PARTIAL PURIFICATION AND KINETICS OF γ-GLUTAMYL TRANSPEPTIDASE FROM BOVINE CHOROID PLEXUS

Abstract— γ-Glutamyl transpeptidase from bovine choroid plexus has been shown to be a membrane-bound enzyme. Partial purification of the enzyme has been accomplished using detergent extraction and ammonium sulfate fractionation. Important determinants of enzymatic activity with acceptor substrates included chain length, stereoisomerism, and amino acid composition of the acceptors. L-Methionine was the best amino acid substrate and its corresponding peptides L-methionylmethionine and L-methionyl-L-serine were also good γ-glutamyl acceptors. L-Alanine and glycine were poor acceptor substrates; whereas, some peptides containing these amino acids were excellent substrates. Glycylglycine was significantly more effective as a γ-glutamyl acceptor than glycine, triglycine, or tetraglycine. L-Alanylglycine was a superior acceptor to glycine, L-alanine, or L-alanylglycylglycine, while the D-isomer of alanylglycine was only minimally effective as an acceptor substrate. In general glycyl peptides were the best acceptor substrates examined. Our findings that γ-glutamyl transpeptidase could catalyze the transfer of γ-glutamyl groups to glycylglycyl-L-alanine and L-alanylglycylglycine are of special interest, since few examples of tripeptide acceptors for the enzyme have been found. It is suggested that γ-glutamyl transpeptidase might play a role in the inactivation and/or transport of biologically active peptides.     

Transpeptidation reactions of a specific substrate catalyzed by the Streptomyces R61 DD-peptidase: the structural basis of acyl acceptor specificity

Bacterial dd-peptidases, the targets of beta-lactam antibiotics, are believed to catalyze d-alanyl-d-alanine carboxypeptidase and transpeptidase reactions in vivo. To date, however, there have been few concerted attempts to explore the kinetic and thermodynamic specificities of the active sites of these enzymes. We have shown that the peptidoglycan-mimetic peptide, glycyl-l-alpha-amino-epsilon-pimelyl-d-alanyl-d-alanine, 1, is a very specific and reactive carboxypeptidase substrate of the Streptomyces R61 dd-peptidase [Anderson, J. W., and Pratt, R. F. (2000) Biochemistry 39, 12200-12209]. In the present paper, we explore the transpeptidation reactions of this substrate, where the enzyme catalyzes transfer of the glycyl-l-alpha-amino-epsilon-pimelyl-d-alanyl moiety to amines. These reactions are believed to occur through capture of an acyl-enzyme intermediate by amines rather than water. Experiments show that effective acyl acceptors require a carboxylate group and thus are amino acids and peptides. d(but not l)-amino acids, analogues of the leaving group of 1, are good acceptors. The effectiveness of d-alanine as an acceptor increases with pH, suggesting that the bound and reactive form of an amino acid acceptor is the free amine. Certain glycyl-l(but not d)-amino acids, such as glycyl-l-alanine and glycyl-l-phenylalanine, are also good acceptors. These molecules may resemble the N-terminus of the Streptomyces stem peptides that, presumably, are the acceptors in vivo. The acyl acceptor binding site therefore demonstrates a dual specificity. That d-alanyl-l-alanine shows little activity as an acceptor suggested that, on binding of acceptors to the enzyme, the carboxylate of d-amino acids does not overlap with the peptide carbonyl group of glycyl-l-amino acids. Molecular modeling of transpeptidation tetrahedral intermediates and products demonstrated the likely structural bases for the stereospecificity of the acceptors and the nature of the dual function acceptor binding site. For both groups of acceptors, the terminal carboxylate appeared to be anchored at the active site by interaction with Arg 285 and Thr 299.     

