Mechanism of aminoglycoside antibiotic kinase APH(3')-IIIa: role of the nucleotide positioning loop

The aminoglycoside antibiotic resistance kinases (APHs) and the Ser/Thr/Tyr protein kinases share structural and functional homology but very little primary sequence conservation (<5%). A region of structural, but not amino acid sequence, homology is the nucleotide positioning loop (NPL) that closes down on the enzyme active site upon binding of ATP. This loop region has been implicated in facilitating phosphoryl transfer in protein kinases; however, there is no primary sequence conservation between APHs and protein kinases in the NPL. There is an invariant Ser residue in all APH NPL regions, however. This residue in APH(3')-IIIa (Ser27), an enzyme widespread in aminoglycoside-resistant Enterococci, Streptococci, and Staphylococci, directly interacts with the beta-phosphate of ATP through the Ser hydroxymethyl group and the amide hydrogen in the 3D structure of the enzyme. Mutagenesis of this residue to Ala and Pro supported a role for the Ser amide hydrogen in nucleotide capture and phosphoryl transfer. A molecular model of the proposed dissociative transition state, which is consistent with all of the available mechanistic data, suggested a role for the amide of the adjacent Met26 in phosphoryl transfer. Mutagenesis studies confirmed the importance of the amide hydrogen and suggest a mechanism where Ser27 anchors the ATP beta-phosphate facilitating bond breakage with the gamma-phosphate during formation of the metaphosphate-like transition, which is stabilized by interaction with the amide hydrogen of Met26. The APH NPL therefore acts as a lever, promoting phosphoryl transfer to the aminoglycoside substrate, with the biological outcome of clinically relevant antibiotic resistance.     

Role of Serine 286 in cosubstrate binding and catalysis of a flavonol O-methyltransferase.

O-Methyltransferases catalyze the transfer of the methyl groups of S-adenosyl-L-methionine to specific hydroxyl groups of several classes of flavonoid compounds. Of the several cDNA clones isolated from a Chrysosplenium americanum library, FOMT3' encodes the 3'/5'-O-methylation of partially methylated flavonols. The recombinant protein of another clone, FOMTx which differs from FOMT3' by a single amino acid residue (Ser286Arg) exhibits no enzymatic activity towards any of the flavonoid substrates tested. Replacement of Ser 286 in FOMT3' with either Ala, Leu, Lys or Thr, almost abolished O-methyltransferase activity. In contrast with FOMT3', no photoaffinity labeling could be achieved using [(14)CH(3)]AdoMet with the mutant recombinant proteins indicating that Ser 286 is also required for cosubstrate binding. These results are corroborated by isothermal titration microcalorimetry measurements. Circular dichroism spectra ruled out any significant conformational differences in the secondary structures of both FOMT3' and Ser286Arg. Modeling FOMT3' on the structure of chalcone methyltransferase indicates that serine 286 is greater than 10 A from any of the residues of the active site or the AdoMet binding site of FOMT3'. At the same time, residues 282 to 290 are conserved in most of the Chrysosplenium americanum OMTs. These residues form a large part of the subunit interface, and at least five of these residues are within 4 A of the opposing subunit. It would appear, therefore, that mutations in Ser286 exert their influence by altering the contacts between the subunits and that these contacts are necessary for maintaining the integrety of the AdoMet binding site and active site of this group of enzymes.     

