Crystal structure of phosphodiesterase 4D and inhibitor complex(1)

Cyclic nucleotide phosphodiesterases (PDEs) regulate physiological processes by degrading intracellular second messengers, adenosine-3′,5′-cyclic phosphate or guanosine-3′,5′-cyclic phosphate. The first crystal structure of PDE4D catalytic domain and a bound inhibitor, zardaverine, was determined. Zardaverine binds to a highly conserved pocket that includes the catalytic metal binding site. Zardaverine fills only a portion of the active site pocket. More selective PDE4 inhibitors including rolipram, cilomilast and roflumilast have additional functional groups that can utilize the remaining empty space for increased binding energy and selectivity. In the crystal structure, the catalytic domain of PDE4D possesses an extensive dimerization interface containing residues that are highly conserved in PDE1, 3, 4, 8 and 9. Mutations of R358D or D322R among these interface residues prohibit dimerization of the PDE4D catalytic domain in solution.     

Properties of triple helix formation with oligodeoxyribonucleotides containing 8-oxo-2′-deoxyadenosine and 2′-modified nucleoside derivatives

The ability of homopyrimidine oligonucleotides containing 8-oxo-2′-deoxyadenosine (dAOH), 2′-methoxyuridine (Um). 2′-fluorouridine (Uf), 2′-methoxycytidine (Cm), and 2′-fluorocytidine (Cf) to form stable, triple-helical structures with sequences containing the recognition site for the class II-S restriction enzyme, Ksp632-I, was studied as a function of pH. The 8-oxo-2′-deoxyadenosine substituted oligomers were shown to bind within the physiological pH range in a pH-independent fashion, without a compromise in specificity. In particular, the substitutions of three deoxycytidine residues with 8-oxo-2′-deoxyadenosine showed higher endonuclease inhibition than the substitution of either one or two deoxycytidine residues with 8-oxo-2′-deoxyadenosine. In contrast, the oligonucleotides containing 2′-modified nucleosides (Uf, Um, Uf-Cf, Um-Cm, dAOHUf, and dAOH-Um) bind in a pH-dependent manner to the target duplex.

The 8-oxo-2′-deoxyadenosine substituted oligomers were shown to bind within the physiological pH range in a pH-independent fashion, without a compromise in specificity. In particular, the substitutions of three deoxycytidine resides with 8-oxo-2′-deoxyadenosine showed higher endonuclease inhibition than the substitution of either one or two deoxycytidine residues with 8-oxo-2′-deoxyadenosine. By contrast, the oligonucleotides containing 2′-modified nucleosides (Uf, Um, Uf-Cf, Um-Cm, dAOH-Uf, and dAOH-Um) bind in a pH-dependent manner to the target duplex.     

The catalytic aspartate is protonated in the Michaelis complex formed between trypsin and an in vitro evolved substrate-like inhibitor: a refined mechanism of serine protease action

The mechanism of serine proteases prominently illustrates how charged amino acid residues and proton transfer events facilitate enzyme catalysis. Here we present an ultrahigh resolution (0.93 Å) x-ray structure of a complex formed between trypsin and a canonical inhibitor acting through a substrate-like mechanism. The electron density indicates the protonation state of all catalytic residues where the catalytic histidine is, as expected, in its neutral state prior to the acylation step by the catalytic serine. The carboxyl group of the catalytic aspartate displays an asymmetric electron density so that the O_δ2–C_γ bond appears to be a double bond, with O_δ2 involved in a hydrogen bond to His-57 and Ser-214. Only when Asp-102 is protonated on O_δ1 atom could a density functional theory simulation reproduce the observed electron density. The presence of a putative hydrogen atom is also confirmed by a residual mF_obs − DF_calc density above 2.5 σ next to O_δ1. As a possible functional role for the neutral aspartate in the active site, we propose that in the substrate-bound form, the neutral aspartate residue helps to keep the pK_a of the histidine sufficiently low, in the active neutral form. When the histidine receives a proton during the catalytic cycle, the aspartate becomes simultaneously negatively charged, providing additional stabilization for the protonated histidine and indirectly to the tetrahedral intermediate. This novel proposal unifies the seemingly conflicting experimental observations, which were previously seen as either supporting the charge relay mechanism or the neutral pK_a histidine theory.     

