Structural Analysis and Construction of a Thermostable Antifungal Chitinase.

Chitin is a biopolymer of N-acetyl-d-glucosamine with ß-1,4-bond and is the main component of arthropod exoskeletons and the cell walls of many fungi. Chitinase (EC 3.2.1.14) is an enzyme that hydrolyzes the ß-1,4-bond in chitin and degrades chitin into oligomers. It has been found in a wide range of organisms. Chitinase from Gazyumaru (Ficus microcarpa) latex exhibits antifungal activity by degrading chitin in the cell wall of fungi and is expected to be used in medical and agricultural fields. However, the enzyme's thermostability is an important factor; chitinase is not thermostable enough to maintain its activity under the actual application conditions. In addition to the fact that thermostable chitinases exhibiting antifungal activity can be used under various conditions, they have some advantages for the production process and long-term preservation, which are highly demanded in industrial use. We solved the crystal structure of chitinase to explore the target sites to improve its thermostability. We rationally introduced proline residues, a disulfide bond, and salt bridges in the chitinase using protein-engineering methods based on the crystal structure and sequence alignment among other chitinases. As a result, we successfully constructed the thermostable mutant chitinases rationally with high antifungal and specific activities. The results provide a useful strategy to enhance the thermostability of this enzyme family. IMPORTANCE We solved the crystal structure of the chitinase from Gazyumaru (Ficus microcarpa) latex exhibiting antifungal activity. Furthermore, we demonstrated that the thermostable mutant enzyme with a melting temperature (Tm) 6.9°C higher than wild type (WT) and a half-life at 60°C that is 15 times longer than WT was constructed through 10 amino acid substitutions, including 5 proline residues substitutions, making disulfide bonding, and building a salt bridge network in the enzyme. These mutations do not affect its high antifungal activity and chitinase activity, and the principle for the construction of the thermostable chitinase was well explained by its crystal structure. Our results provide a useful strategy to enhance the thermostability of this enzyme family and to use the thermostable mutant as a seed for antifungal agents for practical use.

Ensemble structural analyses depict the regulatory mechanism of non-phosphorylated human MAP2K4.

Mitogen-activated protein kinase kinase 4 (MAP2K4) plays a critical role in regulating the stress-activated protein kinase signaling cascade. A small angle X-ray scattering experiment, a powerful technique for analyzing a solution structure cleared from the structural artifacts due to crystal packing, provided the ensemble structures of human non-phosphorylated MAP2K4 in three states involving the apo form, the binary complex with an ATP analogue, and the ternary complex with the ATP analogue and substrate peptide. These ensemble structures provided more detailed mechanisms for regulating MAP2K4 in addition to those delineated only by the crystal structures in three states.

Long-Term Stability and Reversible Thermal Unfolding of Antibody Structure at Low pH: Case Study.

We have here observed that the differential scanning calorimetry profiles and melting temperatures of a humanized antibody were unchanged over a 10-year span when stored at 4°C and at different pH values, even at pH 2.7. This is somewhat surprising, as this particular antibody undergoes conformational changes below pH 4.0. Differential scanning calorimetry analysis showed that melting of the antibody at pH 2.7 was highly reversible, suggesting a possibility that the observed reversibility is at least in part responsible for a 10-year stability at low pH. Conversely, it showed thermal unfolding followed by aggregation at higher pH.

High-resolution structure discloses the potential for allosteric regulation of mitogen-activated protein kinase kinase 7.

Mitogen-activated protein kinase kinase 7 (MAP2K7) regulates stress and inflammatory responses, and is an attractive drug discovery target for several diseases including arthritis and cardiac hypertrophy. Intracellular proteins such as MAP2K7 are prone to aggregation due to cysteine-driven oxidation in in vitro experiments. MAP2K7 instability due to the four free cysteine residues on the molecular surface abrogated the crystal growth and led to a low-resolution structure with large residual errors. To acquire a higher resolution structure for promoting rational drug discovery, we explored stable mutants of MAP2K7 by replacing the surface cysteine residues, Cys147, Cys218, Cys276 and Cys296. Single-site mutations, except for Cys147, maintained the specific activity and increased the protein yield, while all the multi-site mutations massively reduced the activity. The C218S mutation drastically augmented the protein production and crystallographic resolution. Furthermore, the C218S crystals grown under microgravity in a space environment yielded a 1.3 Å resolution structure, providing novel insights for drug discovery: the precisely assigned water molecules in the active site, the double conformations in the flexible region and the C-terminal extension bound to the N-terminal region of the adjacent molecules. The latter insight is likely to promote the production of allosteric MAP2K7 inhibitors.

