[Two-stage total hip arthroplasty using an antibiotic-loaded cement spacer for infected internal fixation of hip fractures].

Objective: To evaluate the application and clinical results of two-stage total hip arthroplasty in the treatment of the deep hip infection following the internal fixation of hip fractures. Methods: From May 2007 to November 2014, 21 patients with active hip infection secondary to internal fixation of hip fractures were treated with two-stage total hip arthroplasty using a temporary antibiotic-loaded cement spacers. Of 21 cases, 15 were males and 6 were females, aged from 27 to 64 years (mean, 45); there are 18 cases of femoral neck fractures and 3 cases of intertrochanteric fractures. The serologic examination and X-ray were taken at 1 month, 3 months, 6 months, 12 months and annually thereafter post-operatively to evaluate the clinical results and prosthesis status. Harris hip score system was used to evaluate the joint function. Results: All patients were successfully treated with two stage operations under general anesthesia. The operational interval was 12-44 weeks (mean, 21) and 1 spacer breakage. For the arthroplasty, cementless components were used in 20 cases and cemented component was use in 1 case. The patients were followed up 25-102 months ( mean, 55 ) and infections were eradicated in all hips. The Harris hip score was improved from 23.24±11.81 pre-operatively to 90.24±3.92 post-operatively and the difference was statistically significant (P<0.05). According to this scoring criteria, the excellent and good rate reached up to 95%. At latest fellow-up, the location of prosthesis were well and the function of hip joint was satisfied. All cases had no dislocation, periprosthetic fracture, ectopic ossification or any other complications at the latest fellow-up. Conclusion: By means of an antibiotic-loaded cement spacer, two-stage total hip arthroplasty is an effective salvage procedure eradicating infection and providing functional improvement to the infected internal fixation of hip fractures. The early and mid-term clinical effects are satisfied.

Influence of proline-rich inositol polyphosphate 5-phosphatase, on early development of fertilized mouse eggs, via inhibition of phosphorylation of Akt.

OBJECTIVES: Proline-rich inositol polyphosphate 5-phosphatase (PIPP) is one of the signal-modifying enzymes that play pivotal regulatory roles in PI3K signalling pathway. The aim of this study was to determine the role of PIPP in early development of fertilized mouse eggs, via inhibition of Akt activity and subsequent downstream signalling events. MATERIALS AND METHODS: The mRNA transcript levels of endogenous PIPP and Akt1, Akt2, Akt3 were detected in G(1) , S, G(2) and M phases of fertilized mouse eggs by RT-PCR. Levels of exogenous PIPP, phosphorylated Akt at Ser473, dephosphorylated cdc2 at Tyr15 and levels of CCNB1, were detected respectively by immunoblotting. Changes in Akt localization were observed by fluoroimmunoassay; meanwhile, changes in activity of Akt and its downstream MPF were detected. Percentages of cells undergoing division were determined by counting, using a dissecting microscope. RESULTS: PIPP and Akt1 transcripts were detectable in G(1), S, G(2) and M phases of fertilized mouse eggs, but Akt2 and Akt3 were not. We also observed that overexpression of PIPP in fertilized eggs decreased expression of phosphorylated Akt at Ser473 and altered membrane localization of phosphorylated Akt at Ser473 specifically. Furthermore, overexpression of PIPP resulted in decreases in mitosis-phase promoting factor activity, level of dephosphorylated cdc2 at Tyr15 and cleavage rate of fertilized mouse eggs. CONCLUSIONS: Our data suggest, for the first time, that PIPP may affect development of fertilized mouse eggs by inhibition of level of phosphorylated Akt at Ser473 and subsequent inhibition of downstream signal cascades.

Electrochemical behavior of Au colloidal electrode through layer-by-layer self-assembly.

Electrodes formed by Au colloidal nanoparticles have been obtained by layer-by-layer self-assembly using 1,6-hexanedithiol as cross-linkers. Cyclic voltammograms show that the peak-to-peak separation decreases as the number of Au colloidal layers increases. After seven layers of Au colloidal particles have been deposited, the multilayer electrodes have the electrochemical properties of metallic Au and show ideal microelectrode behavior. An equivalent circuit for the electrochemical impedance spectroscopy was established to model the working electrode. It is evident that by increasing the layer number of Au colloidals, the interfacial electron transfer is promoted, implying the electron-transfer process changes from a kinetically limited process to a diffusionally limited process.