Importance of purine-pyridine hydroxyl and purine amino groups for hammerhead ribozyme cleavage

The importance of the 2′-hydroxyl and 2-amino groups of guanosine residues for the catalytic efficiency of a hammerhead ribozyme has been investigated. The three guanosines in the central core of a hammerhead ribozyme were replaced by deoxyinosine, inosine, and deoxyguanosine, and ribozymes containing these analogues were chemically synthesized. Most of the modified ribozymes are drastically descreased in their cleavage efficiency. However. deletion of the 2-amino group at G₈ (replacement with inosine, deoxyguanosine, deoxyinosine) caused little alteration in the catalytic activity relative to that obtained with the unmodified ribozyme. Whereas, deletion of the 2′-amino group at G₁₂ and G₅ (replacement with inosine, deoxyinosine, and deoxyguanosine) resulted in ribozymes with drastic decrease in the catalytic activity relative to that obtained with the unmodified ribozyme. In contrast, two uridine residues, U⁷ and U⁴, in the ribozyne sequence were replaced by deoxyuridine (dU). The dU4 complex resulted in a decrease in the catalytic rate, with relative cleavage activity that ws about half that observed for the native complex. By comparison, the dU⁷ complex exhibited a relative cleavage activity within 3.3-fold of that observed with native ribozyme/substrate complex. This result suggests that the 2′-hydroxyl group at U ⁷ is not essential for activity.

The importance of the 2′-hydroxyl, and 2-amino groups of guanosine residues for the catalytic efficiency of a hammerhead roibozyme has been investigated. Most of the modified rybozymes are drastically decreased in their cleavage efficiency. However, deletion of the 2-amino group at G₈ or deletion of the 2′-hydroxyl group at G₁₂ caused little alteration in the catalytic activity relative to that obtained with the unmodified ribozyme. In contrast, two uridine residues, U₇ and U₄, in the ribozyme sequence were replaced by deoxyuridine (dU). The U4 complex resulted in a decrease in the catalytic rate, with relative cleavage activity that was about half that observed for the native complex.     

Conjugation of d-glucosamine to bovine trypsin increases thermal stability and alters functional properties

d-glucosamine was conjugated to bovine trypsin by carbodiimide chemistry, involving a water-soluble carbodiimide and a succinimide ester, with the latter being to increase the yield of the conjugation. Mass spectrometric data suggested that several glycoforms were formed, with around 12 d-glucosamine moieties coupled to each trypsin molecule on average. The moieties were probably coupled to eight carboxyl groups (of glutamyl and aspartyl residues) and to four tyrosyl residues on the surface of the enzyme. The glycated trypsin possessed increased thermal stability. When compared with its unmodified counterpart, T_50% was increased by 7 °C, thermal inactivation of the first step was increased 34%, and long-term stability assay revealed 71-times higher residual activity at 25 °C (without stabilizing Ca²⁺ ions in aqueous buffer) after 67 days. Furthermore, resistance against autolysis was increased almost two-fold. Altered functional properties of the glycated trypsin were also observed. The glycated trypsin was found to become increasingly basophilic, and was found to be slightly structurally altered. This was indicated by 1.2 times higher catalytic efficiency (k_cat/K_m) than unmodified trypsin against the substrate N-α-benzoyl-l-arginine-p-nitroanilide. Circular dichroism spectropolarimetry suggested a minor change in spatial arrangement of α-helix/helices, resulting in an increased affinity of the glycated trypsin for this small synthetic substrate.     