Histidine 167 is the phosphate acceptor in glucose-6-phosphatase-beta forming a phosphohistidine enzyme intermediate during catalysis

The glucose-6-phosphatase (Glc-6-Pase) family comprises two active endoplasmic reticulum (ER)-associated isozymes: the liver/kidney/intestine Glc-6-Pase-alpha and the ubiquitous Glc-6-Pase-beta. Both share similar kinetic properties. Sequence alignments predict the two proteins are structurally similar. During glucose 6-phosphate (Glc-6-P) hydrolysis, Glc-6-Pase-alpha, a nine-transmembrane domain protein, forms a covalently bound phosphoryl enzyme intermediate through His(176), which lies on the lumenal side of the ER membrane. We showed that Glc-6-Pase-beta is also a nine-transmembrane domain protein that forms a covalently bound phosphoryl enzyme intermediate during Glc-6-P hydrolysis. However, the intermediate was not detectable in Glc-6-Pase-beta active site mutants R79A, H114A, and H167A. Using [(32)P]Glc-6-P coupled with cyanogen bromide mapping, we demonstrated that the phosphate acceptor in Glc-6-Pase-beta is His(167) and that it lies inside the ER lumen with the active site residues, Arg(79) and His(114). Therefore Glc-6-Pase-alpha and Glc-6-Pase-beta share a similar active site structure, topology, and mechanism of action.     

Molecular mechanism of aminoglycoside antibiotic kinase APH(3')-IIIa: roles of conserved active site residues

The aminoglycoside antibiotic kinases (APHs) constitute a clinically important group of antibiotic resistance enzymes. APHs share structural and functional homology with Ser/Thr and Tyr kinases, yet only five amino acids are invariant between the two groups of enzymes and these residues are all located within the nucleotide binding regions of the proteins. We have performed site-directed mutagenesis on all five conserved residues in the aminoglycoside kinase APH(3')-IIIa: Lys(44) and Glu(60) involved in ATP capture, a putative active site base required for deprotonating the incoming aminoglycoside hydroxyl group Asp(190), and the Mg(2+) ligands Asn(195) and Glu(208), which coordinate two Mg(2+) ions, Mg1 and Mg2. Previous structural and mutagenesis evidence have demonstrated that Lys(44) interacts directly with the phosphate groups of ATP; mutagenesis of invariant Glu(60), which forms a salt bridge with the epsilon-amino group of Lys(44), demonstrated that this residue does not play a critical role in ATP recognition or catalysis. Results of mutagenesis of Asp(190) were consistent with a role in proper positioning of the aminoglycoside hydroxyl during phosphoryl transfer but not as a general base. The Mg1 and Mg2 ligand Asp(208) was found to be absolutely required for enzyme activity and the Mg2 ligand Asn(195) is important for Mg.ATP recognition. The mutagenesis results together with solvent isotope, solvent viscosity, and divalent cation requirements are consistent with a dissociative mechanism of phosphoryl transfer where initial substrate deprotonation is not essential for phosphate transfer and where Mg2 and Asp(208) likely play a critical role in stabilization of a metaphosphate-like transition state. These results lay the foundation for the synthesis of transition state mimics that could reverse aminoglycoside antibiotic resistance in vivo.     

Evidence that both arginine 102 and arginine 747 are involved in substrate binding to neutral endopeptidase (EC 3.4.24.11)

Neutral endopeptidase (EC 3.4.24.11, NEP) is a Zn-metallopeptidase involved in the degradation of biologically active peptides, notably the enkephalins and atrial natriuretic peptide. Recently, the structure of the active site of this enzyme has been probed by site-directed mutagenesis, and 4 amino acid residues have been identified, namely 2 histidines (His583 and His587), which act as zinc-binding ligands, a glutamate (Glu584) involved in catalysis, and an arginine residue (Arg102), suggested to participate in substrate binding. Site-directed mutagenesis has now been used to investigate the role of 4 other arginine residues (Arg408, Arg409, Arg659, and Arg747) that have been proposed as possible active site residues and to further analyze the role of Arg102. In each case, the arginine was replaced with a methionine, and both enzymatic activity and the IC50 values of several NEP inhibitors were measured for the mutated enzymes and compared to wild-type enzyme. The results suggest that 2 arginines, Arg102 and Arg747, could both be important for substrate and inhibitor binding. Arg747 seems to be positioned to interact with the carbonyl amide group of the P'1 residue and can be modified when the enzyme is treated with the arginine-specific reagents phenylglyoxal and butanedione. Arg102 could be positioned to interact with the free carboxyl group of a P'2 residue in some substrates and inhibitors and can be modified by phenylglyoxal but not by butanedione. The results could explain the dual dipeptidylcarboxypeptidase and endopeptidase nature of NEP.     