The basis for k(cat) impairment in prophospholipase A(2) from the anion-assisted dimer structure.

Kinetic results in this paper show that, contrary to earlier reports, pig pancreatic prophospholipase A(2) (proPLA2) does not hydrolyze monodisperse short chain phosphatidylcholine below the critical micelle concentration. ProPLA2 is active on an anionic interface, but at a rate that is decreased by more than 100-fold compared to that of PLA2, the active form. Solution studies show that both proPLA2 and PLA2 bind to an anionic interface and also bind a tetrahedral intermediate mimic at the active site. The 1.5 A resolution crystal structure of the anion-assisted dimer of proPLA2 reported in this paper is compared with the corresponding structure for PLA2 [Pan, Y. H., et al. (2001) Biochemistry 40, 609-617]. As a mimic for the forms bound to the anionic interface, these structures provide insights into the possible structural basis for the impaired chemical step of the zymogen. The proPLA2 dimer contained within one crystallographic asymmetric unit has one molecule of the inhibitor 1-hexadecyl-3-(trifluoroethyl)-sn-glycero-2-phosphomethanol and is bridged by four coplanar sulfate anions. Relative to the structure of PLA2, the subunit contact surface in proPLA2 displays a tilted orientation, an altered mode of inhibitor binding, displacement of a mechanistically significant loop that includes Tyr69, and a critical active site water seen in PLA2 that is not seen in proPLA2. These differences are interpreted to suggest possible origins of the functional differences between the pro and active enzyme at an anionic interface. A structural origin of this difference is discussed in terms of the calcium-coordinated activated water mechanism of the esterolysis reaction. Together, a comparison of the structures of the anion-assisted dimers of PLA2 and proPLA2 not only offers an explanation of why the zymogen form is k(cat)-impaired and binds poorly even to the anionic interface but also supports a mechanism for the activated enzyme that includes a critical second-sphere assisting water bridging His48 and the calcium-coordinated catalytic water.

Structural basis of the anionic interface preference and kcat* activation of pancreatic phospholipase A2.

Pancreatic phospholipase A(2) (PLA2) shows a strong preference for the binding to the anionic interface and a consequent allosteric activation. In this paper, we show that virtually all the preference is mediated through 3 (Lys-53, -56, and -120) of the 12 cationic residues of bovine pancreatic PLA2. The lysine-to-methionine substitution enhances the binding of the enzyme to the zwitterionic interface, and for the K53,56,120M triple mutant at the zwitterionic interface is comparable to that for the wild type (WT) at the anionic interface. In the isomorphous crystal structure, the backbone folding of K53,56M K120,121A and WT are virtually identical, yet a significant change in the side chains of certain residues, away from the site of substitution, mostly at the putative contact site with the interface (i-face), is discernible. Such reciprocity, also supported by the spectroscopic results for the free and bound forms of the enzyme, is expected because a distal structural change that perturbs the interfacial binding could also affect the i-face. The results show that lysine-to-methionine substitution induces a structural change that promotes the binding of PLA2 to the interface as well as the substrate binding to the enzyme at the interface. The kinetic results are consistent with a model in which the interfacial Michaelis complex exists in two forms, and the complex that undergoes the chemical step is formed by the charge compensation of Lys-53 and -56. Analysis of the incremental changes in the kinetic parameters shows that the charge compensation of Lys-53 and -56 contributes to the activation and that of Lys-120 contributes only to the structural change that promotes the stability of the Michaelis complex at the interface. The charge compensation effects on these three residues also account for the differences in the anionic interface preference of the evolutionarily divergent secreted PLA2.

Control of the chemical step by leucine-31 of pancreatic phospholipase A2.