A single amino acid in the hypervariable stem domain of vertebrate alpha1,3/1,4-fucosyltransferases determines the type 1/type 2 transfer. Characterization of acceptor substrate specificity of the lewis enzyme by site-directed mutagenesis

Alignment of 15 vertebrate alpha1,3-fucosyltransferases revealed one arginine conserved in all the enzymes employing exclusively type 2 acceptor substrates. At the equivalent position, a tryptophan was found in FUT3-encoded Lewis alpha1,3/1,4-fucosyltransferase (Fuc-TIII) and FUT5-encoded alpha1,3/1,4-fucosyltransferase, the only fucosyltransferases that can also transfer fucose in alpha1, 4-linkage. The single amino acid substitution Trp111 --> Arg in Fuc-TIII was sufficient to change the specificity of fucose transfer from H-type 1 to H-type 2 acceptors. The additional mutation of Asp112 --> Glu increased the type 2 activity of the double mutant Fuc-TIII enzyme, but the single substitution of the acidic residue Asp112 in Fuc-TIII by Glu decreased the activity of the enzyme and did not interfere with H-type 1/H-type 2 specificity. In contrast, substitution of Arg115 in bovine futb-encoded alpha1, 3-fucosyltransferase (Fuc-Tb) by Trp generated a protein unable to transfer fucose either on H-type 1 or H-type 2 acceptors. However, the double mutation Arg115 --> Trp/Glu116 --> Asp of Fuc-Tb slightly increased H-type 1 activity. The acidic residue adjacent to the candidate amino acid Trp/Arg seems to modulate the relative type 1/type 2 acceptor specificity, and its presence is necessary for enzyme activity since its substitution by the corresponding amide inactivated both Fuc-TIII and Fuc-Tb enzymes.     

C-terminal amino acids of Helicobacter pylori alpha1,3/4 fucosyltransferases determine type I and type II transfer

The alpha1,3/4 fucosyltransferase (FucT) enzyme from Helicobacter pylori catalyzes fucose transfer from donor GDP-beta-l-fucose to the GlcNAc group of two series of acceptor substrates in H. pylori lipopolysaccharide: betaGal1,3betaGlcNAc (Type I) or betaGal1,4betaGlcNAc (Type II). Fucose is added either in alpha1,3 linkage of Type II acceptor to produce Lewis X or in alpha1,4 linkage of Type I acceptor to produce Lewis A, respectively. H. pylori FucTs from different strains have distinct Type I or Type II substrate specificities. FucT in H. pylori strain NCTC11639 has an exclusive alpha1,3 activity because it recognizes only Type II substrates, whereas FucT in H. pylori strain UA948 can utilize both Type II and Type I acceptors; thus it has both alpha1,3 and alpha1,4 activity, respectively. To identify elements conferring substrate specificity, 12 chimeric FucTs were constructed by domain swapping between 11639FucT and UA948FucT and characterized for their ability to transfer fucose to Type I and Type II acceptors. Our results indicate that the C-terminal region of H. pylori FucTs controls Type I and Type II acceptor specificity. In particular, the highly divergent C-terminal portion, seven amino acids DNPFIFC at positions 347-353 in 11639FucT, and the corresponding 10 amino acids CNDAHYSALH at positions 345-354 in UA948FucT, controls the Type I and Type II acceptor recognition. This is the opposite of mammalian FucTs where acceptor preference is determined primarily by the N-terminal residues in the hypervariable stem domain.     

Substrate specificity characterization of recombinant metallo oligo-peptidases thimet oligopeptidase and neurolysin

