the importance of the acidic residue(s) to the ligation of required metal ions. Using (25)Mg NMR spectroscopy as a direct probe of metal ion binding and the homodimeric PvuII restriction endonuclease as a model system, this interpretation is examined and clarified. Our results indicate that Mg(II) binds wild-type PvuII endonuclease in the absence of DNA with a K(d,app) of 1.9 mM. Hill analysis yields an n(H) coefficient of 1.4, a value consistent with the binding of more than one Mg(II) ion per monomer active site. Variable pH studies indicate that two ionizable groups are responsible for Mg(II) binding by wild-type PvuII endonuclease near physiological pH. The pK(a,app) for these ionizations is 6.7, a value which is unusual for acidic residues but consistent with data obtained for critical groups in MunI endonuclease and a number of other hydrolases. To assign residues critical to ligating Mg(II), binding measurements were performed on the low activity catalytic site mutants E68A and D58A. As expected, E68A binds Mg(II) ions very weakly (K(d,app) approximately 40 mM), implicating Glu68 as critical to Mg(II) binding. Interestingly, while D58A has only residual specific activity, it retains an affinity for Mg(II) with a K(d,app) of 3.6 mM and exhibits a Hill coefficient of 0.7. Moreover, in this variant, multiple ionizable groups with pK(a,app) of 7.2 are involved in Mg(II) binding, suggesting a shuffling of Mg(II) ligands in the active site. These data indicate that Asp58 is important for the critical positioning of metal ion(s) required for catalysis.

Quantitative evaluation of metal ion binding to PvuII restriction endonuclease

Restriction enzymes are important examples of phosphodiester hydrolysis activity and as such have been of increasing interest to structural biologists. Much of the architecture of endonuclease active sites has been derived from X-ray crystallographic studies. These structures implicate conserved active site acidic residues and the scissile bond of the substrate as coordination ligands of required metal ions. Central to the development of restriction enzyme mechanism is our understanding of the role of metal ion binding in the reaction, an important feature of which is identifying the energetic contributions of the enzyme and the substrate to metal ion affinity. To begin to address this issue, isothermal titration calorimetry (ITC) and 19F NMR spectroscopy have been applied to evaluate metal ion binding by the representative PvuII endonuclease in the absence of substrate. In separate experiments, ITC data demonstrate that PvuII endonuclease binds 2.16 Mn(II) ions and 2.05 Ca(II) metal ions in each monomer active site with Kd values of approximately 1 mM. While neither calorimetry nor protein NMR spectroscopy is directly sensitive to Mg(II) binding to the enzyme, Mn(II) competes with Mg(II) for common sites(s) on PvuII endonuclease. Substitution of the conserved active site carboxylate Glu68 with Ala resulted in a loss of affinity for both equivalents of both Ca(II) and Mn(II). Interestingly, the active site mutant D58A retained an affinity for Mn(II) with Kd approximately 2 mM. Mn(II) paramagnetic broadening in 19F spectra of wild-type and mutant 3-fluorotyrosine PvuII endonucleases are consistent with ITC results. Chemical shift analysis of 3-fluorotyrosine mutant enzymes is consistent with a perturbed conformation for D58A. Therefore, free PvuII endonuclease binds metal ions, and metal ion binding can precede DNA binding. Further, while Glu68 is critical to metal ion binding, Asp58 does not appear to be critical to the binding of at least one metal ion and appears to also have a role in structure. These findings provide impetus for exploring the roles of multiple metal ions in the structure and function of this representative endonuclease.

Modulating restriction endonuclease activities and specificities using neutral detergents