A well-defined region of pancreatic and other secreted phospholipase A2 (PLA2), which we call the i-face, makes a molecular contact with the interface to facilitate and control the events and processivity of the interfacial catalytic turnover cycles. The structural features of the i-face and its allosteric relationship to the active site remain to be identified. As a part of the calcium binding (26-34) loop, Leu-31 is located on the surface near the substrate binding slot of PLA2. Analysis of the primary rate and equilibrium parameters of the Leu-31 substitution mutants of the pig pancreatic PLA2 shows that the only significant effect of the substitution is to impair the chemical step at the zwitterionic interface in the presence of added NaCl, and only a modest effect is seen on kcat at the anionic interface. Leu-31 substitutions have little effect on the binding of the enzyme to the interface; the affinity for certain substrate mimics is modestly influenced in W3F, L31W double mutant. The fluorescence emission results with the double mutant show that the microenvironment of Trp-31 is qualitatively different at the zwitterionic versus anionic interfaces. At both of the interfaces Trp-31 is not shielded from the bulk aqueous environment as it remains readily accessible to acrylamide and water. The NaCl-induced change in the Trp-31 emission spectrum of the double mutant on the zwitterionic interface is similar to that seen on the binding to the anionic interface. Together, the kinetic and spectroscopic results show that the form of PLA2 at the zwitterionic interface (Ez) is distinguishably different from the catalytically more efficient form at the anionic interface (Ea). This finding provides a structural basis for the two-state model for kcat activation by the anionic interface. In conjunction with earlier results we suggest that neutralization of certain cationic residues of PLA2 exerts a control on the calcium loop through residue 31.

Hydrolysis of monodisperse phosphatidylcholines by phospholipase A2 occurs on vessel walls and air bubbles.

Hydrolysis of monodisperse short chain phosphatidylcholines, far below their critical micelle concentration, by phospholipase A2 (PLA2) and other interfacial enzymes is characterized. Results show that virtually all the observed hydrolysis by pancreatic and human inflammatory PLA2 occurs on surfaces of the reaction vessel or air bubbles. Conditions to eliminate such extraneous contributions at low substrate concentrations are established. Premicellar aggregates are apparently formed near the critical micelle concentration. The observation window at low substrate concentrations is used to obtain an upper limit estimate of the rate of hydrolysis through the monodisperse Michaelis complex. A limit estimate of <0.1 s-1 is obtained for the hydrolysis of monodisperse substrates by pig pancreatic phospholipase A2. These results show that the observed rate of hydrolysis of dihexanoyl- and diheptanoylphosphatidylcholines with pig pancreatic phospholipase A(2) through the monomer path is insignificant compared to the rate of >1000 s-1 seen at the saturating levels of the micellar substrate. These protocols should be useful for evaluating reactions catalyzed at vessel walls. Implications of these results for assays and models of interfacial activation of pancreatic PLA2 are discussed.

Contributions of residues of pancreatic phospholipase A2 to interfacial binding, catalysis, and activation.

Primary rate and equilibrium parameters for 60 site-directed mutants of bovine pancreatic phospholipase A2 (PLA2) are analyzed so incremental contributions of the substitution of specific residues can be evaluated. The magnitude of the change is evaluated so a functional role in the context of the N- and C-domains of PLA2 can be assigned, and their relationship to the catalytic residues and to the i-face that makes contact with the interface. The effect of substitutions and interfacial charge is characterized by the equilibrium dissociation constant for dissociation of the bound enzyme from the interface (Kd), the dissociation constant for dissociation of a substrate mimic from the active site of the bound enzyme (KL), and the interfacial Michaelis constants, KM and kcat. Activity is lost (>99.9%) on the substitution of H48 and D49, the catalytic residues. A more than 95% decrease in kcat is seen with the substitution of F5, I9, D99, A102, or F106, which form the substrate binding pocket. Certain residues, which are not part of the catalytic site or the substrate binding pocket, also modulate kcat. Interfacial anionic charge lowers Kd, and induces kcat activation through K56, K53, K119, or K120. Significant changes in KL are seen by the substitution of N6, I9, F22, Y52, K53, N71, Y73, A102, or A103. Changes in KM [=(k2+k-1)/k1] are attributed to kcat (=k2) and KL (=k-1/k1). Some substitutions change more than one parameter, implying an allosteric effect of the binding to the interface on KS, and the effect of the interfacial anionic charge on kcat. Interpreted in the context of the overall structure, results provide insights into the role of segments and domains in the microscopic events of catalytic turnover and processivity, and their allosteric regulation. We suggest that the interfacial recognition region (i-face) of PLA2, due to the plasticity of certain segments and domains, exercises an allosteric control on the substrate binding and chemical step.

Catalytic significance of the specificity of divalent cations as KS* and kcat* cofactors for secreted phospholipase A2.

