Mechanism of phosphatidylinositol-specific phospholipase C: origin of unusually high nonbridging thio effects

A "Seleno Effect" Differentiates the Roles of Redox Active Cysteine Residues in Plasmodium falciparum Thioredoxin Reductase

Here, we introduce the concept of the "seleno effect" in the study of oxidoreductases that catalyze thiol/disulfide exchange reactions. In these reactions, selenium can replace sulfur as a nucleophile, electrophile, or leaving group, and the resulting change in rate (the seleno effect) is defined as k_S/ k_Se. In solution, selenium accelerates the rate of thiol/disulfide exchange regardless of its chemical role (e.g., nucleophile or electrophile). Here we show that this is not the case for enzyme catalyzed reactions and that the magnitude of the seleno effect can differentiate the role of each sulfur atom of a disulfide bond between that of an electrophile or leaving group. We used selenium for sulfur substitution to study the thiol/disulfide exchange step that occurs between the N-terminal redox center and the C-terminal disulfide-containing β-hairpin motif of Plasmodium falciparum thioredoxin reductase (PfTrxR), which has the sequence Gly-Cys⁵³⁵-Gly-Gly-Gly-Lys-Cys⁵⁴⁰-Gly. We assayed a truncated PfTrxR enzyme missing this C-terminal tail for disulfide-reductase activity using synthetic peptide substrates in which either Cys⁵³⁵ or Cys⁵⁴⁰ was replaced with selenocysteine (Sec). The results show that substitution of Cys⁵³⁵ with Sec resulted in a nearly 9-fold decrease in the rate of reduction, while substitution of Cys⁵⁴⁰ resulted in a 1.5-fold increase in the rate of reduction. We also produced full-length, semisynthetic enzymes in which Sec replaced either of these two Cys residues and observed similar results using E. coli thioredoxin as the substrate. In this assay, the observed seleno effect ( k_S/ k_Se) for the C535U mutant was 7.4, and that for the C540U mutant was 0.2.

A feedback mechanism between PLD and deadenylase PARN for the shortening of eukaryotic poly(A) mRNA tails that is deregulated in cancer cells

The removal of mRNA transcript poly(A) tails by 3′→5′ exonucleases is the rate-limiting step in mRNA decay in eukaryotes. Known cellular deadenylases are the CCR4-NOT and PAN complexes, and poly(A)-specific ribonuclease (PARN). The physiological roles and regulation for PARN is beginning to be elucidated. Since phospholipase D (PLD2 isoform) gene expression is upregulated in breast cancer cells and PARN is downregulated, we examined whether a signaling connection existed between these two enzymes. Silencing PARN with siRNA led to an increase in PLD2 protein, whereas overexpression of PARN had the opposite effect. Overexpression of PLD2, however, led to an increase in PARN expression. Thus, PARN downregulates PLD2 whereas PLD2 upregulates PARN. Co-expression of both PARN and PLD2 mimicked this pattern in non-cancerous cells (COS-7 fibroblasts) but, surprisingly, not in breast cancer MCF-7 cells, where PARN switches from inhibition to activation of PLD2 gene and protein expression. Between 30 and 300 nM phosphatidic acid (PA), the product of PLD enzymatic reaction, added exogenously to culture cells had a stabilizing role of both PARN and PLD2 mRNA decay. Lastly, by immunofluorescence microscopy, we observed an intracellular co-localization of PA-loaded vesicles (0.1-1 nm) and PARN. In summary, we report for the first time the involvement of a phospholipase (PLD2) and PA in mediating PARN-induced eukaryotic mRNA decay and the crosstalk between the two enzymes that is deregulated in breast cancer cells.

Summary: Cell signaling enzyme phospholipase D2 (PLD2) and its reaction product, phospholipid phosphatidic acid (PA), are involved in mediating PARN-induced eukaryotic mRNA decay.