We report a systematic and detailed analysis of recombinant neurolysin (EC 3.4.24.16) specificity in parallel with thimet oligopeptidase (TOP, EC 3.4.24.15) using Bk sequence and its C- and N-terminal extensions as in human kininogen as motif for synthesis of internally quenched fluorescent substrates. The influence of the substrate size was investigated, and the longest peptide susceptible to TOP and neurolysin contains 17 amino acids. The specificities of both oligopeptidases to substrate sites P(4) to P(3)' were also characterized in great detail using seven series of peptides based on Abz-GFSPFRQ-EDDnp taken as reference substrate. Most of the peptides were hydrolyzed at the bond corresponding to P(4)-F(5) in the reference substrate and some of them were hydrolyzed at this bond or at F(2)-S(3) bond. No restricted specificity was found for P(1)' as found in thermolysin as well for P(1) substrate position, however the modifications at this position (P(1)) showed to have large influence on the catalytic constant and the best substrates for TOP contained at P(1), Phe, Ala, or Arg and for neurolysin Asn or Arg. Some amino acid residues have large influence on the K(m) constants independently of its position. On the basis of these results, we are hypothesizing that some amino acids of the substrates can bind to different sub-sites of the enzyme fitting P-F or F-S bond, which requires rapid interchange for the different forms of interaction and convenient conformations of the substrate in order to expose and fit the cleavage bonds in correct position for an efficient hydrolysis. Finally, this plasticity of interaction with the substrates can be an essential property for a class of cytosolic oligopeptidases that are candidates to participate in the selection of the peptides to be presented by the MHC class I.     

Three-dimensional structures of noncovalent complexes of <Emphasis Type="Italic">Citrobacter freundii</Emphasis> methionine γ-lyase with substrates

Crystal structures of Citrobacter freundii methionine γ-lyase complexes with the substrates of γ-(L-1-amino-3-methylthiopropylphosphinic acid) and β-(S-ethyl-L-cysteine) elimination reactions and the competitive inhibitor L-nor-leucine have been determined at 1.45, 1.8, and 1.63 Å resolution, respectively. All three amino acids occupy the active site of the enzyme but do not form a covalent bond with pyridoxal 5′-phosphate. Hydrophobic interactions between the active site residues and the side groups of the substrates and the inhibitor are supposed to cause noncovalent binding. Arg374 and Ser339 are involved in the binding of carboxyl groups of the substrates and the inhibitor. The hydroxyl of Tyr113 is a potential acceptor of a proton from the amino groups of the amino acids.     

Substrate specificity at the P1' site of Escherichia coli OmpT under denaturing conditions

Though OmpT has been reported to mainly cleave the peptide bond between consecutive basic amino acids, we identified more precise substrate specificity by using a series of modified substrates, termed PRX fusion proteins, consisting of 184 residues. The cleavage site of the substrate PRR was Arg140-Arg141 and the modified substrates PRX substituted all 19 natural amino acids at the P1' site instead of Arg141. OmpT under denaturing conditions (in the presence of 4 M urea) cleaved not only between two consecutive basic amino acids but also at the carboxyl side of Arg140 except for the Arg140-Asp141, -Glu141, and -Pro141 pairs. In addition to Arg140 at the P1 site, similar results were obtained when Lys140 was substituted into the P1 site. In the absence of urea, an aspartic acid residue at the P1' site was unfavorable for OmpT cleavage of synthetic decapeptides, the enzyme showed a preference for a dibasic site.     

Biosynthesis of the carbohydrate antigenic determinants, Globo H, blood group H, and Lewis b: a role for prostate cancer cell alpha1,2-L-fucosyltransferase