Calcium is required for the substrate binding and for the chemical step of the interfacial catalytic turnover cycle of pancreatic phospholipase A2 (PLA2), but not for the binding of the enzyme to the interface. The role of calcium and other divalent cations (C) is analyzed for the effect on the substrate binding and kcat* for the chemical step. The cofactor role of 3d-cations(II) (C) for the hydrolysis of dimyristoylphosphatidylmethanol (DMPM) vesicles is characterized as an equilibrium dissociation constant for the interfacial binary (E*C) and ternary (E*CL) complexes of PLA2 and substrate mimics (L). Of the cations(II) that promote the binding of a mimic to the enzyme at the interface (E*), only a subgroup supports the chemical step. For example, Cd, Zn, and Cu form ternary E*CL complexes with kcat* of <1 s-1, compared to the rate of >100 s-1 with Ca, Fe, Mn, Co, and Ni. Oxygen exchange from H218O to the products of hydrolysis of DMPM incorporates one 18O in myristate. Incorporation of the first and second 18O occurs during the incubation of both the products of hydrolysis in H218O with PLA2 and Ca, but not with Zn. The cation-dependent changes in the UV difference spectrum, associated with the formation of E*C and E*CL, suggest that the changes are mainly due to catalytic His-48, and possibly Tyr-52 and Tyr-73, and are different with Ca as opposed to Zn. These results and simulations suggest considerable plasticity in the calcium binding and catalytic site environment. It is proposed that the higher ground state stability of the E*CS complex with the inhibitory cations increases the effective activation energy. For the chemical step, calcium coordinated with a nucleophilic water and the ester carbonyl oxygen facilitates the near-attack geometry in the E*CaS, and the His-48.Asp-99 pair acts as a proton acceptor. As a prelude to establishing the catalytic mechanism, factors controlling the energetically demanding transition state are also discussed.

Cationic residues 53 and 56 control the anion-induced interfacial k*cat activation of pancreatic phospholipase A2.

Added NaCl or anionic amphiphiles increase the rate of hydrolysis of dispersions of zwitterionic phospholipid by pancreatic phospholipase A2 (PLA2). Two effects of the negative charge at the interface have been dissected: enhanced binding of the enzyme to the interface, and k*cat activation of the enzyme at the interface [Berg et al. (1997) Biochemistry 36, 14512-14530]. Results reported here show that the structural basis for the k*cat activation is predominantly through cationic K53 and K56 in bovine pancreatic PLA2 with the anionic interface. The maximum rate at saturating diheptanoylphosphatidylcholine micelles, VMapp, for WT, K56M, and K53M in 4 M NaCl is in the 800-1300 s-1 range. In contrast, VMapp at 0.1 M NaCl is considerably higher for K56M (400 s-1) and K53M (230 s-1) compared to the rate with WT (30 s-1) or K56E (45 s-1). The rate of hydrolysis of anionic dimyristoylphosphatidylmethanol vesicles is virtually the same with all these mutants (200-300 s-1) and it is not affected by added NaCl. The chemical step for the hydrolysis of anionic and zwitterionic substrates remains rate-limiting in the presence or absence of added NaCl. A modest (approximately 10-fold) effect of K56M substitution or of added NaCl is seen on the binding of the enzyme to the interface; however, the binding of the substrate or a substrate mimic to the active site of the enzyme at the interface is not affected by more than a factor of 2. Magnitudes of the primary rate and equilibrium parameters at the zwitterionic and anionic interfaces show that the effect of mutation or of added NaCl is primarily on k*cat at the zwitterionic interface. These results are interpreted in terms of a two-state model for the interfacial allosteric activation, where the enzyme-substrate complex at the zwitterionic interface becomes catalytically active only after the positive charge on cationic K56 and K53 has been removed by mutation or neutralized by anionic charges in the interface.

Interfacial activation of triglyceride lipase from Thermomyces (Humicola) lanuginosa: kinetic parameters and a basis for control of the lid.

