Clement Angkawidjaja

Crystal structure of a family I.3 lipase from Pseudomonas sp. MIS38 in a closed conformation

The crystal structure of a family I.3 lipase from Pseudomonas sp. MIS38 in a closed conformation was determined at 1.5 Å resolution. This structure highly resembles that of Serratia marcescens LipA in an open conformation, except for the structures of two lids. Lid1 is anchored by a Ca2+ ion (Ca1) in an open conformation, but lacks this Ca1 site and greatly changes its structure and position in a closed conformation. Lid2 forms a helical hairpin in an open conformation, but does not form it and covers the active site in a closed conformation. Based on these results, we discuss on the lid‐opening mechanism.

Structure and stability of a thermostable carboxylesterase from the thermoacidophilic archaeon Sulfolobus tokodaii

The hormone‐sensitive lipase (HSL) family is comprised of carboxylesterases and lipases with similarity to mammalian HSL. Thermophilic enzymes of this family have a high potential for use in biocatalysis. We prepared and crystallized a carboxylesterase of the HSL family from Sulfolobusu2003tokodaii (Sto‐Est), and determined its structures in the presence and absence of an inhibitor. Sto‐Est forms a dimer in solution and the crystal structure suggests the presence of a stable biological dimer. We identified a residue close to the dimer interface, R267, which is conserved in archaeal enzymes of HSL family and is in close proximity to the same residue from the other monomer. Mutations of R267 to Glu, Gly and Lys were conducted and the resultant R267 mutants were characterized and crystallized. The structures of R267E, R267G and R267K are highly similar to that of Sto‐Est with only slight differences in atomic coordinates. The dimerized states of R267E and R267G are unstable under denaturing conditions or at high temperature, as shown by a urea‐induced dimer dissociation experiment and molecular dynamics simulation. R267E is the most unstable mutant protein, followed by R267G and R267K, as shown by the thermal denaturation curve and optimum temperature for activity. From the data, we discuss the importance of R267 in maintaining the dimer integrity of Sto‐Est.

Crystal Structure of a Subtilisin Homologue, Tk-SP, from Thermococcus kodakaraensis: Requirement of a C-terminal β-Jelly Roll Domain for Hyperstability

Tk-SP is a hyperthermostable subtilisin-like serine protease from Thermococcus kodakaraensis and is autoprocessed from its precursor (Pro-Tk-SP) with N- and C-propeptides. The crystal structure of the active-site mutant of Pro-Tk-SP lacking C-propeptide, ProN-Tk-S359A, was determined at 2.0 A resolution. ProN-Tk-S359A consists of the N-propeptide, subtilisin, and beta-jelly roll domains. Two Ca(2+) ions bind to the beta-jelly roll domain. The overall structure of ProN-Tk-S359A without the beta-jelly roll domain is similar to that of the bacterial propeptide:subtilisin complex, except that it does not contain Ca(2+) ions. To analyze the role of the beta-jelly roll domain of Tk-SP, we constructed a series of the active-site mutants of Tk-SP with (Tk-S359A/C) and without (Tk-S359A/CDeltaJ) beta-jelly roll domain. Both Tk-S359C and Tk-S359CDeltaJ exhibited protease activities in gel assay, indicating that the beta-jelly roll domain is not required for folding or activity. However, the T(m) value of Tk-S359ADeltaJ determined by far-UV CD spectroscopy in the presence of 10-mM CaCl(2) was lower than that of Tk-S359A by 29.4 degrees C. The T(m) value of Tk-S359A was decreased by 29.5 degrees C by the treatment with 10 mM ethylenediaminetetraacetic acid, indicating that the beta-jelly roll domain contributes to the stabilization of Tk-S359A only in a Ca(2+)-bound form. Tk-SP highly resembles subtilisin-like serine proteases from Pyrococcus furiosus, Thermococcus gammatolerans, and Thermococcus onnurineus in size and amino acid sequence. We propose that attachment of a beta-jelly roll domain to the C-terminus is one of the strategies of the proteins from hyperthermophiles to adapt to high-temperature environment.