Hymenoic acid, a novel specific inhibitor of human DNA polymerase lambda from a fungus of Hymenochaetaceae sp

Hymenoic acid (1) is a natural compound isolated from cultures of a fungus, Hymenochaetaceae sp., and this structure was determined by spectroscopic analyses. Compound 1 is a novel sesquiterpene, trans-4-[(1′E,5′S)-5′-carboxy-1′-methyl-1′-hexenyl]cyclohexanecarboxylic acid. This compound selectively inhibited the activity of human DNA polymerase λ (pol λ) in vitro, and 50% inhibition was observed at a concentration of 91.7 μM. Compound 1 did not influence the activities of the other seven mammalian pols (i.e., pols , γ, δ, ε, η, ι, and κ), but also showed no effect even on the activity of pol β, which is thought to have a very similar three-dimensional structure to the pol β-like region of pol λ. This compound also did not inhibit the activities of prokaryotic pols and other DNA metabolic enzymes tested. These results suggested that compound 1 could be a selective inhibitor of eukaryotic pol λ. This compound had no inhibitory activities against two N-terminal truncated pol λ, del-1 pol λ (lacking nuclear localization signal (NLS), BRCA1 C-terminus (BRCT) domain [residues 133–575]), and del-2 pol λ (lacking NLS, BRCT, domain and proline-rich region [residues 245–575]). The compound 1-induced inhibition of intact pol λ activity was non-competitive with respect to both the DNA template-primer and the dNTP substrate. On the basis of these results, the pol λ inhibitory mechanism of compound 1 is discussed.     

Characterization of member of DUF1888 protein family, self-cleaving and self-assembling endopeptidase

The crystal structure of SO1698 protein from Shewanella oneidensis was determined by a SAD method and refined to 1.57 Å. The structure is a β sandwich that unexpectedly consists of two polypeptides; the N-terminal fragment includes residues 1–116, and the C-terminal one includes residues 117–125. Electron density also displayed the Lys-98 side chain covalently linked to Asp-116. The putative active site residues involved in self-cleavage were identified; point mutants were produced and characterized structurally and in a biochemical assay. Numerical simulations utilizing molecular dynamics and hybrid quantum/classical calculations suggest a mechanism involving activation of a water molecule coordinated by a catalytic aspartic acid.     

Functional and structural characterization of α-(1->2) branching sucrase derived from DSR-E glucansucrase

ΔN₁₂₃-glucan-binding domain-catalytic domain 2 (ΔN₁₂₃-GBD-CD2) is a truncated form of the bifunctional glucansucrase DSR-E from Leuconostoc mesenteroides NRRL B-1299. It was constructed by rational truncation of GBD-CD2, which harbors the second catalytic domain of DSR-E. Like GBD-CD2, this variant displays α-(1→2) branching activity when incubated with sucrose as glucosyl donor and (oligo-)dextran as acceptor, transferring glucosyl residues to the acceptor via a ping-pong bi-bi mechanism. This allows the formation of prebiotic molecules containing controlled amounts of α-(1→2) linkages. The crystal structure of the apo α-(1→2) branching sucrase ΔN₁₂₃-GBD-CD2 was solved at 1.90 Å resolution. The protein adopts the unusual U-shape fold organized in five distinct domains, also found in GTF180-ΔN and GTF-SI glucansucrases of glycoside hydrolase family 70. Residues forming subsite −1, involved in binding the glucosyl residue of sucrose and catalysis, are strictly conserved in both GTF180-ΔN and ΔN₁₂₃-GBD-CD2. Subsite +1 analysis revealed three residues (Ala-2249, Gly-2250, and Phe-2214) that are specific to ΔN₁₂₃-GBD-CD2. Mutation of these residues to the corresponding residues found in GTF180-ΔN showed that Ala-2249 and Gly-2250 are not directly involved in substrate binding and regiospecificity. In contrast, mutant F2214N had lost its ability to branch dextran, although it was still active on sucrose alone. Furthermore, three loops belonging to domains A and B at the upper part of the catalytic gorge are also specific to ΔN₁₂₃-GBD-CD2. These distinguishing features are also proposed to be involved in the correct positioning of dextran acceptor molecules allowing the formation of α-(1→2) branches.     