A strategy is developed to analyze steady-state kinetics for the hydrolysis of a soluble substrate partitioned into the interface by an enzyme at the interface. The feasibility of this approach to obtain interfacial primary kinetic and equilibrium parameters is demonstrated for a triglyceride lipase. Analysis for phospholipase A2 catalyzed hydrolysis of rapidly exchanging micellar (Berg et al. (1997) Biochemistry 36, 14512-14530) and nonexchangeable vesicular (Berg et al., (1991) Biochemistry 30, 7283-7291) phospholipids is extended to include the case of a substrate that does not form the interface. The triglyceride lipase (tlTGL) from Thermomyces (formerly Humicola) lanuginosa hydrolyzes p-nitrophenylbutyrate or tributyrin partitioned in the interface of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoglycerol (POPG) vesicles at a rate that is more than 100-fold higher than that for the monodispersed substrate or for the substrate partitioned into zwitterionic vesicles. Catalysis and activation is not seen with the S146A mutant without the catalytic serine-146; however, it binds to the POPG interface with the same affinity as the WT. Thus POPG acts as a diluent surface to which the lipase binds in an active, or "open", form for the catalytic turnover; however, the diluent molecules have poor affinity for the active site. Analysis of the substrate and the diluent concentration dependence of the rate of hydrolysis provides a basis for the determination of the primary interfacial catalytic parameters. As a competitive substrate, tributyrin provided a check for the apparent affinity parameters. Nonidealities from the fractional difference in the molecular areas in interfaces are expressed as the area correction factor and can be interpreted as a first-order approximation for the interfacial activity coefficient. The basis for the interfacial activation of tlTGL on anionic interface is attributed to cationic R81, R84, and K98 in the "hinge" around the 86-93 "lid" segment of tlTGL.

Interfacial recognition by bee venom phospholipase A2: insights into nonelectrostatic molecular determinants by charge reversal mutagenesis.

The basis for tight binding of bee venom phospholipase A2 (bvPLA2) to anionic versus zwitterionic phospholipid interfaces is explored by charge reversal mutagenesis of basic residues (lysines/arginines to glutamates) on the putative membrane binding surface. Single-site mutants and, surprisingly, multisite mutants (2-5 of the 6 basic residues mutated) are fully functional on anionic vesicles. Mutants bind tightly to anionic vesicles, and active-site substrate and Ca2+ binding are not impaired. Multisite mutants undergo intervesicle exchange slightly faster than wild type, especially in the presence of salt. It is estimated that electrostatic contribution to interfacial binding is modest, perhaps 2-3 kcal/mol of the estimated 15 kcal/mol. Elution properties of bvPLA2 from HPLC columns containing solid phases of tightly packed monolayers of phosphocholine amphiphiles suggest that ionic effects provide a modest portion of the interfacial binding energy and that this contribution decreases as the number of cationic residues mutated is increased. These results are consistent with the observation that Gila monster venom PLA2 (Pa2), which is homologous to bvPLA2, has high activity on anionic vesicles despite the fact that it has only a single basic residue on its putative interfacial recognition face. Results with bvPLA2 mutants show that manoalogue and 12-epi-scalaradial inactivate bvPLA2 by modification of K94. Also, deletion of the large beta-loop (residues 99-118) is without consequence for interfacial binding and catalysis of bvPLA2. All together, the preferential binding of bvPLA2 to anionic vesicles versus phosphatidylcholine vesicles is mainly due to factors other than electrostatics. Therefore hydrogen-bonding and hydrophobic interactions must provide a major portion of the interfacial binding energy, and this is consistent with recent spectroscopic studies.

Thermodynamic and kinetic basis of interfacial activation: resolution of binding and allosteric effects on pancreatic phospholipase A2 at zwitterionic interfaces.

A general kinetic model for catalysis by interfacial enzymes is developed. It couples the Michaelis-Menten catalytic turnover cycle at the interface with that in the aqueous phase through the distribution equilibria between the interface and the surrounding aqueous phase. Analysis under two limiting conditions fully describes the steady-state kinetics of hydrolysis and resolves the allosteric effects from apparent modes of interfacial activation in terms of the primary rate and equilibrium parameters for pig pancreatic phospholipase A2 (PLA2). One limit is observed in dispersions of anionic phospholipid vesicles, in which intervesicle exchange of enzyme, substrate, and hydrolysis products is absent and reaction occurs only on vesicles containing enzyme. A complete analysis at this highly processive limit, called kinetics in the scooting mode, has been published [Berg et al. (1991) Biochemistry 30, 7283]. Here is reported the analysis in the other limit, PLA2-catalyzed hydrolysis of zwitterionic micelles of short-chain phosphatidylcholines, at which substrate and products are in rapid exchange. Hydrolysis occurs either in bulk aqueous solution with phospholipid monomers or at the micellar interface. Above the critical micelle concentration (cmc), the hydrolysis rate shows a hyperbolic dependence on the bulk substrate concentration present as micelles. This dependence, characterized by the fitting parameters KMapp and VMapp, is analyzed in terms of the primary rate and equilibrium constants. The kinetic analysis is based on the assumption that the microscopic steady-state condition is satisfied because substrate replenishment in the micro-environment of the enzyme is fast relative to the catalytic turnover time. Added NaCl and anionic interface increase the hydrolysis rate in zwitterionic micelles dramatically. The overall interfacial rate enhancement is attributed to three factors: (a) promotion of PLA2 binding by net anionic charge of the interface, (b) enhancement of substrate affinity of PLA2 at the interface (Ks* allostery), and (c) stimulation of the rate-limiting chemical step (kcat* allostery).