Caught in the act: the structure of phosphorylated beta-phosphoglucomutase from Lactococcus lactis

Phosphoglucomutases catalyze the interconversion of D-glucose 1-phosphate and D-glucose 6-phosphate, a reaction central to energy metabolism in all cells and to the synthesis of cell wall polysaccharides in bacterial cells. Two classes of phosphoglucomutases (alpha-PGM and beta-PGM) are distinguished on the basis of their specificity for alpha- and beta-glucose-1-phosphate. beta-PGM is a member of the haloacid dehalogenase (HAD) superfamily, which includes the sarcoplasmic Ca(2+)-ATPase, phosphomannomutase, and phosphoserine phosphatase. beta-PGM is unusual among family members in that the common phosphoenzyme intermediate exists as a stable ground-state complex in this enzyme. Herein we report, for the first time, the three-dimensional structure of a beta-PGM and the first view of the true phosphoenzyme intermediate in the HAD superfamily. The crystal structure of the Mg(II) complex of phosphorylated beta-phosphoglucomutase (beta-PGM) from Lactococcus lactis has been determined to 2.3 A resolution by multiwavelength anomalous diffraction (MAD) phasing on selenomethionine, and refined to an R(cryst) = 0.24 and R(free) = 0.28. The active site of beta-PGM is located between the core and the cap domain and is freely solvent accessible. The residues within a 6 A radius of the phosphorylated Asp8 include Asp10, Thr16, Ser114, Lys145, Glu169, and Asp170. The cofactor Mg(2+) is liganded with octahedral coordination geometry by the carboxylate side chains of Asp8, Glu169, Asp170, and the backbone carbonyl oxygen of Asp10 along with one oxygen from the Asp8-phosphoryl group and one water ligand. The phosphate group of the phosphoaspartyl residue, Asp8, interacts with the side chains of Ser114 and Lys145. The absence of a base residue near the aspartyl phosphate group accounts for the persistence of the phosphorylated enzyme under physiological conditions. Substrate docking shows that glucose-6-P can bind to the active site of phosphorylated beta-PGM in such a way as to position the C(1)OH near the phosphoryl group of the phosphorylated Asp8 and the C(6) phosphoryl group near the carboxylate group of Asp10. This result suggests a novel two-base mechanism for phosphoryl group transfer in a phosphorylated sugar.     

Roles of the N-terminal domain and remote substrate binding subsites in activity of the debranching barley limit dextrinase

Barley limit dextrinase (HvLD) of glycoside hydrolase family 13 is the sole enzyme hydrolysing α-1,6-glucosidic linkages from starch in the germinating seed. Surprisingly, HvLD shows 150- and 7-fold higher activity towards pullulan and β-limit dextrin, respectively, than amylopectin. This is investigated by mutational analysis of residues in the N-terminal CBM-21-like domain (Ser14Arg, His108Arg, Ser14Arg/His108Arg) and at the outer subsites +2 (Phe553Gly) and +3 (Phe620Ala, Asp621Ala, Phe620Ala/Asp621Ala) of the active site. The Ser14 and His108 mutants mimic natural LD variants from sorghum and rice with elevated enzymatic activity. Although situated about 40 Å from the active site, the single mutants had 15–40% catalytic efficiency compared to wild type for the three polysaccharides and the double mutant retained 27% activity for β-limit dextrin and 64% for pullulan and amylopectin. These three mutants hydrolysed 4,6-O-benzylidene-4-nitrophenyl-6³-α-d-maltotriosyl-maltotriose (BPNPG3G3) with 51–109% of wild-type activity. The results highlight that the N-terminal CBM21-like domain plays a role in activity. Phe553 and the highly conserved Trp512 sandwich a substrate main chain glucosyl residue at subsite +2 of the active site, while substrate contacts of Phe620 and Asp621 at subsite +3 are less prominent. Phe553Gly showed 47% and 25% activity on pullulan and BPNPG3G3, respectively having a main role at subsite +2. By contrast at subsite +3, Asp621Ala increased activity on pullulan by 2.4-fold, while Phe620Ala/Asp621Ala retained only 7% activity on pullulan albeit showed 25% activity towards BPNPG3G3. This outcome supports that the outer substrate binding area harbours preference determinants for the branched substrates amylopectin and β-limit dextrin.     