Prostate carcinoma LNCaP cells were unique among several human cancer cell lines which include two other prostate cancer cell lines, PC-3 and DU-145, in expressing alpha1,2-L-fucosyltransferase (FT) as an exclusive FT activity. Affinity gel-GDP and Sephacryl S100 HR columns were used for a partial purification of this enzyme from 3.9 x 10(9) LNCaP cells (approximately 200-fold; 40% yield). The K(m) value (2.7 mM) for the LacNAc type 2 acceptor was quite similar to the one reported for the cloned blood group H gene-specified alpha1,2-FT [Chandrasekaran et al. (1996) Biochemistry 35, 8914-8924]. N-Ethylmaleimide was a potent inhibitor (K(i ) 12.5 microM). The enzyme showed four-fold acceptor preference for the LacNAc type 2 unit in comparison to the T-hapten in mucin core 2 structure. Its main features were similar to those of the cloned enzyme: (1) C-6 sulfation of terminal Gal in the LacNAc unit increased the acceptor efficiency, whereas C-6 sialylation abolished acceptor ability; (2) C-6 sulfation of GlcNAc in LacNAc type 2 decreased by 80% the acceptor ability, whereas LacNAc type 1 was unaffected; (3) Lewis x did not serve as an acceptor; (4) the C-4 hydroxyl rather than the C-6 hydroxyl group of the GlcNAc moiety in LacNAc type1 was essential for activity; and (5) the acrylamide copolymer of Galbeta1,3GlcNAcbeta-O-Al was the best acceptor among the acrylamide copolymers. Additionally, highly significant biological features of alpha1,2FT were identified in the present study. The synthesis of Globo H and Lewis b determinants became evident from the fact that Galbeta1,3GalNAcbeta1,3Galalpha-O-Me and Galbeta1,3(Fucalpha1,4)Glc-NAcbeta1,3Galbeta-O-Me served as high-affinity acceptors for this enzyme. Further, D-Fucbeta1,3Gal-NAcbeta1,3Galalpha-O-Me was a very efficient acceptor, indicating that the C-6 hydroxyl group of the terminal Gal moiety in Globo H is not essential for the enzyme activity. Thus, the present study was able to demonstrate three different catalytic roles of LNCaP alpha1,2-FT, namely, the expressions of blood group H, Lewis b from Lewis a, and Globo H.     

Active site studies of bovine alpha1-->3-galactosyltransferase and its secondary structure prediction

The catalytic domain of bovine alpha1-->3-galactosyltransferase (alpha3GalT), residues 80-368, have been cloned and expressed, in Escherichia coli. Using a sequential purification protocol involving a Ni(2+) affinity column followed by a UDP-hexanolamine affinity column, we have obtained a pure and active protein from the soluble fraction which catalyzes the transfer of galactose (Gal) from UDP-Gal to N-acetyllactosamine (LacNAc) with a specific activity of 0.69 pmol/min/ng. The secondary structural content of alpha3GalT protein was analyzed by Fourier transform infrared (FTIR) spectroscopy, which shows that the enzyme has about 35% beta-sheet and 22% alpha-helix. This predicted secondary structure content by FTIR spectroscopy was used in the protein sequence analysis algorithm, developed by the Biomolecular Engineering Research Center at Boston University and Tasc Inc., for the assignment of secondary structural elements to the amino acid sequence of alpha3GalT. The enzyme appears to have three major and three minor helices and five sheet-like structures. The studies on the acceptor substrate specificity of the enzyme, alpha3GalT, show that in addition to LacNAc, which is the natural substrate, the enzyme accepts various other disaccharides as substrates such as lactose and Gal derivatives, beta-O-methylgalactose and beta-D-thiogalactopyranoside, albeit with lower specific activities. There is an absolute requirement for Gal to be at the non-reducing end of the acceptor molecule which has to be beta1-->4-linked to a second residue that can be more diverse in structure. The kinetic parameters for four acceptor molecules were determined. Lactose binds and functions in a similar way as LacNAc. However, beta-O-methylgalactose and Gal do not bind as tightly as LacNAc or lactose, as their K(ia) and K(A) values indicate, suggesting that the second monosaccharide is critical for holding the acceptor molecule in place. The 2' and 4' hydroxyl groups of the receiving Gal moiety are important in binding. Even though there is large structural variability associated with the second residue of the acceptor molecule, there are constraints which do not allow certain Gal-R sugars to be good acceptors for the enzyme. The beta1-->4-linked residue at the second position of the acceptor molecule is preferred, but the interactions between the enzyme and the second residue are likely to be non-specific.     