Selenocysteine in thiol/disulfide-like exchange reactions

SIGNIFICANCE

Among trace elements used as cofactors in enzymes, selenium is unique in that it is incorporated into proteins co-translationally in the form of an amino acid, selenocysteine (Sec). Sec differs from cysteine (Cys) by only one atom (selenium versus sulfur), yet this switch dramatically influences important aspects of enzyme reactivity.

RECENT ADVANCES

The main focus of this review is an updated and critical discussion on how Sec might be used to accelerate thiol/disulfide-like exchange reactions in natural selenoenzymes, compared with their Cys-containing homologs.

CRITICAL ISSUES

We discuss in detail three major aspects associated with thiol/disulfide exchange reactions: (i) nucleophilicity of the attacking thiolate (or selenolate); (ii) electrophilicity of the center sulfur (or selenium) atom; and (iii) stability of the leaving group (sulfur or selenium). In all these cases, we analyze the benefits that selenium might provide in these types of reactions.

FUTURE DIRECTIONS

It is the biological thiol oxidoreductase-like function that benefits from the use of Sec, since Sec functions to chemically accelerate the rate of these reactions. We review various hypotheses that could help explain why Sec is used in enzymes, particularly with regard to competitive chemical advantages provided by the presence of the selenium atom in enzymes. Ultimately, these chemical advantages must be connected to biological functions of Sec.

Investigation of the catalytic mechanism of a synthetic DNAzyme with protein-like functionality: an RNaseA mimic?

The protein enzyme ribonuclease A (RNaseA) cleaves RNA with catalytic perfection, although with little sequence specificity, by a divalent metal ion (M(2+))-independent mechanism in which a pair of imidazoles provides general acid and base catalysis, while a cationic amine provides electrostatic stabilization of the transition state. Synthetic imitation of this remarkable organo-catalyst ("RNaseA mimicry") has been a longstanding goal in biomimetic chemistry. The 9(25)-11 DNAzyme contains synthetically modified nucleotides presenting both imidazole and cationic amine side chains, and catalyzes RNA cleavage with turnover in the absence of M(2+) similarly to RNaseA. Nevertheless, the catalytic roles, if any, of the "protein-like" functional groups have not been defined, and hence the question remains whether 9(25)-11 engages any of these functionalities to mimic aspects of the mechanism of RNaseA. To address this question, we report a mechanistic investigation of 9(25)-11 catalysis wherein we have employed a variety of experiments, such as DNAzyme functional group deletion, mechanism-based affinity labeling, and bridging and nonbridging phosphorothioate substitution of the scissile phosphate. Several striking parallels exist between the results presented here for 9(25)-11 and the results of analogous experiments applied previously to RNaseA. Specifically, our results implicate two particular imidazoles in general acid and base catalysis and suggest that a specific cationic amine stabilizes the transition state via diastereoselective interaction with the scissile phosphate. Overall, 9(25)-11 appears to meet the minimal criteria of an RNaseA mimic; this demonstrates how added synthetic functionality can expand the mechanistic repertoire available to a synthetic DNA-based catalyst.

Differing views of the role of selenium in thioredoxin reductase

This review covers three different chemical explanations that could account for the requirement of selenium in the form of selenocysteine in the active site of mammalian thioredoxin reductase. These views are the following: (1) the traditional view of selenocysteine as a superior nucleophile relative to cysteine, (2) the superior leaving group ability of a selenol relative to a thiol due to its significantly lower pK (a) and, (3) the superior ability of selenium to accept electrons (electrophilicity) relative to sulfur. We term these chemical explanations as the "chemico-enzymatic" function of selenium in an enzyme. We formally define the chemico-enzymatic function of selenium as its specific chemical property that allows a selenoenzyme to catalyze its individual reaction. However we, and others, question whether selenocysteine is chemically necessary to catalyze an enzymatic reaction since cysteine-homologs of selenocysteine-containing enzymes catalyze their specific enzymatic reactions with high catalytic efficiency. There must be a unique chemical reason for the presence of selenocysteine in enzymes that explains the biological pressure on the genome to maintain the complex selenocysteine-insertion machinery. We term this biological pressure the "chemico-biological" function of selenocysteine. We discuss evidence that this chemico-biological function is the ability of selenoenzymes to resist inactivation by irreversible oxidation. The way in which selenocysteine confers resistance to oxidation could be due to the superior ability of the oxidized form of selenocysteine (Sec-SeO(2)(-), seleninic acid) to be recycled back to its parent form (Sec-SeH, selenocysteine) in comparison to the same cycling of cysteine-sulfinic acid to cysteine (Cys-SO(2)(-) to Cys-SH).