Influence of key residues on the reaction mechanism of the cAMP-dependent protein kinase

The reaction mechanism of the catalytic phosphoryl transfer of cAMP-dependent protein kinase (cAPK) was investigated by semi-empirical AM1 molecular orbital computations of an active site model system derived from the crystal structure of the catalytic subunit of the enzyme. The activation barrier is calculated as 20.7 kcal mol(-1) and the reaction itself to be exothermic by 12.2 kcal mol(-1). The active site residue Asp166, which was often proposed to act as a catalytic base, does not accept a proton in any of the reaction steps. Instead, the hydroxyl hydrogen of serine is shifted to the simultaneously transferred phosphate group of ATP. Although the calculated transition state geometry indicates an associative phosphoryl transfer, no concentration of negative charge is found. To study the influence of protein mutations on the reaction mechanism, we compared two-dimensional energy hypersurfaces of the protein kinase wild-type model and a corresponding mutant in which Asp166 was replaced by alanine. Surprisingly, they show similar energy profiles despite the experimentally known decrease of catalytic activity for corresponding mutants. Furthermore, a model structure was examined, where the charged NH3 group of Lys168 was replaced by a neutral methyl group. The energetic hypersurface of this hypothetical mutant shows two possible pathways for phosphoryl transfer, which both require significantly higher activation energies than the other systems investigated, while the energetic stabilization of the reaction product is similar in all systems. As the position of the amino acid side chains and the substrate peptide is virtually unchanged in all model systems, our results suggest that the exchange of Asp166 by other amino acid is less important to the phosphoryl transfer itself, but crucial to maintain the configuration of the active site in vivo. The positively charged side chain of Lys168, however, is necessary to stabilize the intermediate reaction states, particularly the side chain of the substrate peptide.     

Enzyme I of the phosphoenolpyruvate:sugar phosphotransferase system. In vitro intragenic complementation: the roles of Arg126 in phosphoryl transfer and the C-terminal domain in dimerization

Enzyme I mutants of the Salmonella typhimurium phosphoenolpyruvate:sugar phosphotransferase system (PTS), which show in vitro intragenic complementation, have been identified as Arg126Cys (strain SB1690 ptsI34), Gly356Ser (strain SB1681 ptsI16), and Arg375Cys (strain SB1476 ptsI17). The mutation Arg126Cys is in the N-terminal HPr-binding domain, and complements Gly356Ser and Arg375Cys enzyme I mutations located in the C-terminal phosphoenolpyruvate(PEP)-binding domain. Complementation results in the formation of unstable heterodimers. None of the mutations alters the K(m) for HPr, which is phosphorylated by enzyme I. Arg126 is a conserved residue; the Arg126Cys mutation gives a V(max) of 0.04% wild-type, establishing a role in phosphoryl transfer. The Gly356Ser and Arg375Cys mutations reduce enzyme I V(max) to 4 and 2%, respectively, and for both, the PEP K(m) is increased from 0.1 to 3 mM. It is concluded that this activity was from the monomer, rather than the dimer normally found in assays of wild-type. In the presence of Arg126Cys enzyme, V(max) for Gly356Ser and Arg375Cys enzymes I increased 6- and 2-fold, respectively; the K(m) for PEP decreased to <10 microM, but the K(m) became dependent upon the stability of the heterodimer in the assay. Gly356 is conserved in enzyme I and pyruvate phosphate dikinase, which is a homologue of enzyme I, and this residue is part of a conserved sequence in the subunit interaction site. Gly356Ser mutation impairs enzyme I dimerization. The mutation Arg375Cys also impairs dimerization, but the equivalent residue in pyruvate phosphate dikinase is not associated with the subunit interaction site. A 37 000 Da, C-terminal domain of enzyme I has been expressed and purified; it dimerizes and complements Gly356Ser and Arg375Cys enzymes I proving that the association/dissociation properties of enzyme I are a function of the C-terminal domain.     

