Shouhei Mine

Stabilization of an Immunoglobulin Fold Domain by an Engineered Disulfide Bond at the Buried Hydrophobic Region

We report for the first time the stabilization of an immunoglobulin fold domain by an engineered disulfide bond. In the llama single-domain antibody, which has human chorionic gonadotropin as its specific antigen, Ala49 and Ile70 are buried in the structure. A mutant with an artificial disulfide bond at this position showed a 10 °C higher midpoint temperature of thermal unfolding than that without the extra disulfide bond. The modified domains exhibited an antigen binding affinity comparable with that of the wild-type domain. Ala49 and Ile70 are conserved in camel and llama single-domain antibody frameworks. Therefore, domains against different antigens are expected to be stabilized by the engineered disulfide bond examined here. In addition to the effect of the loop constraints in the unfolded state, thermodynamic analysis indicated that internal interaction and hydration also control the stability of domains with disulfide bonds. The change in physical properties resulting from mutation often causes unpredictable and destabilizing effects on these interactions. The introduction of a hydrophobic cystine into the hydrophobic region maintains the hydrophobicity of the protein and is expected to minimize the unfavorable mutational effects.

Tertiary Structure and Carbohydrate Recognition by the Chitin-Binding Domain of a Hyperthermophilic Chitinase from Pyrococcus furiosus

A chitinase is a hyperthermophilic glycosidase that effectively hydrolyzes both alpha and beta crystalline chitins; that studied here was engineered from the genes PF1233 and PF1234 of Pyrococcus furiosus. This chitinase has unique structural features and contains two catalytic domains (AD1 and AD2) and two chitin-binding domains (ChBDs; ChBD1 and ChBD2). A partial enzyme carrying AD2 and ChBD2 also effectively hydrolyzes crystalline chitin. We determined the NMR and crystal structures of ChBD2, which significantly enhances the activity of the catalytic domain. There was no significant difference between the NMR and crystal structures. The overall structure of ChBD2, which consists of two four-stranded beta-sheets, was composed of a typical beta-sandwich architecture and was similar to that of other carbohydrate-binding module 2 family proteins, despite low sequence similarity. The chitin-binding surface identified by NMR was flat and contained a strip of three solvent-exposed Trp residues (Trp274, Trp308 and Trp326) flanked by acidic residues (Glu279 and Asp281). These acidic residues form a negatively charged patch and are a characteristic feature of ChBD2. Mutagenesis analysis indicated that hydrophobic interaction was dominant for the recognition of crystalline chitin and that the acidic residues were responsible for a higher substrate specificity of ChBD2 for chitin compared with that of cellulose. These results provide the first structure of a hyperthermostable ChBD and yield new insight into the mechanism of protein-carbohydrate recognition. This is important in the development of technology for the exploitation of biomass.

High-level expression of uniformly 15N-labeled hen lysozyme in Pichia pastoris and identification of the site in hen lysozyme where phosphate ion binds using NMR measurements.

The non‐enzymatic deamidation of Asn to Asp is known to occur in proteins and peptides and is accelerated by phosphate buffer [Tyler‐Cross, R. and Schirch, V. (1991) J. Biol. Chem. 25, 22549–22556]. We attempted to identify the site in lysozyme where a phosphate ion binds by means of 1H‐15N HSQC measurements of 15N‐labeled lysozyme, which was successfully obtained using Pichia pastoris. As a result, we found that the phosphate ion was preferentially bound to Asn‐103 in hen lysozyme. The method presented here may be useful for identifying the binding site of a protein with low molecular weight substances.

Structure of the catalytic domain of the hyperthermophilic chitinase from Pyrococcus furiosus

The crystal structure of the catalytic domain of a chitinase from the hyperthermophilic archaeon Pyrococcus furiosus (AD2(PF-ChiA)) has been determined at 1.5 A resolution. This is the first structure of the catalytic domain of an archaeal chitinase. The overall structure of AD2(PF-ChiA) is a TIM-barrel fold with a tunnel-like active site that is a common feature of family 18 chitinases. Although the catalytic residues (Asp522, Asp524 and Glu526) are conserved, comparison of the conserved residues and structures with those of other homologous chitinases indicates that the catalytic mechanism of PF-ChiA is different from that of family 18 chitinases.