The beta subunit loop that couples catalysis and rotation in ATP synthase has a critical length

ATP synthase uses a unique rotational mechanism to convert chemical energy into mechanical energy and back into chemical energy. The helix-turn-helix structure in the C-terminal domain of the β subunit containing the conserved DELSEED motif, termed “DELSEED-loop,” was suggested to be involved in coupling between catalysis and rotation. If this is indeed the role of the loop, it must have a critical length, the minimum length required to sustain its function. Here, the critical length of the DELSEED-loop was determined by functional analysis of mutants of Bacillus PS3 ATP synthase that had 7–14 amino acids within the loop deleted. A 10 residue deletion lost the ability to catalyze ATP synthesis, but was still an active ATPase. Deletion of 14 residues abolished any enzymatic activity. Modeling indicated that in both deletion mutants the DELSEED-loop was shortened by ∼10 Å; fluorescence resonance energy transfer experiments confirmed the modeling results. This appears to define the minimum length for DELSEED-loop required for coupling of catalysis and rotation. In addition, we could demonstrate that the loss of high-affinity binding to the catalytic site(s) that had been observed previously in two deletion mutants with 3–4 residues removed was not due to the loss of negative charged residues of the DELSEED motif in these mutants. An AALSAAA mutant in which all negative charges of the DELSEED motif were removed showed a normal pattern for MgATP binding to the catalytic sites, with a clearly present high-affinity site.     

Scanning the prime-site substrate specificity of proteolytic enzymes: a novel assay based on ligand-enhanced lanthanide ion fluorescence

A novel method for assaying the substrate specificity of proteolytic enzymes has been developed utilizing ligand-enhanced lanthanide ion fluorescence. This approach was used to develop peptide libraries to probe substrate specificity in the prime sites of proteolytic enzymes. A positional scanning synthetic combinatorial library of fluorogenic peptides was synthesized and used to determine the extended prime site specificity of bovine -chymotrypsin. The enzyme showed a preference for Lys and Arg in the P1′ position, rather broad specificity in the P2′ position, and a slight Arg specificity in the P3′ position. The specificity profile of bovine -chymotrypsin agrees well with previously reported data, and the substrate library reported herein should provide valuable information about the prime site substrate specificities of other proteolytic enzymes as well. Furthermore, the continuous fluorogenic assay described may prove useful in analyzing the activity of other hydrolytic enzymes.     

Crystal structure of the acyltransferase domain of the iterative polyketide synthase in enediyne biosynthesis

Biosynthesis of the enediyne natural product dynemicin in Micromonospora chersina is initiated by DynE8, a highly reducing iterative type I polyketide synthase that assembles polyketide intermediates from the acetate units derived solely from malonyl-CoA. To understand the substrate specificity and the evolutionary relationship between the acyltransferase (AT) domains of DynE8, fatty acid synthase, and modular polyketide synthases, we overexpressed a 44-kDa fragment of DynE8 (hereafter named AT_DYN10) encompassing its entire AT domain and the adjacent linker domain. The crystal structure at 1.4 Å resolution unveils a α/β hydrolase and a ferredoxin-like subdomain with the Ser-His catalytic dyad located in the cleft between the two subdomains. The linker domain also adopts a α/β fold abutting the AT catalytic domain. Co-crystallization with malonyl-CoA yielded a malonyl-enzyme covalent complex that most likely represents the acyl-enzyme intermediate. The structure explains the preference for malonyl-CoA with a conserved arginine orienting the carboxylate group of malonate and several nonpolar residues that preclude α-alkyl malonyl-CoA binding. Co-crystallization with acetyl-CoA revealed two noncovalently bound acetates generated by the enzymatic hydrolysis of acetyl-CoA that acts as an inhibitor for DynE8. This suggests that the AT domain can upload the acyl groups from either malonyl-CoA or acetyl-CoA onto the catalytic Ser⁶⁵¹ residue. However, although the malonyl group can be transferred to the acyl carrier protein domain, transfer of the acetyl group to the acyl carrier protein domain is suppressed. Local structural differences may account for the different stability of the acyl-enzyme intermediates.     