Arginine coordination in enzymatic phosphoryl transfer: evaluation of the effect of Arg166 mutations in Escherichia coli alkaline phosphatase

Arginine residues are commonly found in the active sites of enzymes catalyzing phosphoryl transfer reactions. Numerous site-directed mutagenesis experiments establish the importance of these residues for efficient catalysis, but their role in catalysis is not clear. To examine the role of arginine residues in the phosphoryl transfer reaction, we have measured the consequences of mutations to arginine 166 in Escherichia coli alkaline phosphatase on hydrolysis of ethyl phosphate, on individual reaction steps in the hydrolysis of the covalent enzyme-phosphoryl intermediate, and on thio substitution effects. The results show that the role of the arginine side chain extends beyond its positive charge, as the Arg166Lys mutant is as compromised in activity as Arg166Ser. Through measurement of individual reaction steps, we construct a free energy profile for the hydrolysis of the enzyme-phosphate intermediate. This analysis indicates that the arginine side chain strengthens binding by approximately 3 kcal/mol and provides an additional 1-2 kcal/mol stabilization of the chemical transition state. A 2.1 A X-ray diffraction structure of Arg166Ser AP is presented, which shows little difference in enzyme structure compared to the wild-type enzyme but shows a significant reorientation of the bound phosphate. Altogether, these results support a model in which the arginine contributes to catalysis through binding interactions and through additional transition state stabilization that may arise from complementarity of the guanidinum group to the geometry of the trigonal bipyramidal transition state.     

Ligand-induced structural changes in adenosine 5'-phosphosulfate kinase from Penicillium chrysogenum

Adenosine 5'-phosphosulfate (APS) kinase catalyzes the second reaction in the two-step, ATP-dependent conversion of inorganic sulfate to 3'-phosphoadenosine 5'-phosphosulfate (PAPS). PAPS serves as the sulfuryl donor for the biosynthesis of all sulfate esters and also as a precursor of reduced sulfur biomolecules in many organisms. Previously, we determined the crystal structure of ligand-free APS kinase from the filamentous fungus, Penicillium chrysogenum [MacRae et al. (2000) Biochemistry 39, 1613-1621]. That structure contained a protease-susceptible disordered region ("mobile lid"; residues 145-170). Addition of MgADP and APS, which together promote the formation of a nonproductive "dead-end" ternary complex, protected the lid from trypsin. This report presents the 1.43 A resolution crystal structure of APS kinase with both ADP and APS bound at the active site and the 2.0 A resolution structure of the enzyme with ADP alone bound. The mobile lid is ordered in both complexes and is shown to provide part of the binding site for APS. That site is formed primarily by the highly conserved Arg 66, Arg 80, and Phe 75 from the protein core and Phe 165 from the mobile lid. The two Phe residues straddle the adenine ring of bound APS. Arg 148, a completely conserved residue, is the only residue in the mobile lid that interacts directly with bound ADP. Ser 34, located in the apex of the P-loop, hydrogen-bonds to the 3'-OH of APS, the phosphoryl transfer target. The structure of the binary E.ADP complex revealed further changes in the active site and N-terminal helix that occur upon the binding/release of (P)APS.     