Expression from engineered Escherichia coli chromosome and crystallographic study of archaeal N,N′‐diacetylchitobiose deacetylase

In order to develop a structure‐based understanding of the chitinolytic pathway in hyperthermophilic Pyrococcus species, we performed crystallographic studies on N,N′‐diacetylchitobiose deacetylases (Dacs) from Pyrococcus horikoshii (Ph‐Dac) and Pyrococcus furiosus (Pf‐Dac). Neither Ph‐Dac nor Pf‐Dac was expressed in the soluble fraction of Escherichia coli harboring the expression plasmid. However, insertion of the target genes into the chromosome of E. coli yielded the soluble recombinant protein. The purified Pyrococcus Dacs were active and thermostable up to 85 °C. The crystal structures of Ph‐Dac and Pf‐Dac were determined at resolutions of 2.0 Å and 1.54 Å, respectively. The Pyrococcus Dac forms a hexamer composed of two trimers. These Dacs are characterized by an intermolecular cleft, which is formed by two polypeptides in the trimeric assembly. In Ph‐Dac, catalytic Zn situated at the end of the cleft is coordinated by three side chain ligands from His44, Asp47, and His155, and by a phosphate ion derived from the crystallization reservoir solution. We considered that the bound phosphate mimicked the tetrahedral oxyanion, which is an intermediate of hydrolysis of the N‐acetyl group, and proposed an appropriate reaction mechanism. In the proposed mechanism, the Nε atom of His264 (from the adjacent polypeptide in the Ph‐Dac sequence) is directly involved in the stabilization of the oxyanion intermediate. Mutation analysis also indicated that His264 was essential to the catalysis. These factors give the archaeal Dacs an unprecedented active site architecture a Zn‐dependent deacetylases.

Solution structure of the chitin-binding domain 1 (ChBD1) of a hyperthermophilic chitinase from Pyrococcus furiosus.

A chitinase, from Pyrococcus furiosus, is a hyperthermophilic glycosidase that effectively hydrolyses both α and β crystalline chitin. This chitinase has unique structural features; it contains two catalytic domains (AD1 and AD2) and two chitin-binding domains (ChBD1 and ChBD2). We have determined the structure of ChBD1, which significantly enhances the activity of the catalytic domains, by nuclear magnetic resonance spectroscopy. The overall structure of ChBD1 had a compact and globular architecture consisting of three anti-parallel β-strands, similar to those of other proteins classified into carbohydrate-binding module (CBM) family 5. A mutagenesis experiment suggested three solvent-exposed aromatic residues (Tyr112, Trp113 and Tyr123) as the chitin-binding sites. The involvement of Tyr123 or the corresponding aromatic residues in other CBMs, has been demonstrated for the first time. This result indicates that the binding mode may be different from those of other chitin-binding domains in CBM family 5. In addition, the binding affinities of ChBD1 and ChBD2 were quite different, suggesting that the two ChBDs each play a different role in efficiently increasing the activities of AD1 and AD2.

Characterization and crystal structure of the thermophilic ROK hexokinase from Thermus thermophilus