Gossypol modification of Ala-1 of secreted phospholipase A2: a probe for the kinetic effects of sulfate glycoconjugates.

Gossypol is shown to covalently modify secreted phospholipase A2 (PLA2) in the aqueous phase, but not at the interface. A rapid initial noncovalent binding of gossypol is followed by a slow covalent modification of the alpha-amino group of Ala-1 by stoichiometric amounts of gossypol. The rate of modification increases in the presence of calcium, but occupancy of the substrate binding site does not alter the rate. Pancreatic PLA2 is modified at the alpha-amino group of the N terminus to form a Schiff base, which can be stabilized by reduction with borohydride. Residual activity of the gossypol-modified PLA2 from several different sources is about 10%, indicative of impaired catalytic turnover. The half-time for the inactivation is about 10 min, and it is more than 100-fold longer for PLA2 at the interface. Gossypol promotes binding of PLA2 to the interface, and the binding of PLA2 to the interface promotes only the noncovalent binding of gossypol, but not the covalent modification. Gossypol, in conjunction with spectroscopic and kinetic protocols, is used to characterize the kinetic effects of sulfated glycoconjugates, heparin and artery wall proteoglycans, with human inflammatory and pancreatic PLA2.1 The conjugates do not interfere with the binding of PLA2 to the interface or with the catalytic cycle at the interface. The conjugates do not influence the kinetics of modification of PLA2 by gossypol in the aqueous phase, and the enzyme at the interface is not modified in the presence of the conjugates. The conjugates bind to PLA2 at the interface with only a modest effect on the interfacial catalytic turnover without dislodging the bound enzyme. Complex kinetic effects induced by the conjugates are shown to be due to sequestration of PLA2 in the aqueous phase as a high-molecular mass complex, which dissociates with added NaCl.

Use of an imperfect neutral diluent and outer vesicle layer scooting mode hydrolysis to analyze the interfacial kinetics, inhibition, and substrate preferences of bee venom phospholipase A2.

Interfacial catalytic constants for bee venom phospholipase A2 (bvPLA2) have been obtained for its action on vesicles of the anionic phospholipid 1,2-dimyristoylphosphatidylmethanol (DMPM) in the highly processive scooting mode. Spectroscopic measurements which directly measure transbilayer movement of membrane components show that this exchange does not occur in anionic vesicles that have undergone complete bvPLA2-catalyzed hydrolysis of all phospholipids in the outer vesicle monolayer. 3-Hexadecyl-sn-glycero-1-phosphocholine (D-LPC) is an adequate neutral diluent for bvPLA2, which is defined as an amphiphile that forms an aggregate to which enzyme binds but neutral diluent molecules bind weakly in the enzyme's active site. D-LPC has weak affinity for the active site of bvPLA2, and theory and protocols are developed that allow its use to determine equilibrium dissociation constants for competing active site ligands. Some of the properties of bvPLA2 are shared by other 14 kDa PLA2s. (1) Ca2+ is required for binding of ligands to the active site but not for the binding of enzyme to the interface. (2) bvPLA2 does not significantly discriminate between phospholipids with different polar head groups or acyl chains. (3) bvPLA2 does not bind to phosphatidylcholine vesicles, and binding occurs if anionic amphiphiles are present in the vesicle. Novel features of bvPLA2 include the following: (1) Neutral diluents for other 14 kDa phospholipases A2 are not neutral diluents for bvPLA2. (2) Saturation of the active site with a variety of different ligands does not completely prevent histidine alkylation by 2-bromo-4'-nitroacetophenone, and Ca2+ binding does not change the rate of histidine alkylation. Finally, the carbohydrate portion of bvPLA2 does not alter the interfacial catalytic properties of the enzyme. Kinetic analysis of bvPLA2 in the scooting mode together with previous studies with other 14 kDa PLA2s provides a paradigm for the quantitative analysis of interfacial catalysis.