Identification of the cysteine residue exposed by the conformational change in pig heart succinyl-CoA:3-ketoacid coenzyme A transferase on binding coenzyme A

Succinyl-CoA:3-ketoacid CoA transferase (SCOT) transfers CoA from succinyl-CoA to acetoacetate via a thioester intermediate with its active site glutamate residue, Glu 305. When CoA is linked to the enzyme, a cysteine residue can now be rapidly modified by 5,5'-dithiobis(2-nitrobenzoic acid), reflecting a conformational change of SCOT upon formation of the thioester. Since either Cys 28 or Cys 196 could be the target, each was mutated to Ser to distinguish between them. Like wild-type SCOT, the C196S mutant protein was modified rapidly in the presence of acyl-CoA substrates. In contrast, the C28S mutant protein was modified much more slowly under identical conditions, indicating that Cys 28 is the residue exposed on binding CoA. The specific activity of the C28S mutant protein was unexpectedly lower than that of wild-type SCOT. X-ray crystallography revealed that Ser adopts a different conformation than the native Cys. A chloride ion is bound to one of four active sites in the crystal structure of the C28S mutant protein, mimicking substrate, interacting with Lys 329, Asn 51, and Asn 52. On the basis of these results and the studies of the structurally similar CoA transferase from Escherichia coli, YdiF, bound to CoA, the conformational change in SCOT was deduced to be a domain rotation of 17 degrees coupled with movement of two loops: residues 321-329 that bury Cys 28 and interact with succinate or acetoacetate and residues 374-386 that interact with CoA. Modeling this conformational change has led to the proposal of a new mechanism for catalysis by SCOT.     

Experimental and computational investigations of Ser10 and Lys13 in the binding and cleavage of DNA substrates by Escherichia coli DNA topoisomerase I

Ser10 and Lys13 found near the active site tyrosine of Escherichia coli DNA topoisomerase I are conserved among the type IA topoisomerases. Site-directed mutagenesis of these two residues to Ala reduced the relaxation and DNA cleavage activity, with a more severe effect from the Lys13 mutation. Changing Ser10 to Thr or Lys13 to Arg also resulted in loss of DNA cleavage and relaxation activity of the enzyme. In simulations of the open form of the topoisomerase–DNA complex, Lys13 interacts directly with Glu9 (proposed to be important in the catalytic mechanism). This interaction is removed in the K13A mutant, suggesting the importance of lysine as either a proton donor or a stabilizing cation during strand cleavage, while the Lys to Arg mutation significantly distorts catalytic residues. Ser10 forms a direct hydrogen bond with a phosphate group near the active site and is involved in direct binding of the DNA substrate; this interaction is disturbed in the S10A and S10T mutants. This combination of a lysine and a serine residue conserved in the active site of type IA topoisomerases may be required for correct positioning of the scissile phosphate and coordination of catalytic residues relative to each other so that DNA cleavage and subsequent strand passage can take place.     

Seeing the process of histidine phosphorylation in human bisphosphoglycerate mutase

Bisphosphoglycerate mutase is an erythrocyte-specific enzyme catalyzing a series of intermolecular phosphoryl group transfer reactions. Its main function is to synthesize 2,3-bisphosphoglycerate, the allosteric effector of hemoglobin. In this paper, we directly observed real-time motion of the enzyme active site and the substrate during phosphoryl transfer. A series of high resolution crystal structures of human bisphosphoglycerate mutase co-crystallized with 2,3-bisphosphoglycerate, representing different time points in the phosphoryl transfer reaction, were solved. These structures not only clarify the argument concerning the substrate binding mode for this enzyme family but also depict the entire process of the key histidine phosphorylation as a "slow movie". It was observed that the enzyme conformation continuously changed during the different states of the reaction. These results provide direct evidence for an "in line" phosphoryl transfer mechanism, and the roles of some key residues in the phosphoryl transfer process are identified.     