Acceptor specificity of the Pasteurella hyaluronan and chondroitin synthases and production of chimeric glycosaminoglycans

The hyaluronan (HA) synthase, PmHAS, and the chondroitin synthase, PmCS, from the Gram-negative bacterium Pasteurella multocida polymerize the glycosaminoglycan (GAG) sugar chains HA or chondroitin, respectively. The recombinant Escherichia coli-derived enzymes were shown previously to elongate exogenously supplied oligosaccharides of their cognate GAG (e.g. HA elongated by PmHAS). Here we show that oligosaccharides and polysaccharides of certain noncognate GAGs (including sulfated and iduronic acid-containing forms) are elongated by PmHAS (e.g. chondroitin elongated by PmHAS) or PmCS. Various acceptors were tested in assays where the synthase extended the molecule with either a single monosaccharide or a long chain (approximately 10(2-4) sugars). Certain GAGs were very poor acceptors in comparison to the cognate molecules, but elongated products were detected nonetheless. Overall, these findings suggest that for the interaction between the acceptor and the enzyme (a) the orientation of the hydroxyl at the C-4 position of the hexosamine is not critical, (b) the conformation of C-5 of the hexuronic acid (glucuronic versus iduronic) is not crucial, and (c) additional negative sulfate groups are well tolerated in certain cases, such as on C-6 of the hexosamine, but others, including C-4 sulfates, were not or were poorly tolerated. In vivo, the bacterial enzymes only process unsulfated polymers; thus it is not expected that the PmCS and PmHAS catalysts would exhibit such relative relaxed sugar specificity by acting on a variety of animal-derived sulfated or epimerized GAGs. However, this feature allows the chemoenzymatic synthesis of a variety of chimeric GAG polymers, including mimics of proteoglycan complexes.     

Structural insight into the mechanism of substrate specificity of aedes kynurenine aminotransferase

Aedes aegypti kynurenine aminotransferase (AeKAT) is a multifunctional aminotransferase. It catalyzes the transamination of a number of amino acids and uses many biologically relevant alpha-keto acids as amino group acceptors. AeKAT also is a cysteine S-conjugate beta-lyase. The most important function of AeKAT is the biosynthesis of kynurenic acid, a natural antagonist of NMDA and alpha7-nicotinic acetylcholine receptors. Here, we report the crystal structures of AeKAT in complex with its best amino acid substrates, glutamine and cysteine. Glutamine is found in both subunits of the biological dimer, and cysteine is found in one of the two subunits. Both substrates form external aldemines with pyridoxal 5-phosphate in the structures. This is the first instance in which one pyridoxal 5-phosphate enzyme has been crystallized with cysteine or glutamine forming external aldimine complexes, cysteinyl aldimine and glutaminyl aldimine. All the units with substrate are in the closed conformation form, and the unit without substrate is in the open form, which suggests that the binding of substrate induces the conformation change of AeKAT. By comparing the active site residues of the AeKAT-cysteine structure with those of the human KAT I-phenylalanine structure, we determined that Tyr286 in AeKAT is changed to Phe278 in human KAT I, which may explain why AeKAT transaminates hydrophilic amino acids more efficiently than human KAT I does.     

Enzymatic properties and substrate specificity of the trehalose phosphorylase from Caldanaerobacter subterraneus

A putative glycoside phosphorylase from Caldanaerobacter subterraneus subsp. pacificus was recombinantly expressed in Escherichia coli, after codon optimization and chemical synthesis of the encoding gene. The enzyme was purified by His tag chromatography and was found to be specifically active toward trehalose, with an optimal temperature of 80°C. In addition, no loss of activity could be detected after 1 h of incubation at 65°C, which means that it is the most stable trehalose phosphorylase reported so far. The substrate specificity was investigated in detail by measuring the relative activity on a range of alternative acceptors, applied in the reverse synthetic reaction, and determining the kinetic parameters for the best acceptors. These results were rationalized based on the enzyme-substrate interactions observed in a homology model with a docked ligand. The specificity for the orientation of the acceptor's hydroxyl groups was found to decrease in the following order: C-3 > C-2 > C-4. This results in a particularly high activity on the monosaccharides d-fucose, d-xylose, l-arabinose, and d-galactose, as well as on l-fucose. However, determination of the kinetic parameters revealed that these acceptors bind less tightly in the active site than the natural acceptor d-glucose, resulting in drastically increased K(m) values. Nevertheless, the enzyme's high thermostability and broad acceptor specificity make it a valuable candidate for industrial disaccharide synthesis.     