Using chemical approaches to study selenoproteins-focus on thioredoxin reductases

The study of selenocysteine-containing proteins is difficult due to the problems associated with the heterologous production of these proteins. These problems are due to the intricate recoding mechanism used by cells to translate the UGA codon as a sense codon for selenocysteine. The process is further complicated by the fact that eukaryotes and prokaryotes have different UGA recoding machineries. This review focuses on chemical approaches to produce selenoproteins and study the mechanism of selenoenzymes. The use of intein-mediated peptide ligation is discussed with respect to the production of the mammalian selenoenzymes thioredoxin reductase and selenoprotein R, also known as methionine sulfoxide reductase B1. New methods for removing protecting groups from selenocysteine post-synthesis and methods for selenosulfide/diselenide formation are also reviewed. Chemical approaches have also been used to study the enzymatic mechanism of thioredoxin reductase. The approach divides the enzyme into two modules, a large protein module lacking selenocysteine and a small, synthetic selenocysteine-containing peptide. Study of this semisynthetic enzyme has revealed three distinct enzymatic pathways that depend on the properties of the substrate. The enzyme utilizes a macromolecular mechanism for protein substrates, a second mechanism for small molecule substrates and a third pathway for selenium-containing substrates such as selenocystine.

Characterization of specific noncovalent complexes between guanidinium derivatives and single-stranded DNA by MALDI

Noncovalently bound complexes between highly basic sites of 12 guanidinium compounds and single-stranded DNA were studied using matrix-assisted laser desorption/ionization (MALDI) mass spectrometry. 6-Aza-2-thiothymine (ATT) was used as the matrix in the presence of ammonium citrate, and spectra were recorded in the positive ion mode. Detailed control experiments confirmed unambiguously the high selectivity and specificity of the guanidinium moiety for phosphate groups of DNA. The results verify the binding stoichiometry and show preferential binding of hydrophobic binders (pyrene and anthracene guanidinium derivatives) to all sequences examined. In addition, we demonstrate that electrostatic noncovalent interactions are strengthened with phosphorothioate analogs of DNA. These results clearly highlight the structure-directing role of the self-assembling organic species and strongly emphasize the significance of concentration, hydrophobicity, hydrogen-bonding, and pi-pi interactions of the artificial receptor in the formation of these noncovalent complexes. Because of the ability of DNA-binding compounds to influence gene expression, and therefore cell proliferation and differentiation, the interactions described above could be important in providing a better understanding of the mechanism of action of these noncovalent genetic regulators.

The Catalytic Role of Aspartate in a Short Strong Hydrogen Bond of the Asp274–His32 Catalytic Dyad in Phosphatidylinositol-specific Phospholipase C Can Be Substituted by a Chloride Ion