X-ray Crystallographic and MD Simulation Studies on the Mechanism of Interfacial Activation of a Family I.3 Lipase with Two Lids

The interfacial activation mechanism of family I.3 lipase from Pseudomonas sp. MIS38 (PML), which has two alpha-helical lids (lid1 and lid2), was investigated using a combination of X-ray crystallography and molecular dynamics (MD) simulation. The crystal structure of PML in an open conformation was determined at 2.1 A resolution in the presence of Ca(2+) and Triton X-100. Comparison of this structure with that in the closed conformation indicates that both lids greatly change their positions and lid1 is anchored by the calcium ion (Ca1) in the open conformation. This structure was not seriously changed even when the protein was dialyzed extensively against the Ca(2+)-free buffer containing Triton X-100 before crystallization, indicating that the open conformation is fairly stable unless a micellar substance is removed. The crystal structure of the PML derivative, in which the active site serine residue (Ser207) is diethylphosphorylated by soaking the crystal of PML in the open conformation in a solution containing diethyl p-nitrophenyl phosphate, was also determined. This structure greatly resembles that in the open conformation, indicating that PML structure in the open conformation represents that in the active form. MD simulation of PML in the open conformation in the absence of micelles showed that lid2 closes first, while lid1 maintains its open conformation. Likewise, MD simulation of PML in the closed conformation in the absence of Ca(2+) and in the presence of octane or trilaurin micelles showed that lid1 opens, while lid2 remains closed. These results suggest that Ca1 functions as a hook for stabilization of a fully opened conformation of lid1 and for initiation of subsequent opening of lid2.

Importance of a repetitive nine-residue sequence motif for intracellular stability and functional structure of a family I.3 lipase

PML5 is a functional derivative of a family I.3 lipase from Pseudomonas sp. MIS38 and contains five repeats of a nine‐residue sequence motif. Two aspartate residues within the second and third repetitive sequences of PML5 were replaced by Ala. The secretion level, intracellular accumulation level, and stability of the resultant mutant protein were greatly reduced as compared to those of PML5. In addition, this mutant protein was inactive and did not bind Ca2+ ion. We propose that the repetitive sequences of PML5 form a β‐roll structure in the cells and thereby contribute to the intracellular stability and secretion efficiency of the protein.

Engineering of monomeric FK506-binding protein 22 with peptidyl prolyl cis-trans isomerase

FK506‐binding protein 22 (FKBP22) from the psychrotrophic bacterium Shewanella sp. SIB1 is a homodimeric protein with peptidyl prolyl cis–trans isomerase (PPIase) (EC 5.2.1.8) activity. Each monomer consists of 205 amino acid residues. According to a tertiary model, SIB1 FKBP22 assumes a V‐shaped structure, in which two monomers interact with each other at their N‐termini. Each monomer consists of an N‐terminal domain with a dimerization core and a C‐terminal catalytic domain, which are separated by a 40‐residue‐long α‐helix. To clarify the role of this V‐shaped structure, we constructed a mutant protein, in which the N‐domain is tandemly repeated through a flexible linker. This protein, termed NNC‐FKBP22, is designed such that two repetitive N‐domains are folded into a structure similar to that of the Shewanella sp. SIB1 FKBP22 wild‐type protein (WT). NNC‐FKBP22 was overproduced in Escherichiau2003coli in a His‐tagged form, purified and biochemically characterized. Gel‐filtration chromatography and ultracentrifugation analyses indicate that NNC‐FKBP22 exists as a monomer. Analysis of thermal denaturation using differential scanning calorimetry indicates that NNC‐FKBP22 unfolds with two transitions, as does the WT protein. NNC‐FKBP22 exhibited PPIase activity for both peptide and protein substrates. However, in contrast to its activity for peptide substrate, which was comparable to that of the WT protein, its activity for protein substrate was reduced by five‐ to six‐fold, compared to that of the WT. Surface plasmon resonance analyses indicate that NNC‐FKBP22 binds to a reduced form of α‐lactalbumin with a six‐fold weaker affinity than that of WT. These results suggest that a V‐shaped structure of SIB1 FKBP22 is important for efficient binding to a protein substrate.

Importance of the Ca2+-binding sites in the N-catalytic domain of a family I.3 lipase for activity and stability.

A family I.3 lipase from Pseudomonas sp. MIS38 (PML) contains three Ca(2+)-binding sites (Ca1-Ca3) in the N-catalytic domain. Of them, the Ca1 site is formed only in an open conformation. To analyze the role of these Ca(2+)-binding sites, three mutant proteins D157A-PML, D275A-PML and D337A-PML, which are designed to remove the Ca1, Ca2 and Ca3 sites, respectively, were constructed. Of them, the crystal structures of D157A-PML and D337A-PML in a closed conformation were determined. Both structures are nearly identical to that of the wild-type protein, except that the Ca3 site is missing in the D337A-PML structure. D157A-PML was as stable as the wild-type protein. Nevertheless, it exhibited little lipase and very weak esterase activities. D275A-PML was less stable than the wild-type protein by approximately 5 degrees C in T(1/2). It exhibited weak but significant lipase and esterase activities when compared with the wild-type protein. D337A-PML was also less stable than the wild-type protein by approximately 5 degrees C in T(1/2) but was fully active. These results suggest that the Ca1 site is required to make the active site fully open by anchoring lid 1. The Ca2 and Ca3 sites contribute to the stabilization of PML. The Ca2 site is also required to make PML fully active.