It is well known that type II restriction enzyme activities and specificities can be modulated by altering solution conditions. The addition of co-solvents such as dimethyl sulfoxide (DMSO), alcohols and polyols can promote star activity, which is the cleavage of non-cognate sequences. While neutral detergents are often used to control protein aggregation, little is known about the effect of neutral detergents on restriction enzyme activities and specificities. We report here that BamHI, BglI, BglII, EcoRI, EcoRV, HindIII, MluI, PvuII, SalI and XhoI restriction endonucleases are remarkably tolerant of high concentrations of neutral detergents Triton X-100, CHAPS and octyl glucoside. In most cases, lambda DNA cleavage rates were comparable to those observed in the absence of detergent. Indeed, the specific activities of SalI and XhoI were appreciably increased in the presence of Triton X-100. For all enzymes active in the presence of detergents, sequence specificity toward lambda DNA was not compromised. Assays of star cleavage of pUC18 by EcoRI, PvuII and BamHI endonucleases in equimolar concentrations of Triton X-100 and sucrose revealed reduced star activity in the detergent relative to the sucrose co-solvent. Interestingly, under star activity-promoting conditions, PvuII endonuclease displayed greater fidelity in Triton X-100 than in conventional buffer. Taken altogether, these results suggest that in some cases, neutral detergents can be used to manipulate restriction endonuclease reaction rates and specificities.

Effects of divalent metal ions on the activity and conformation of native and 3-fluorotyrosine-PvuII endonucleases

The activities of restriction enzymes are important examples of Mg(II)-dependent hydrolysis of DNA. While a number of crystallographic studies of enzyme-DNA complexes have also involved metal ions, there have been no solution studies exploring the relationship between enzyme conformation and metal-ion binding in restriction enzymes. Using PvuII restriction endonuclease as a model system, we have successfully developed biosynthetic fluorination and NMR spectroscopy as a solution probe of restriction-enzyme conformation. The utility of this method is demonstrated with a study of metal-ion binding by PvuII endonuclease. Replacement of 74% (+/- 10%) of the Tyr residues in PvuII endonuclease by 3-fluorotyrosine produces an enzyme with Mg(II)-supported specific activity and sequence specificity that is indistinguishable from that of the native enzyme. Mn(II) supports residual activity of both the native and fluorinated enzymes; Ca(II) does not support activity in either enzyme, a result consistent with previous studies. 1H- and 19F-NMR spectroscopic studies reveal that while Mg(II) does not alter the enzyme conformation, the paramagnetic Mn(II) produces both short-range spectral broadening and longer range changes in chemical shift. Most interestingly, Ca(II) binding perturbs a larger number of different resonances than Mn(II). Coupled with earlier mutagenesis studies that place Ca(II) in the active site [Nastri, H. G., Evans, P.D., Walker, I.H. & Riggs, P.D. (1997) J. Biol. Chem. 272, 25761-25767], these data suggest that the enzyme makes conformational adjustments to accommodate the distinct geometric preferences of Ca(II) and may play a role in the inability of this metal ion to support activity in restriction enzymes.

Phospholipase A2 engineering. The roles of disulfide bonds in structure, conformational stability, and catalytic function

Site-directed mutagenesis was used to probe the contribution of each of the seven disulfide bonds of bovine pancreatic phospholipase A2 (PLA2, overexpressed in Escherichia coli) to the structure, conformational stability, and catalytic function of the enzyme. Each of the seven disulfide bonds, C11-C77, C27-C123, C29-C45, C44-C105, C51-C98, C61-C91, and C84-C96, was deleted separately by changing both cysteine (C) residues to alanine (A). The structural properties of the mutants were analyzed by 1D and 2D proton NMR, the conformational stability by guanidine hydrochloride-induced denaturation, and the catalytic property by measuring kinetic parameters toward DC8PC (1,2-dioctanoyl-sn-glycero-3-phosphocholine) micelles. The results led to the following significant findings: (i) All but one (C84A-C96A) mutants have been refolded and purified by use of the same procedure for wild-type PLA2. Thus, the disulfide bonds are generally not important to the folding pathway of PLA2. (ii) The disulfide bond C11-C77 is most important to the conformation and conformational stability of the enzyme since deletion of this disulfide bond resulted in greatly perturbed NMR properties and in a decrease of 6.2 kcal/mol in conformational stability. However, the C11A-C77A mutant displayed little change in catalytic function. (iii) The effects of deleting disulfide bonds on the catalytic function of PLA2 are small, except the disulfide bond C29-C45 which connects the calcium binding loop with the helix C. However, the conformation and conformational stability of the C29A-C45A mutant was found to decrease by a factor of 10 or greater. (ABSTRACT TRUNCATED AT 250 WORDS)