Pronounced effect of hapten binding on thermal stability of an anti-(4-hydroxy-3-nitrophenyl)acetyl antibody possessing a glycine residue at position 95 of the heavy chain.

Immune response to T-cell-dependent antigens is highly dynamic; several B-cell clones responsible for antibody production appear alternately during immunization. It was previously shown that at least two-types of antibodies are secreted after immunization with (4-hydroxy-3-nitrophenyl)acetyl (NP); one has Tyr and another has Gly at position 95 of the heavy chain (referred to as Tyr95- and Gly95-type). The former appeared at an early stage, while the latter appeared at a late stage, i.e., after secondary immunization, although Fv domains of these antibodies were encoded by same genes of variable heavy and light chains. We examined whether any biophysical properties of antigen-combing sites relate to this shift in B-cell clones by preparing single-chain Fv (scFv). Thermodynamic and kinetic parameters of the interaction of scFv with various haptens are in accordance with those of intact antibodies, indicating that scFvs are appropriate models for the study on structure and function of antibodies. Next, we measured thermal stability of scFvs using differential scanning calorimetry and found that the apparent melting temperature of free Tyr95-type was 64-66°C,while that of Gly95-type was 47-48°C, indicating that the latter was highly unstable. However, Gly95-type greatly gained thermal stability because of hapten binding. We discussed the relationship between thermal stability resulted by hapten binding and dynamism of antibody response during immunization.

Ubiquitylation Directly Induces Fold Destabilization of Proteins.

Ubiquitin is a common post-translational modifier and its conjugation is a key signal for proteolysis by the proteasome. Because the molecular mass of ubiquitin is larger than that of other modifiers such as phosphate, acetyl, or methyl groups, ubiquitylation not only influences biochemical signaling, but also may exert physical effects on its substrate proteins by increasing molecular volume and altering shape anisotropy. Here we show that ubiquitylation destabilizes the fold of two proteins, FKBP12 and FABP4, and that elongation of the conjugated ubiquitin chains further enhances this destabilization effect. Moreover, NMR relaxation analysis shows that ubiquitylation induces characteristic structural fluctuations in the backbone of both proteins. These results suggest that the ubiquitylation-driven structural fluctuations lead to fold destabilization of its substrate proteins. Thus, physical destabilization by ubiquitylation may facilitate protein degradation by the proteasome.

Construction of Thermophilic Xylanase and Its Structural Analysis.

The glycoside hydrolase family 11 xylanase has been utilized in a wide variety of industrial applications, from food processing to kraft pulp bleaching. Thermostability enhances the economic value of industrial enzymes by making them more robust. Recently, we determined the crystal structure of an endo-ß-1,4-xylanase (GH11) from mesophilic Talaromyces cellulolyticus, named XylC. Ligand-free XylC exists to two conformations (open and closed forms). We found that the "closed" structure possessed an unstable region within the N-terminal region far from the active site. In this study, we designed the thermostable xylanase by the structure-based site-directed mutagenesis on the N-terminal region. In total, nine mutations (S35C, N44H, Y61M, T62C, N63L, D65P, N66G, T101P, and S102N) and an introduced disulfide bond of the enzyme contributed to the improvement in thermostability. By combining the mutations, we succeeded in constructing a mutant for which the melting temperature was partially additively increased by >20 °C (measured by differential scanning calorimetry) and the activity was additively enhanced at elevated temperatures, without loss of the original specific activity. The crystal structure of the most thermostable mutant was determined at 2.0 Å resolution to elucidate the structural basis of thermostability. From the crystal structure of the mutant, it was revealed that the formation of a disulfide bond induces new C-C contacts and a conformational change in the N-terminus. The resulting induced conformational change in the N-terminus is key for stabilizing this region and for constructing thermostable mutants without compromising the activity.

Structural and binding properties of laminarin revealed by analytical ultracentrifugation and calorimetric analyses.

One of the ß-1,3-glucans, laminarin, has been widely used as a substrate for enzymes including endo-1,3-ß-glucanase. To obtain quantitative information about the molecular interaction between laminarin and endo-1,3-ß-glucanase, the structural properties of laminarin should be determined. The results from pioneering work using analytical ultracentrifugation for carbohydrate analysis showed that laminarin from Laminaria digitata predominantly exists as a single-chain species with approximately 5% of triple-helical species. Differential scanning calorimetry experiments did not show a peak assignable to the transition from triple-helix to single-chain, supporting the notion that a large proportion of laminarin is the single-chain species. The interaction of laminarin with an inactive variant of endo-1,3-ß-glucanase from Cellulosimicrobium cellulans, E119A, was quantitatively analyzed using isothermal titration calorimetry. The binding was enthalpically driven and the binding affinity was approximately 10(6) M(-1). The results from binding stoichiometric analysis indicated that on average, E119A binds to laminarin in a 2:1 ratio. This seems to be reasonable, because laminarin mainly exists as a monomer, the apparent molecular mass of laminarin is 3.6 kDa, and E119A would have substrate-binding subsites corresponding to 6 glucose units. The analytical ultracentrifugation experiments could detect different complex species of laminarin and endo-1,3-ß-glucanase.