We characterized and determined the crystal structure of a putative glucokinase/hexokinase from Thermus thermophilus that belongs to the ROK (bacterial repressors, uncharacterized open reading frames, and sugar kinases) family. The protein possessed significant enzymatic activity against glucose and mannose, with V(max) values of 260 and 68 μmol·min(-1)·mg(-1) protein, respectively. Therefore, we concluded that the enzyme is a hexokinase. However, the hexokinase showed little catalytic capacity for galactose and fructose. Circular dichroism measurements indicated that the enzyme was structurally stable at 90°C. The crystal structure of the enzyme was determined at a resolution of 2.02 Å, with R(cryst) and R(free) values of 18.1% and 22.6%, respectively. The polypeptide structure was divided into large and small domains. The ROK consensus sequences 1 and 2 were included in the large domain. The cysteine-rich consensus sequence 2 folded into a zinc finger, and the bound zinc was confirmed by both electron density and X-ray absorption fine structure (XAFS) spectrum. The overall structure was a homotetramer that consisted of a dimer of dimers. The accessible surface area buried by the association of the dimers into the tetrameric structures was significantly higher in the T. thermophilus enzyme than in a homologous tetrameric ROK sugar kinase.

Expression, refolding, and purification of active diacetylchitobiose deacetylase from Pyrococcus horikoshii.

A chitinase from the hyperthermophilic archaeon Pyrococcus furiosus degrades chitin to produce diacetylchitobiose [(GlcNAc)(2)] as the end product. To further investigate the degradation mechanism of (GlcNAc)(2) in Pyrococcus spp., we cloned the gene of PH0499 from Pyrococcus horikoshii, which encodes a protein homologous to the diacetylchitobiose deacetylase of Thermococcus kodakaraensis. The deacetylase (Ph-Dac) was overexpressed as inclusion bodies in Escherichia coli Rosetta (DE3) pLys. The insoluble inclusion body was solubilized and reactivated through a refolding procedure. After several purification steps, 40 mg of soluble, thermostable (up to 80°C) Ph-Dac was obtained from 1L of culture. The apparent molecular mass of the refolded Ph-Dac was 180 kDa, indicating Ph-Dac to be a homohexamer. The refolded Ph-Dac also exhibited deacetylase activity toward (GlcNAc)(2), and the deacetylation site was revealed to be specific to the nonreducing end residue of (GlcNAc)(2). These expression and purification systems are useful for further characterization of Ph-Dac.

Functional Role of the C-Terminal Amphipathic Helix 8 of Olfactory Receptors and Other G Protein-Coupled Receptors.

G protein-coupled receptors (GPCRs) transduce various extracellular signals, such as neurotransmitters, hormones, light, and odorous chemicals, into intracellular signals via G protein activation during neurological, cardiovascular, sensory and reproductive signaling. Common and unique features of interactions between GPCRs and specific G proteins are important for structure-based design of drugs in order to treat GPCR-related diseases. Atomic resolution structures of GPCR complexes with G proteins have revealed shared and extensive interactions between the conserved DRY motif and other residues in transmembrane domains 3 (TM3), 5 and 6, and the target G protein C-terminal region. However, the initial interactions formed between GPCRs and their specific G proteins remain unclear. Alanine scanning mutagenesis of the murine olfactory receptor S6 (mOR-S6) indicated that the N-terminal acidic residue of helix 8 of mOR-S6 is responsible for initial transient and specific interactions with chimeric Gα15_olf, resulting in a response that is 2.2-fold more rapid and 1.7-fold more robust than the interaction with Gα15. Our mutagenesis analysis indicates that the hydrophobic core buried between helix 8 and TM1–2 of mOR-S6 is important for the activation of both Gα15_olf and Gα15. This review focuses on the functional role of the C-terminal amphipathic helix 8 based on several recent GPCR studies.

Crystallization and X-ray diffraction analysis of a catalytic domain of hyperthermophilic chitinase from Pyrococcus furiosus.

The crystallization and preliminary X-ray diffraction analysis of a catalytic domain of chitinase (PF1233 gene) from the hyperthermophilic archaeon Pyrococcus furiosus is reported. The recombinant protein, prepared using an Escherichia coli expression system, was crystallized by the hanging-drop vapour-diffusion method. An X-ray diffraction data set was collected at the undulator beamline BL44XU at SPring-8 to a resolution of 1.50 angstroms. The crystals belong to space group P2(1)2(1)2(1), with unit-cell parameters a = 90.0, b = 92.8, c = 107.2 angstroms.