Phosphatidylinositol-specific phospholipase C from Bacillus thuringiensis catalyzes the cleavage of the phosphorus-oxygen bond in phosphatidylinositol. The focus of this work is to dissect the roles of the carboxylate side chain of Asp(274) in the Asp(274)-His(32) dyad, where a short strong hydrogen bond (SSHB) was shown to exist based on NMR criteria. A regular hydrogen bond (HB) was observed in D274N, and no low field proton resonance was detected for D274E and D274A. Comparison of the activity of wild type, D274N, and D274A suggested that the regular HB contributes significantly (approximately 4 kcal/mol) to catalysis, whereas the SSHB contributes only an additional 2 kcal/mol. The mutant D274E displays high activity similar to wild type, suggesting that the negative charge is sufficient for the catalytic role of Asp(274). To further support this interpretation and rule out possible contribution of regular HB or SSHB in D274E, we showed that the activity of D274G can be rescued by exogenous chloride ions to a level comparable with that of D274E. Comparison between different anions suggested that the ability of an anion to rescue the activity is due to the size and the charge of the anion not the property as a HB acceptor. In conclusion, a major fraction of the functional role of Asp(274) in the Asp(274)-His(32) dyad can be attributed to a negative charge (as in D274E and D274G-Cl(-)), and the SSHB in the wild type enzyme provides minimal contribution to catalysis. These results represent novel insight for an Asp-His catalytic dyad and for the mechanism of phosphatidylinositol-specific phospholipase C.

His151 and His296 are the acid-base catalytic residues of Bacillus cereus sphingomyelinase in sphingomyelin hydrolysis

Bacillus cereus sphingomyelinase belongs to the Mg(2+)-dependent neutral sphingomyelinase, which hydrolyses sphingomyelin to phosphocholine and ceramide, and acts as an extracellular hemolysin. The triplet residues, His151-Asp195-His296, of the enzyme are highly conserved among bacterial and mammalian Mg(2+)-dependent neutral sphingomyelinases. The triplet residues converge on the active-site pocket of the 3D model of the enzyme. To investigate the function of these residues in the acid-base catalysis, we introduced several mutations for each residue by site-directed mutagenesis. Hemolytic and hydrolytic activities of the enzyme, abolished by the mutations at Asp195 and His296, revealed that these residues are critical for the catalytic function. The effect of the divalent metal cations on the pH dependency of the hydrolytic activities indicates that His296 corresponds to the most acidic ionizable group as a general base. The mutagenesis at His151 was also deleterious; however, the H151A and H151Q mutant enzymes partially retained their activities. The H151A mutation affected the most basic ionizable group, suggesting that His151 may act as a general acid in catalysis. By the structural basis of the 3D model, Asp195 must maintain not only the appropriate spatial arrangement but also pK(a)s of His151 and His296. Taking into consideration all of these, we proposed the acid-base catalytic mechanism of B. cereus sphingomyelinase.

Evaluating the effects of enhanced processivity and metal ions on translesion DNA replication catalyzed by the bacteriophage T4 DNA polymerase

The fidelity of DNA replication is achieved in a multiplicative process encompassing nucleobase selection and insertion, removal of misinserted nucleotides by exonuclease activity, and enzyme dissociation from primer/templates that are misaligned due to mispairing. In this study, we have evaluated the effect of altering these kinetic processes on the dynamics of translesion DNA replication using the bacteriophage T4 replication apparatus as a model system. The effect of enhancing the processivity of the T4 DNA polymerase, gp43, on translesion DNA replication was evaluated using a defined in vitro assay system. While the T4 replicase (gp43 in complex with gp45) can perform efficient, processive replication using unmodified DNA, the T4 replicase cannot extend beyond an abasic site. This indicates that enhancing the processivity of gp43 does not increase unambiguously its ability to perform translesion DNA replication. Surprisingly, the replicase composed of an exonuclease-deficient mutant of gp43 was unable to extend beyond the abasic DNA lesion, thus indicating that molecular processes involved in DNA polymerization activity play the predominant role in preventing extension beyond the non-coding DNA lesion. Although neither T4 replicase complex could extend beyond the lesion, there were measurable differences in the stability of each complex at the DNA lesion. Specifically, the exonuclease-deficient replicase dissociates at a rate constant, k(off), of 1.1s(-1) while the wild-type replicase remains more stably associated at the site of DNA damage by virtue of a slower measured rate constant (k(off) 0.009s(-1)). The increased lifetime of the wild-type replicase suggests that idle turnover, the partitioning of the replicase from its polymerase to its exonuclease active site, may play an important role in maintaining fidelity. Further attempts to perturb the fidelity of the T4 replicase by substituting Mn(2+) for Mg(2+) did not significantly enhance DNA synthesis beyond the abasic DNA lesion. The results of these studies are interpreted with respect to current structural information of gp43 alone and complexed with gp45.