Phospholipase A2 engineering. Structural and functional roles of the highly conserved active site residue aspartate-99.

The aspartate-99 of secreted phospholipase A2 (PLA2) has been proposed to be critical for the catalytic mechanism and interfacial activation of PLA2. Aspartate-99 connects the catalytic machinery (including the catalytic diad, the putative catalytic waters W5 and W6, and the calcium cofactor) to the hydrogen-bonding network. The latter involves Y52, Y73, the structural water, and the N-terminal region putatively required for the interfacial activation. A triple mutant of bovine pancreatic PLA2 with substitutions aspartate plus adjacent tyrosine residues (Y52,73F/D99N) was constructed, its X-ray structure was determined, and kinetic characteristics were analyzed. The kinetic properties of the D99N mutant constructed previously were also further analyzed. The X-ray structure of the Y52,73F/D99N mutant indicated a substantial disruption of the hydrogen-bonding network including the loss of the structural water similar to that seen in the structure of the D99N mutant published previously [Kumar, A., Sekharudu, Y. C., Ramakrishnan, B., Dupureur, C. M., Zhu, H., Tsai, M.-D., & Sundaralingam, M. (1994) Protein Sci. 3, 2082-2088]. Kinetic analysis demonstrated that these mutants possessed considerable catalytic activity with a k(cat) value of about 5% compared to WT. The values of the interfacial Michaelis constant were also little perturbed (ca. 4-fold lower for D99N and marginally higher for Y52,73F/D99N). The results taken together suggest that the hydrogen-bonding network is not critically important for interfacial activation. Instead, it is the chemical step that is perturbed, though only modestly, in the mutants.

Phospholipase A2 engineering. Deletion of the C-terminus segment changes substrate specificity and uncouples calcium and substrate binding at the zwitterionic interface.

It has been suggested [Dijkstra, B. W., Drenth, J., & Kalk, K. H. (1981) Nature 289, 604-606] that the interfacial binding site of phospholipase A2 (PLA2) involves a large number of residues, including a cluster at the N-terminus and another cluster at the C-terminus. The approaches of multiple mutation and deletion were used to test the roles of the C-terminal residues of bovine pancreatic PLA2 overexpressed in Escherichia coli. A double mutant K120A/K121A and a deletion mutant delta 115-123/ C27A were constructed, and structural and functional analyses were performed on both mutants. The double mutant showed little perturbation in the global structure on the basis of proton NMR and X-ray crystallographic analyses. The proton NMR analysis of the deletion mutant suggested that a few residues at the active site, the hydrophobic channel, and the calcium binding loop are perturbed, but the global conformation is not changed. The mutants were then characterized for catalytic and binding properties by use of various kinetic and spectroscopic methods. The double mutant behaved in a manner similar to that of the wild type (WT) PLA2 in every property examined. The deletion mutant was found to show an interesting change of substrate specificity. The kcat,app of the zwitterionic DC8PC micelles but not the anionic DC8PM micelles decreased by a factor of > 100; however, the activity of DC8PC was restored upon addition of 4 M NaCl. The results of fluorescence spectroscopic studies indicate that the deletion mutant behaves in a manner similar to that of WT in the binding to anionic vesicles and to zwitterionic neutral diluent. Thus, the binding affinity of the enzyme to the interface (the E to E* step) should not be the main cause for the change in substrate specificity. The cause lies at least partially in the binding of substrate or inhibitor to the active site of the enzyme at the interface, i.e., the E* to E*L step, as revealed by the results of equilibrium binding studies. The equilibrium dissociation constants of ligands are generally higher for the deletion mutant (relative to WT) at the zwitterionic interface but not at the anionic interface. The cause for the low affinity of an active site-directed ligand to the active site at the zwitterionic interface could be related to the inability of Ca2+ to enhance ligand binding for the deletion mutant. This is in contrast to the WT PLA2 for which Ca2+ binding enhances binding of the substrate to the active site. Overall, the structural and functional perturbations caused by deleting the C-terminal segment are modest, but the changes in substrate specificity and the uncoupling between substrate and calcium binding are interesting and significant.

Kinetic basis for the substrate specificity during hydrolysis of phospholipids by secreted phospholipase A2.