Identification of acridinyl hydrazides as potent aspartic protease inhibitors

We have identified acridinyl derivatives as potent aspartic protease inhibitors by virtual screening of in-house library of synthetic compounds. Enzyme inhibition experiments showed that both compounds inhibit human cathepsin D and Plasmodium falciparum plasmepsin-II in nanomolar ranges. The IC₅₀ values against cathepsin D and plasmepsin-II of compound-Nar103 were found to be 9.0 ± 2.0 and 4.0 ± 1.0 nM and of compound-Nar110 were 0.5 ± 0.05 and 0.13 ± 0.03 nM, respectively. Ligand docking predicted the binding of acridinyl derivatives at the substrate-binding cleft, where hydrazide part of the inhibitors interact with the S1–S1′ subsite residues including catalytic aspartates. The phenyl ring and acridinyl moiety of the inhibitors were predicted to interact with S2/S3 and S2′/S3′ subsite residues.     

Selection of the 3′-splice site in group I introns

A model for selection of 3′-splice sites in splicing of RNA precursors containing group I introns is presented. The key feature of this model is a newly identified tertiary interaction between the catalytic core of the intron and the 3′-splice site. This tertiary pairing would bring the 3′-splice site into the core of the intron, which is known to contain RNA sequences and structures essential for catalyzing the splicing reactions. The proposed tertiary interaction can coexist with P10, a pairing between 3′-exon sequences and the ‘internal guide sequence’ near the 5′-end of the intron. The model predicts that three RNA-RNA interactions are important in selection of 3′-splice sites: (i) binding of intron sequences with the core; (ii) pairing of exon sequences with the internal guide sequence; and (iii) binding of the terminal guanosine to an unknown site within the core.     

Amino acid sequence of crayfish (Astacus fluviatilis) trypsin If

The complete amino acid sequence of trypsin from the crayfish Astacus fluviatilis has been determined. The protein was fragmented with cyanogen bromide after S-carboxymethylation of the reduced disulfide bonds and by trypsin after S-carboxymethylation as well as after succinylation of lysine residues and aminoethylation of the reduced disulfide bonds. Peptides were purified by gel filtration and by reversed-phase high-performance liquid chromatography. Stepwise degradation was performed in a spinning cup sequencer. The enzyme contains 237 amino acid residues and has a molecular weight of 25 030. In contrast to bovine trypsin, it contains three rather than six disulfide bonds which are paired in the same fashion as those in trypsin from Streptomyces griseus. The constituents of the active site of bovine trypsin are present in corresponding positions in the crayfish enzyme. Crayfish trypsin shows 43.6% sequence identity with the bovine enzyme as compared to 40.0% identity with the S. griseus enzyme. The present analysis affords the first detailed view into the evolution of trypsins at the invertebrate level.     

Studies of specificity and catalysis in trypsin by structural analysis of site-directed mutants

We are probing the determinants of catalytic function and substrate specificity in serine proteases by kinetic and crystallographic characterization of genetically engineered site-directed mutants of rat trypsin. The role of the aspartyl residue at position 102, common to all members of the serine protease family, has been tested by substitution with asparagine. In the native enzyme, Asp102 accepts a hydrogen bond from the catalytic base His57, which facilitates the transfer of a proton from the enzyme nucleophile Ser195 to the substrate leaving group. At neutral pH, the mutant is four orders of magnitude less active than the naturally occurring enzyme, but its binding affinity for model substrates is virtually undiminished. Crystallographic analysis reveals that Asn102 donates a hydrogen bond to His57, forcing it to act as donor to Ser195. Below pH 6, His57 becomes statistically disordered. Presumably, the di-protonated population of histidyl side chains are unable to hydrogen bond to Asn102. Steric conflict may cause His57 to rotate away from the catalytic site. These results suggest that Asp102 not only provides inductive and orientation effects, but also stabilizes the productive tautomer of His57. Three experiments were carried out to alter the substrate specificity of trypsin. Glycine residues at positions 216 and 226 in the substrate-binding cavity were replaced by alanine residues in order to differentially affect lysine and arginine substrate binding. While the rate of catalysis by the mutant enzymes was reduced in the mutant enzymes, their substrate specificity was enhanced relative to trypsin. The increased specificity was caused by differential effects on the catalytic activity towards arginine and lysine substrates. The Gly----Ala substitution at 226 resulted in an altered conformation of the enzyme which is converted to an active trypsin-like conformation upon binding of a substrate analog. In a third experiment, Lys189, at the bottom of the specificity pocket, was replaced with an aspartate with the expectation that specificity of the enzyme might shift to aspartate. The mutant enzyme is not capable of cleaving at Arg and Lys or Asp, but shows an enhanced chymotrypsin-like specificity. Structural investigations of these mutants are in progress.     