Allosteric interactions within subsites of a monomeric enzyme: kinetics of fluorogenic substrates of PI-specific phospholipase C

Two novel water-soluble fluorescein myo-inositol phosphate (FLIP) substrates, butyl-FLIP and methyl-FLIP, were used to examine the kinetics and subsite interactions of Bacillus cereus phosphatidylinositol-specific phospholipase C. Butyl-FLIP exhibited sigmoidal kinetics when initial rates are plotted versus substrate concentration. The data fit a Hill coefficient of 1.2-1.5, suggesting an allosteric interaction between two sites. Two substrate molecules bind to this enzyme, one at the active site and one at a subsite, causing an increase in activity. The kinetic behavior is mathematically similar to that of well-known cooperative multimeric enzymes even though this phosphatidylinositol-specific phospholipase C is a small, monomeric enzyme. The less hydrophobic substrate, methyl-FLIP, binds only to the active site and not the activator site, and thus exhibits standard hyperbolic kinetics. An analytical expression is presented that accounts for the kinetics of both substrates in the absence and presence of a nonsubstrate short-chain phospholipid, dihexanoylphosphatidylcholine. The fluorogenic substrates detect activation at much lower concentrations of dihexanoylphosphatidylcholine than previously reported.

Application of Brønsted-type LFER in the study of the phospholipase C mechanism

Phosphatidylinositol-specific phospholipase C cleaves the phosphodiester bond of phosphatidylinositol to form inositol 1,2-cyclic phosphate and diacylglycerol. This enzyme also accepts a variety of alkyl and aryl inositol phosphates as substrates, making it a suitable model enzyme for studying mechanism of phosphoryl transfer by probing the linear free-energy relationship (LFER). In this work, we conducted a study of Brønsted-type relationship (log k = beta(lg) pK(a) + C) to compare mechanisms of enzymatic and nonenzymatic reactions, confirm the earlier proposed mechanism, and assess further the role of hydrophobicity in the leaving group as a general acid-enabling factor. The observation of the high negative Brønsted coefficients for both nonenzymatic (beta(lg) = -0.65 to -0.73) and enzymatic cleavage of aryl and nonhydrophobic alkyl inositol phosphates (beta(lg) = -0.58) indicates that these reactions involve only weak general acid catalysis. In contrast, the enzymatic cleavage of hydrophobic alkyl inositol phosphates showed low negative Brønsted coefficient (beta(lg) = -0.12), indicating a small amount of the negative charge on the leaving group and efficient general acid catalysis. Overall, our results firmly support the previously postulated mechanism where hydrophobic interactions between the enzyme and remote parts of the leaving group induce an unprecedented negative-charge stabilization on the leaving group in the transition state.

Engineering a catalytic metal binding site into a calcium-independent phosphatidylinositol-specific phospholipase C leads to enhanced stereoselectivity