Specificity of acceptor binding to Leuconostoc mesenteroides B-512F dextransucrase: binding and acceptor-product structure of alpha-methyl-D-glucopyranoside analogs modified at C-2, C-3, and C-4 by inversion of the hydroxyl and by replacement of the hydroxyl with hydrogen

The specificity of acceptor binding to the active site of dextransucrase was studied by using alpha-methyl-D-glucopyranoside analogs modified at C-2, C-3, and C-4 positions by (a) inversion of the hydroxyl group and (b) replacement of the hydroxyl group with hydrogen. 2-Deoxy-alpha-methyl-D-glucopyranoside was synthesized from 2-deoxyglucose; 3- and 4-deoxy-alpha-methyl-D-glucopyranosides were synthesized from alpha-methyl-D-glucopyranoside; and alpha-methyl-D-allopyranoside was synthesized from D-glucose. The analogs were incubated with [14C]sucrose and dextransucrase, and the products were separated by thin-layer chromatography and quantitated by liquid scintillation spectrometry. Structures of the acceptor products were determined by methylation analyses and optical rotation. The relative effectiveness of the acceptor analogs in decreasing order were 2-deoxy, 2-inverted, 3-deoxy, 3-inverted, 4-inverted, and 4-deoxy. The enzyme transfers D-glucopyranose to the C-6 hydroxyl of analogs modified at C-2 and C-3, to the C-4 hydroxyl of 4-inverted, and to the C-3 hydroxyl of 4-deoxy analogs of alpha-methyl-D-glucopyranoside. The data indicate that the hydroxyl group at C-2 is not as important for acceptor binding as the hydroxyl groups at C-3 and C-4. The hydroxyl group at C-4 is particularly important as it determines the binding orientation of the alpha-methyl-D-glucopyranoside ring.     

Synthesis of deoxy and methoxy analogs of octyl alpha-D-mannopyranosyl-(1-->6)-alpha-D-mannopyranoside as probes for mycobacterial lipoarabinomannan biosynthesis

A panel of analogs of the disaccharide alpha-D-Manp-(1-->6)-alpha-D-Manp-OOctyl, a known acceptor substrate for a polyprenol monophosphomannose-dependent alpha-(1-->6)-mannosyltransferase involved in the assembly of the alpha-(1-->6)-linked mannan core of mycobacterial lipoarabinomannan, has been synthesized. Described are synthetic routes to the target deoxy and methoxy analogs in which one of the hydroxyl groups of the parent disaccharide has been modified. All glycosylation reactions involved the use of octyl glycoside acceptors and thioglycoside donors using iodonium-ion activation, and the stereochemistry of the mannopyranoside bond formed was established by measurement of the 1J(C-1,H-1). Depending on the target, the key methylation or deoxygenation reactions were carried out on either mono- or disaccharide substrates. This series of analogs will be useful for probing the substrate specificity of the enzyme, in particular, its steric and hydrogen-bonding requirements.     

Kinetic studies of sheep kidney gamma-glutamyl transpeptidase.