Zymogen Activation and Subcellular Activity of Subtilisin Kexin Isozyme 1/Site 1 Protease

The proprotein convertase subtilisin kexin isozyme 1 (SKI-1)/site 1 protease (S1P) plays crucial roles in cellular homeostatic functions and is hijacked by pathogenic viruses for the processing of their envelope glycoproteins. Zymogen activation of SKI-1/S1P involves sequential autocatalytic processing of its N-terminal prodomain at sites B′/B followed by the herein newly identified C′/C sites. We found that SKI-1/S1P autoprocessing results in intermediates whose catalytic domain remains associated with prodomain fragments of different lengths. In contrast to other zymogen proprotein convertases, all incompletely matured intermediates of SKI-1/S1P showed full catalytic activity toward cellular substrates, whereas optimal cleavage of viral glycoproteins depended on B′/B processing. Incompletely matured forms of SKI-1/S1P further process cellular and viral substrates in distinct subcellular compartments. Using a cell-based sensor for SKI-1/S1P activity, we found that 9 amino acid residues at the cleavage site (P1–P8) and P1′ are necessary and sufficient to define the subcellular location of processing and to determine to what extent processing of a substrate depends on SKI-1/S1P maturation. In sum, our study reveals novel and unexpected features of SKI-1/S1P zymogen activation and subcellular specificity of activity toward cellular and pathogen-derived substrates.     

Structural and enzymatic insights into caspase-2 protein substrate recognition and catalysis

Caspase-2, the most evolutionarily conserved member in the human caspase family, may play important roles in stress-induced apoptosis, cell cycle regulation, and tumor suppression. In biochemical assays, caspase-2 uniquely prefers a pentapeptide (such as VDVAD) rather than a tetrapeptide, as required for efficient cleavage by other caspases. We investigated the molecular basis for pentapeptide specificity using peptide analog inhibitors and substrates that vary at the P5 position. We determined the crystal structures of apo caspase-2, caspase-2 in complex with peptide inhibitors VDVAD-CHO, ADVAD-CHO, and DVAD-CHO, and a T380A mutant of caspase-2 in complex with VDVAD-CHO. Two residues, Thr-380 and Tyr-420, are identified to be critical for the P5 residue recognition; mutation of the two residues reduces the catalytic efficiency by about 4- and 40-fold, respectively. The structures also provide a series of snapshots of caspase-2 in different catalytic states, shedding light on the mechanism of capase-2 activation, substrate binding, and catalysis. By comparing the apo and inhibited caspase-2 structures, we propose that the disruption of a non-conserved salt bridge between Glu-217 and the invariant Arg-378 is important for the activation of caspase-2. These findings broaden our understanding of caspase-2 substrate specificity and catalysis.     