Eukaryotic phosphatidylinositol-specific phospholipase Cs (PI-PLCs) utilize calcium as a cofactor during catalysis, whereas prokaryotic PI-PLCs use a spatially conserved guanidinium group from Arg69. In this study, we aimed to construct a metal-dependent mutant of a bacterial PI-PLC and characterize the catalytic role of the metal ion, seeking an enhanced understanding of the functional differences between these two positively charged moieties. The following results indicate that a bona fide catalytic metal binding site was created by the single arginine-to-aspartate mutation at position 69: (1) The R69D mutant was activated by Ca(2+), and the activation was specific for R69D, not for other mutants at this position. (2) Titration of R69D with Ca(2+), monitored by (15)N-(1)H HSQC (heteronuclear single quantum coherence) NMR, showed that addition of Ca(2+) to R69D restores the environment of the catalytic site analogous to that attained by the WT enzyme. (3) Upon Ca(2+) activation, the thio effect of the S(P)-isomer of the phosphorothioate analogue (k(O)/k(Sp) = 4.4 x 10(5)) approached a value similar to that of the WT enzyme, suggesting a structural and functional similarity between the two positively charged moieties (Arg69 and Asp69-Ca(2+)). The R(P)-thio effect (k(O)/k(Rp) = 9.4) is smaller than that of the WT enzyme by a factor of 5. Consequently, R69D-Ca(2+) displays higher stereoselectivity (k(Rp)/k(Sp) = 47,000) than WT (k(Rp)/k(Sp) = 7600). (4) Results from additional mutagenesis analyses suggest that the Ca(2+) binding site is comprised of side chains from Asp33, Asp67, Asp69, and Glu117. Our studies provide new insight into the mechanism of metal-dependent and metal-independent PI-PLCs.

A novel calcium-dependent bacterial phosphatidylinositol-specific phospholipase C displaying unprecedented magnitudes of thio effect, inverse thio effect, and stereoselectivity

Understanding the potential range of enzymatic thio effects (kO/kS) is of great value when using sulfur-substituted phosphate analogues to study phosphoryl transfer reactions in enzymes and ribozymes. Herein we report that a newly discovered Ca2+-dependent Streptomyces antibioticus phosphatidylinositol-specific phospholipase C and its mutants display unprecedented magnitudes of thio effect, inverse thio effect, and RP/SP stereoselectivity. We demonstrate that for a single enzyme the bridging thio effect can vary from 0.002 to 20 and the nonbridging thio effect can vary from 1 to 108. These values fall outside the range of those reported for nonenzymatic reactions, emphasizing the need for cautious interpretation when using thio effects to elucidate details of enzyme catalysis.

Involvement of the Arg-Asp-His catalytic triad in enzymatic cleavage of the phosphodiester bond

Phosphatidylinositol-specific phospholipase C (PI-PLC) catalyzes the cleavage of the P-O bond in phosphatidylinositol via intramolecular nucleophilic attack of the 2-hydroxyl group of inositol on the phosphorus atom. Our earlier stereochemical and site-directed mutagenesis studies indicated that this reaction proceeds by a mechanism similar to that of RNase A, and that the catalytic site of PI-PLC consists of three major components analogous to those observed in RNase A, the His32 general base, the His82 general acid, and Arg69 acting as a phosphate-activating residue. In addition, His32 is associated with Asp274 in forming a catalytic triad with inositol 2-hydroxyl, and His82 is associated with Asp33 in forming a catalytic diad. The focus of this work is to provide a global view of the mechanism, assess cooperation between various catalytic residues, and determine the origin of enzyme activation by the hydrophobic leaving group. To this end, we have investigated kinetic properties of Arg69, Asp33, and His82 mutants with phosphorothioate substrate analogues which feature leaving groups of varying hydrophobicity and pK(a). Our results indicate that interaction of the nonbridging pro-S oxygen atom of the phosphate group with Arg69 is strongly affected by Asp33, and to a smaller extent by His82. This result in conjunction with those obtained earlier can be rationalized in terms of a novel, dual-function triad comprised of Arg69, Asp33, and His82 residues. The function of this triad is to both activate the phosphate group toward the nucleophilic attack and to protonate the leaving group. In addition, Asp33 and His82 mutants displayed much smaller degrees of activation by the fatty acid-containing leaving group as compared to the wild-type (WT) enzyme, and the level of activation was significantly reduced for substrates featuring the leaving group with low pK(a) values. These results strongly suggest that the assembly of the above three residues into the fully catalytically competent triad is controlled by the hydrophobic interactions of the enzyme with the substrate leaving group.