The kinetics of sheep kidney gamma-glutamyl transpeptidase was studied using a novel substrate L-alpha-methyl-gamma-glutamyl-L-alpha-aminobutyrate. When the substrate was incubated with the enzyme in the presence of an amino acid or peptide acceptor, the corresponding L-alpha-methyl-gamma-glutamyl derivatives of the acceptors were formed. In the absence of acceptor only hydrolysis occurred, and no transpeptidation products were detected. The presence of the methyl group on the alpha-carbon apparently prevents enzymatic transfer of the L-alpha-methyl-gamma-glutamyl residue to the amino group of the substrate itself (autotranspeptidation). When the enzyme was incubated with conventional substrates, such as glutathione or gamma-glutamyl-p-nitroanilide and an amino acid acceptor, hydrolysis, autotranspeptidation, and transpeptidation to the acceptor occurred concurrently. Initial velocity measurements in which the concentration of L-alpha-methyl-gamma-glutamyl-L-alpha-aminobutyrate was varied at several fixed acceptor concentrations, and either the release of alpha-aminobutyrate or the formation of the transpeptidation products was determined, yielded results which are consistent with a ping-pong mechanism modified by a hydrolytic shunt. A scheme of such a mechanism is presented. This mechanism predicts the formation of an alpha-methyl-gamma-glutamyl-enzyme intermediate, which can react with an amino acid to form the transpeptidation product; or in the absence of, or in the presence of low concentrations of amino acids, can react with water to form the hydrolytic products. Kinetic derivations for the reaction of the enzyme with the conventional substrate gamma-glutamyl-p-nitroanilide predict either linear or nonlinear double-reciprocal plots, depending on the prevalence of the hydrolytic, autotranspeptidation, or transpeptidation reactions. The results of kinetic experiments confirmed these predictions.     

Exploring the acceptor substrate recognition of the human beta-galactoside alpha 2,6-sialyltransferase

Human beta1,4-galactoside alpha2,6-sialyltransferase I (ST6GalI) recognition of glycoprotein acceptors has been investigated using various soluble forms of the enzyme deleted to a variable extent in the N-terminal half of the polypeptide. Full-length and truncated forms of the enzyme have been investigated with respect to their specificity for a variety of desialylated glycoproteins of known complex glycans as well as related proteins with different carbohydrate chains. Differences in transfer efficiency have been observed between membrane and soluble enzymatic forms, indicating that deletion of the transmembrane fragment induces loss of acceptor preference. No difference in substrate recognition could be observed when soluble enzymes of similar peptide sequence were produced in yeast or mammalian cells, confirming that removal of the membrane anchor and heterologous expression do not alter enzyme folding and activity. When tested on free oligosaccharides, soluble ST6GalI displayed full ability to sialylate free N-glycans as well as various N-acetyllactosaminyl substrates. Progressive truncation of the N terminus demonstrated that the catalytic domain can proceed with sialic acid transfer with increased efficiency until 80 amino acids are deleted. Fusion of the ST6GalI catalytic domain to the N-terminal half of an unrelated transferase (core 2 beta1,6-N-acetylglucosaminyltransferase) further showed that a chimeric form of broad acceptor specificity and high activity could also be engineered in vivo. These findings therefore delineate a peptide region of approximately 50 amino acids within the ST6GalI stem region that governs both the preference for glycoprotein acceptors and catalytic activity, thereby suggesting that it may exert a steric control on the catalytic domain.     

Roles of substrate distortion and intramolecular hydrogen bonding in enzymatic catalysis by scytalone dehydratase.