Biochemical and structural studies of uncharacterized protein PA0743 from Pseudomonas aeruginosa revealed NAD+-dependent L-serine dehydrogenase

The β-hydroxyacid dehydrogenases form a large family of ubiquitous enzymes that catalyze oxidation of various β-hydroxy acid substrates to corresponding semialdehydes. Several known enzymes include β-hydroxyisobutyrate dehydrogenase, 6-phosphogluconate dehydrogenase, 2-(hydroxymethyl)glutarate dehydrogenase, and phenylserine dehydrogenase, but the vast majority of β-hydroxyacid dehydrogenases remain uncharacterized. Here, we demonstrate that the predicted β-hydroxyisobutyrate dehydrogenase PA0743 from Pseudomonas aeruginosa catalyzes an NAD⁺-dependent oxidation of l-serine and methyl-l-serine but exhibits low activity against β-hydroxyisobutyrate. Two crystal structures of PA0743 were solved at 2.2–2.3-Å resolution and revealed an N-terminal Rossmann fold domain connected by a long α-helix to the C-terminal all-α domain. The PA0743 apostructure showed the presence of additional density modeled as HEPES bound in the interdomain cleft close to the predicted catalytic Lys-171, revealing the molecular details of the PA0743 substrate-binding site. The structure of the PA0743-NAD⁺ complex demonstrated that the opposite side of the enzyme active site accommodates the cofactor, which is also bound near Lys-171. Site-directed mutagenesis of PA0743 emphasized the critical role of four amino acid residues in catalysis including the primary catalytic residue Lys-171. Our results provide further insight into the molecular mechanisms of substrate selectivity and activity of β-hydroxyacid dehydrogenases.     

Structural and kinetic analysis of substrate binding to the sialyltransferase Cst-II from Campylobacter jejuni

Sialic acids play important roles in various biological processes and typically terminate the oligosaccharide chains on the cell surfaces of a wide range of organisms, including mammals and bacteria. Their attachment is catalyzed by a set of sialyltransferases with defined specificities both for their acceptor sugars and the position of attachment. However, little is known of how this specificity is encoded. The structure of the bifunctional sialyltransferase Cst-II of the human pathogen Campylobacter jejuni in complex with CMP and the terminal trisaccharide of its natural acceptor (Neu5Ac-α-2,3-Gal-β-1,3-GalNAc) has been solved at 1.95 Å resolution, and its kinetic mechanism was shown to be iso-ordered Bi Bi, consistent with its dual acceptor substrate specificity. The trisaccharide acceptor is seen to bind to the active site of Cst-II through interactions primarily mediated by Asn-51, Tyr-81, and Arg-129. Kinetic and structural analyses of mutants modified at these positions indicate that these residues are critical for acceptor binding and catalysis, thereby providing significant new insight into the kinetic and catalytic mechanism, and acceptor specificity of this pathogen-encoded bifunctional GT-42 sialyltransferase.     

Structural and biochemical elucidation of mechanism for decarboxylative condensation of beta-keto acid by curcumin synthase

The typical reaction catalyzed by type III polyketide synthases (PKSs) is a decarboxylative condensation between acyl-CoA (starter substrate) and malonyl-CoA (extender substrate). In contrast, curcumin synthase 1 (CURS1), which catalyzes curcumin synthesis by condensing feruloyl-CoA with a diketide-CoA, uses a β-keto acid (which is derived from diketide-CoA) as an extender substrate. Here, we determined the crystal structure of CURS1 at 2.32 Å resolution. The overall structure of CURS1 was very similar to the reported structures of type III PKSs and exhibited the αβαβα fold. However, CURS1 had a unique hydrophobic cavity in the CoA-binding tunnel. Replacement of Gly-211 with Phe greatly reduced the enzyme activity. The crystal structure of the G211F mutant (at 2.5 Å resolution) revealed that the side chain of Phe-211 occupied the hydrophobic cavity. Biochemical studies demonstrated that CURS1 catalyzes the decarboxylative condensation of a β-keto acid using a mechanism identical to that for normal decarboxylative condensation of malonyl-CoA by typical type III PKSs. Furthermore, the extender substrate specificity of CURS1 suggested that hydrophobic interaction between CURS1 and a β-keto acid may be important for CURS1 to use an extender substrate lacking the CoA moiety. From these results and a modeling study on substrate binding, we concluded that the hydrophobic cavity is responsible for the hydrophobic interaction between CURS1 and a β-keto acid, and this hydrophobic interaction enables the β-keto acid moiety to access the catalytic center of CURS1 efficiently.