Reduced enzymatic activity of glucokinase after affinity labeling: results from spectrophotometry and electrospray ionization mass spectrometry

Glucokinase catalyzes phosphoryl group transfer from ATP to glucose to form glucose-6-phosphate in the first step of cellular metabolism. While the location of the ATP-binding site of glucokinase was proposed recently, limited information exists on its conformation or the key amino acids involved in substrate binding. Affinity labeling with phenylglyoxal is used to probe possible Arg residues involved in ATP binding. Electrospray ionization mass spectrometry indicates that reaction of purified glucokinase with phenylglyoxal results in as many as six or seven sites of modification, suggesting nonspecific modification. However, preincubation of glucokinase with glucose followed by reaction with phenylglyoxal reveals only two sites of modification. Glucokinase activity assays show that enzyme preincubated with glucose possesses residual activity corresponding to the fraction of unmodified enzyme observed by mass spectrometry, strongly suggesting that glucokinase preincubated with glucose is specifically labeled and inactivated upon modification by phenylglyoxal. The data support the existing conformational model of glucokinase.     

Mutational replacements in subtilisin 309. Val104 has a modulating effect on the P4 substrate preference.

The previous notion that the amino acid side chain at position 104 of subtilisins is involved in the binding of the side chain at position P4 of the substrate has been investigated. The amino acid residue Val104 in subtilisin 309 has been replaced by Ala, Arg, Asp, Phe, Ser, Trp and Tyr by site-directed mutagenesis. It is shown that the P4 specificity of this enzyme is not determined solely by the amino acid residue occupying position 104, as the enzyme exhibits a marked preference for aromatic groups in P4, regardless of the nature of the position-104 residue. With hydrophilic amino acid residues at this position, no involvement is seen in binding of either hydrophobic or hydrophilic amino acid residues at position P4 of the substrates. The substrate with Asp in P4 is an exception, as the preference for this substrate is increased dramatically by introduction of an arginine residue at position 104 in the enzyme, presumably due to a substrate-induced conformational change. However, when position 104 is occupied by hydrophobic residues, it is highly involved in binding of hydrophobic amino acid residues, either by increasing the hydrophobicity of S4 or by determining the size of the pocket. The results suggest that the amino acid residue at position 104 is mobile such that it is positioned in the S4 binding site only when it can interact favourably with the substrate's side chain at position P4.     

DNA recombination and RNA cleavage activities of the Flp protein: roles of two histidine residues in the orientation and activation of the nucleophile for strand cleavage.

Using a combination of DNA and hybrid DNA-RNA substrates, we have analyzed the mechanism of phosphoryl transfer by the Flp site-specific recombinase in three different reactions: DNA strand breakage and joining, and two types of RNA cleavage activities. These reactions were then used to characterize Flp variants altered at His309 and His345, amino acid residues that are in close proximity to two key catalytic residues (Arg308 and Tyr343). These histidine residues are important for strand cutting by Tyr343, the active-site nucleophile of Flp, but neither residue contributes to the type II RNA cleavage activity or to the strand-joining reaction in a pre-cleaved substrate. Strand cleavage reactions using small, diffusible nucleophiles indicate that this histidine pair contributes to the correct positioning and activation of Tyr343 within the shared active site of Flp. The implications of these results are evaluated against the recently solved crystal structure of Flp in association with a Holliday junction.     

Arginine residues in the active site of human phenol sulfotransferase (SULT1A1)