Alternative substrates and site-directed mutations of active-site residues are used to probe factors controlling the catalytic efficacy of scytalone dehydratase. In the E1cb-like, syn-elimination reactions catalyzed, efficient catalysis requires distortion of the substrate ring system to facilitate proton abstraction from its C2 methylene and elimination of its C3 hydroxyl group. Theoretical calculations indicate that such distortions are more readily achieved in the substrate 2,3-dihydro-2,5-dihydroxy-4H-benzopyran-4-one (DDBO) than in the physiological substrates vermelone and scytalone by approximately 2 kcal/mol. A survey of 12 active-site amino acid residues reveals 4 site-directed mutants (H110N, N131A, F53A, and F53L) have higher relative values of k(cat) and k(cat)/K(m) for DDBO over scytalone and for DDBO over vermelone than the wild-type enzyme, thus suggesting substrate-distortion roles for the native residues in catalysis. A structural link for this function is in the modeled enzyme-substrate complex where F53 and H110 are positioned above and below the substrate's C3 hydroxyl group, respectively, for pushing and pulling the leaving group into the axial orientation of a pseudo-boat conformation; N131 hydrogen-bonds to the C8 hydroxyl group at the opposite end of the substrate, serving as a pivot for the actions of F53 and H110. Deshydroxyvermelone lacks the phenolic hydroxyl group and the intramolecular hydrogen bond of vermelone. The relative values of k(cat) (95) and k(cat)/K(m) (1800) for vermelone over deshydroxyvermelone for the wild-type enzyme indicate the importance of the hydroxyl group for substrate recognition and catalysis. Off the enzyme, the much slower rates for the solvolytic dehydration of deshydroxyvermelone and vermelone are similar, thus specifying the importance of the hydroxyl group of vermelone for enzyme catalysis.     

Structure and function of HNK-1 sulfotransferase. Identification of donor and acceptor binding sites by site-directed mutagenesis.

HNK-1 glycan, sulfo-->3GlcAbeta1-->3Galbeta1-->4GlcNAc-->R, is uniquely enriched in neural cells and natural killer cells and is thought to play important roles in cell-cell interaction. HNK-1 glycan synthesis is dependent on HNK-1 sulfotransferase (HNK-1ST), and cDNAs encoding human and rat HNK-1ST have been recently cloned. HNK-1ST belongs to the sulfotransferase gene family, which shares two homologous sequences in their catalytic domains. In the present study, we have individually mutated amino acid residues in these conserved sequences and determined how such mutations affect the binding to the donor substrate, adenosine 3'-phosphate 5'-phosphosulfate, and an acceptor. Mutations of Lys(128), Arg(189), Asp(190), Pro(191), and Ser(197) to Ala all abolished the enzymatic activity. When Lys(128) and Asp(190) were conservatively mutated to Arg and Glu, respectively, however, the mutated enzymes still maintained residual activity, and both mutant enzymes still bound to adenosine 3',5'-diphosphate-agarose. K128R and D190E mutant enzymes, on the other hand, exhibited reduced affinity to the acceptor as demonstrated by kinetic studies. These findings, together with those on the crystal structure of estrogen sulfotransferase and heparan sulfate N-deacetylase/sulfotransferase, suggest that Lys(128) may be close to the 3-hydroxyl group of beta-glucuronic acid in a HNK-1 acceptor. In contrast, the effect by mutation at Asp(190) may be due to conformational change because this amino acid and Pro(191) reside in a transition of the secondary structure of the enzyme. These results indicate that conserved amino acid residues in HNK-1ST play roles in maintaining a functional conformation and are directly involved in binding to donor and acceptor substrates.     

Amino acid substitutions of His296 alter the catalytic properties of Zymomonas mobilis 10232 levansucrase

His296 of Zymomonas mobilis levansucrase (EC 2.4.1.10) is crucial for the catalysis of the transfructosylation reaction. The three-dimensional structures of levansucrases revealed the His296 is involved in the substrate recognition and binding. In this study, nine mutants were created by site-directed mutagenesis, in which His296 was substituted with amino acids of different polarity, charge and length. The substitutions of His296 with Arg or Trp retained partial hydrolysis and transfructosylation activities. The positively charged Lys substitution resulted in a 2.5-fold increase of sucrose hydrolysis. Substitutions with short (Cys or Ser), negatively charged (Glu) or polar (Tyr) amino acids virtually abolished both the activities. Analysis of transfructosylation products indicated that the mutants synthesized different oligosaccharides, suggesting that amino acid substitutions of His296 strongly affected both the enzyme activity and transfructosylation products.