Kinetics of hydrolysis of aqueous dispersions of arsono-, sulfo-, phosphono- and phospholipids by phospholipase A2 from pig pancreas are characterized in terms of interfacial rate and equilibrium parameters. The enzyme with or without calcium binds with high affinity to the aqueous dispersions of the four classes of anionic lipids and shows the same general kinetic behavior. The rate of hydrolysis of anionic substrates does not show an anomalous change at the critical micelle concentration because the enzyme is present in aggregates even when bulk of the substrate is dispersed as a solitary monomer. Apparent affinities of the enzyme for the interface of different anionic lipids are virtually the same. Also, affinities of these substrates for the active site of the enzyme at the interface are comparable. However, a significant change in the catalytic turnover rate is seen as the sn-3 phosphodiester group is modified; the apparent maximum rate at saturating bulk substrate concentration, V(M)app values, increase in the order: homo- and arsonolipids < sulfo- < phosphono- < phospholipids. Not only the basis for the sn-2 enantiomeric selectivity but also the decrease in the rate of hydrolysis with the increasing chain length is due to a decrease in the value of V(M)app. Results show that even when the bulk concentration of anionic phospholipid is below cmc, hydrolysis occurs in aggregates of enzyme and substrate where the chemical step of the turnover cycle remains rate-limiting, which provides a basis for the assumption that V(M)app is directly related to Kcat. The fact that Kcat depends on the nature of the head group (phosphate, phosphonate, sulfate, arsonate) implies that the head group plays a critical role in the rate-limiting chemical step of the catalytic cycle, possibly during the decomposition of the tetrahedral intermediate. The significance of these results for the microscopic steady-state condition for hydrolysis at the micellar interface, mechanism of esterolysis by phospholipase A2, and inhibitor design are discussed.

Continuous, vesicle-based fluorimetric assays of 14- and 85-kDa phospholipases A2.

This paper describes the synthesis and analysis of new substrates for the 85-kDa, mammalian, cytosolic phospholipase A2 (cPLA2) and the 14-kDa, human nonpancreatic, secreted phospholipase A2 (sPLA2). Phosphatidylcholines containing an arachidonyl chain at the sn-2 position and either a 10-pyrenedecyl or a 10-pyrenedecanoyl chain at the sn-1 position were synthesized and shown to be substrates for cPLA2 in a fluorescence-based assay. Most of the assays make use of small and large unilamellar vesicles of substrate phospholipid, although the assay also works when the substrate is dispersed in Triton X-100 mixed-micelles. The cPLA2 assays can be carried out in a fixed time-point mode in which one of the products, the pyrene-containing lysophospholipid, is detected by rapid HPLC. Alternatively, the assay becomes continuous when bovine serum albumin is present in the aqueous phase; this protein extracts the pyrene-containing lysophospholipid from the vesicle, and this leads to the fluorescence of monomeric pyrene label. These assays are capable of detecting subnanogram amounts of cPLA2. The ester formed between gamma-linolenic acid and 7-hydroxycoumarin is also a substrate for cPLA2, and when incorporated into vesicles of the anionic phospholipid, 1,2-dioleoyl-sn-glycero-3-phosphomethanol, provides an assay in which the enzyme does not leave the vesicle surface (scooting mode). Unlike all of the previously reported, vesicle-based cPLA2 assays, a prolonged linear reaction progress is seen with the DOPM-based assay. An assay of sPLA2 with subnanogram sensitivity was developed which makes use of the substrate 1-palmitoyl-2-(10-pyrenedecanoyl)-sn-glycero-3-phosphomethanol and a lipid sink. The latter is composed of phosphatidylcholine vesicles, in excess of substrate vesicles, which do not bind sPLA2 but provide a trap for enzyme-produced 10-pyrenedecanoic acid. The fluorescence of monomeric pyrene label in sink vesicles is detected. A second sPLA2 assay using a single type of vesicle was developed based on the substrate 1,2-di(10-pyrenedecanoyl)-sn-glycero-3-phosphocholine present at 10 mol% in vesicles of the nonhydrolyzable anionic phospholipid 1,2-ditetradecyl-sn-glycero-3-phosphomethanol. The action of sPLA2 on this fluorescent substrate leads to a separation of the pyrene chains resulting in fluorescence emission from monomeric pyrene. These cPLA2 and sPLA2 assays are ideal for inhibitor screening and analysis, and for studying the interfacial kinetics of these enzymes.