Cytosolic sulfotransferases (STs) catalyze the sulfation of hydroxyl containing compounds. Human phenol sulfotransferase (SULT1A1) is the major human ST that catalyzes the sulfation of simple phenols. Because of its broad substrate specificity and lack of endogenous substrates, the biological function of SULT1A1 is believed to be an important detoxification enzyme. In this report, amino acid modification, computer structure modeling, and site-directed mutagenesis were used for studies of Arg residues in the active site of SULT1A1. The Arg-specific modification reagent, 2,3-butanedione, inactivated SULT1A1 in an efficient, time- and concentration-dependent manner, suggesting Arg residues play an important role in the catalytic activity of SULT1A1. According to the computer model, Arg78, Arg130, and Arg257 may be important for SULT1A1 catalytic activity. Site-directed mutagenesis results demonstrated that the positive charge on Arg78 is not critical for SULT1A1 because R78A is still active. In contrast, a negative charge at this position, R78E, completely inactivated SULT1A1. Arg78 is in close proximity to the site of sulfuryl group transfer. Arg257 is located very close to the 3'-phosphate in adenosine 3'-phosphate 5'-phosphosulfate (PAPS). Site-directed mutagenesis demonstrated that Arg257 is critical for SULT1A1: both R257A and R257E are inactive. Although Arg130 is also located very close to the 3'-phosphate of PAPS, R130A and R130E are still active, suggesting that Arg130 is not a critical residue for the catalytic activity of SULT1A1. Computer modeling suggests that the ionic interaction between the positive charge on Arg257, and the negative charge on 3'-phosphate is the primary force stabilizing the specific binding of PAPS.     

Crystal structure of the reduced Schiff-base intermediate complex of transaldolase B from Escherichia coli: mechanistic implications for class I aldolases.

Transaldolase catalyzes transfer of a dihydroxyacetone moiety from a ketose donor to an aldose acceptor. During catalysis, a Schiff-base intermediate between dihydroxyacetone and the epsilon-amino group of a lysine residue at the active site of the enzyme is formed. This Schiff-base intermediate has been trapped by reduction with potassium borohydride, and the crystal structure of this complex has been determined at 2.2 A resolution. The overall structures of the complex and the native enzyme are very similar; formation of the intermediate induces no large conformational changes. The dihydroxyacetone moiety is covalently linked to the side chain of Lys 132 at the active site of the enzyme. The Cl hydroxyl group of the dihydroxyacetone moiety forms hydrogen bonds to the side chains of residues Asn 154 and Ser 176. The C3 hydroxyl group interacts with the side chain of Asp 17 and Asn 35. Based on the crystal structure of this complex a reaction mechanism for transaldolase is proposed.     

Phosphorylation and mutations of Ser(16) in human phenylalanine hydroxylase. Kinetic and structural effects

Phosphorylation of phenylalanine hydroxylase (PAH) at Ser(16) by cyclic AMP-dependent protein kinase is a post-translational modification that increases its basal activity and facilitates its activation by the substrate l-Phe. So far there is no structural information on the flexible N-terminal tail (residues 1-18), including the phosphorylation site. To get further insight into the molecular basis for the effects of phosphorylation on the catalytic efficiency and enzyme stability, molecular modeling was performed using the crystal structure of the recombinant rat enzyme. The most probable conformation and orientation of the N-terminal tail thus obtained indicates that phosphorylation of Ser(16) induces a local conformational change as a result of an electrostatic interaction between the phosphate group and Arg(13) as well as a repulsion by Glu(280) in the loop at the entrance of the active site crevice structure. The modeled reorientation of the N-terminal tail residues (Met(1)-Leu(15)) on phosphorylation is in agreement with the observed conformational change and increased accessibility of the substrate to the active site, as indicated by circular dichroism spectroscopy and the enzyme kinetic data for the full-length phosphorylated and nonphosphorylated human PAH. To further validate the model we have prepared and characterized mutants substituting Ser(16) with a negatively charged residue and found that S16E largely mimics the effects of phosphorylation of human PAH. Both the phosphorylated enzyme and the mutants with acidic side chains instead of Ser(16) revealed an increased resistance toward limited tryptic proteolysis and, as indicated by circular dichroism spectroscopy, an increased content of alpha-helical structure. In agreement with the modeled structure, the formation of an Arg(13) to Ser(16) phosphate salt bridge and the conformational change of the N-terminal tail also explain the higher stability toward limited tryptic proteolysis of the phosphorylated enzyme. The results obtained with the mutant R13A and E381A further support the model proposed for the molecular mechanism for the activation of the enzyme by phosphorylation.