Rational design of a glycosynthase by the crystal structure of β-galactosidase from Bacillus circulans (BgaC) and its use for the synthesis of N-acetyllactosamine type 1 glycan structures

The crystal structure of β-galactosidase from Bacillus circulans (BgaC) was determined at 1.8Å resolution. The overall structure of BgaC consists of three distinct domains, which are the catalytic domain with a TIM-barrel structure and two all-β domains (ABDs). The main-chain fold and steric configurations of the acidic and aromatic residues at the active site were very similar to those of Streptococcus pneumoniae β(1,3)-galactosidase BgaC in complex with galactose. The structure of BgaC was used for the rational design of a glycosynthase. BgaC belongs to the glycoside hydrolase family 35. The essential nucleophilic amino acid residue has been identified as glutamic acid at position 233 by site-directed mutagenesis. Construction of the active site mutant BgaC-Glu233Gly gave rise to a galactosynthase transferring the sugar moiety from α-d-galactopyranosyl fluoride (αGalF) to different β-linked N-acetylglucosamine acceptor substrates in good yield (40-90%) with a remarkably stable product formation. Enzymatic syntheses with BgaC-Glu233Gly afforded the stereo- and regioselective synthesis of β1-3-linked key galactosides like galacto-N-biose or lacto-N-biose.

Structure and stability of metagenome-derived glycoside hydrolase family 12 cellulase (LC-CelA) a homolog of Cel12A from Rhodothermus marinus☆

Ten genes encoding novel cellulases with putative signal peptides at the N‐terminus, termed pre‐LC‐CelA–J, were isolated from a fosmid library of a leaf–branch compost metagenome by functional screening using agar plates containing carboxymethyl cellulose and trypan blue. All the cellulases except pre‐LC‐CelG have a 14–29 residue long flexible linker (FL) between the signal peptide and the catalytic domain. LC‐CelA without a signal peptide (residues 20–261), which shows 76% amino acid sequence identity to Cel12A from Rhodothermus marinus (RmCel12A), was overproduced in Escherichia coli, purified and characterized. LC‐CelA exhibited its highest activity across a broad pH range (pH 5–9) and at 90 °C, indicating that LC‐CelA is a highly thermostable cellulase, like RmCel12A. The crystal structure of LC‐CelA was determined at 1.85 Å resolution and is nearly identical to that of RmCel12A determined in a form without the FL. Both proteins contain two disulfide bonds. LC‐CelA has a 16‐residue FL (residues 20–35), most of which is not visible in the electron density map, probably due to structural disorder. However, Glu34 and Pro35 form hydrogen bonds with the central region of the protein. ΔFL‐LC‐CelA (residues 36–261) and E34A‐LC‐CelA with a single Glu34 → Ala mutation were therefore constructed and characterized. ΔFL‐LC‐CelA and E34A‐LC‐CelA had lower melting temperatures (T m) than LC‐CelA by 14.7 and 12.0 °C respectively. The T m of LC‐CelA was also decreased by 28.0 °C in the presence of dithiothreitol. These results suggest that Glu34‐mediated hydrogen bonds and the two disulfide bonds contribute to the stabilization of LC‐CelA.

Importance of an extreme C-terminal motif of a family I.3 lipase for stability.

A five-residue sequence motif (VTLVG) located at positions 15-19 from the C-terminus of family I.3 lipase from Pseudomonas sp. MIS38 (PML) and an extreme C-terminal motif (DGIVIA) located at the C-terminus of PML are relatively well conserved in the passenger proteins of type 1 secretion system (T1SS). To analyze the role of these motifs, four mutant proteins of PML (PMLΔ5, PMLΔ10, 3A-PML and 2A-PML) were constructed. PMLΔ5 and PMLΔ10 lack the C-terminal 5 and 10 residues of PML, respectively. 3A-PML has triple mutations within an extreme C-terminal motif and 2A-PML has double mutations within a five-residue sequence motif. Secretion of these proteins was analyzed using Escherichia coli DH5 cells carrying Lip system (T1SS for family I.3 lipase). The secretion level of 2A-PML was dramatically reduced when compared with that of PML, whereas the secretion level of 3A-PML was comparable to that of PML, indicating that a five-residue sequence motif, instead of an extreme C-terminal motif, is required for secretion of PML. None of the mutations and truncations seriously affects the enzymatic activity of PML. However, 3A-PML, PMLΔ5 and PMLΔ10 were less stable than PML by 2.1, 7.6 and 7.6°C in T(1/2), respectively, and by 5.0, 21.3 and 17.9 kJ/mol in ΔG(H(2)O), respectively. These results indicate that an extreme C-terminal motif of PML is important for stability.