Structural dynamics of a single-chain Fv antibody against (4-hydroxy-3-nitrophenyl)acetyl.

Protein structure dynamics are critical for understanding structure-function relationships. An antibody can recognize its antigen, and can evolve toward the immunogen to increase binding strength, in a process referred to as affinity maturation. In this study, a single-chain Fv (scFv) antibody against (4-hydroxy-3-nitrophenyl)acetyl, derived from affinity matured type, C6, was designed to comprise the variable regions of light and heavy chains connected by a (GGGGS)3 linker peptide. This scFv was expressed in Escherichia coli in the insoluble fraction, solubilized in the presence of urea, and refolded by stepwise dialysis. The correctly refolded scFv was purified, and its structural, physical, and functional properties were analyzed using analytical ultracentrifugation, circular dichroism spectrometry, differential scanning calorimetry, and surface plasmon resonance biosensor. Thermal stability of C6 scFv increased greatly upon antigen binding, due to favorable enthalpic contributions. Antigen binding kinetics were comparable to those of the intact C6 antibody. Structural dynamics were analyzed using the diffracted X-ray tracking method, showing that fluctuations were suppressed upon antigen binding. The antigen binding energy determined from the angular diffusion coefficients was in good agreement with that calculated from the kinetics analysis, indicating that the fluctuations detected at single-molecule level are well reflected by antigen binding events.

Hyperstabilization of Tetrameric Bacillus sp. TB-90 Urate Oxidase by Introducing Disulfide Bonds through Structural Plasticity.

Bacillus sp. TB-90 urate oxidase (BTUO) is one of the most thermostable homotetrameric enzymes. We previously reported [Hibi, T., et al. (2014) Biochemistry 53, 3879-3888] that specific binding of a sulfate anion induced thermostabilization of the enzyme, because the bound sulfate formed a salt bridge with two Arg298 residues, which stabilized the packing between two ß-barrel dimers. To extensively characterize the sulfate-binding site, Arg298 was substituted with cysteine by site-directed mutagenesis. This substitution markedly increased the protein melting temperature by ∼ 20 °C compared with that of the wild-type enzyme, which was canceled by reduction with dithiothreitol. Calorimetric analysis of the thermal denaturation suggested that the hyperstabilization resulted from suppression of the dissociation of the tetramer into the two homodimers. The crystal structure of R298C at 2.05 Å resolution revealed distinct disulfide bond formation between the symmetrically related subunits via Cys298, although the Cß distance between Arg298 residues of the wild-type enzyme (5.4 Å apart) was too large to predict stable formation of an engineered disulfide cross-link. Disulfide bonding was associated with local disordering of interface loop II (residues 277-300), which suggested that the structural plasticity of the loop allowed hyperstabilization by disulfide formation. Another conformational change in the C-terminal region led to intersubunit hydrogen bonding between Arg7 and Asp312, which probably promoted mutant thermostability. Knowledge of the disulfide linkage of flexible loops at the subunit interface will help in the development of new strategies for enhancing the thermostabilization of multimeric proteins.

Folding thermodynamics of c-Myb DNA-binding domain in correlation with its α-helical contents.

The conformational and thermal stabilities of the minimum functional unit for c-Myb DNA-binding domain, tandem repeat 2 and 3 (R2R3), were analyzed under different pH conditions, ranging from 4.0 to 7.5, using circular dichroism and differential scanning calorimetry. Secondary structure analysis showed that the solution pH largely affects the conformational stability of the protein domain. Of all conditions analyzed, the α-helical content was maximal at pH 6.5, and the thermal stability was highest at pH 5.0. Thermodynamic parameters for thermal unfolding of R2R3 were determined using differential scanning calorimetry, and the origin of folding thermodynamics at the different pHs and its correlation with the α-helical content were further analyzed. It should be noted that the α-helical content correlates well with the enthalpy change in the pH range from 4.5 to 7.5, suggesting that the strength of hydrogen bonds and salt bridges needed for maintenance of helical structure is related to enthalpy in the native state. Under physiological pH conditions, c-Myb R2R3 exists in the enthalpically unstable but entropically stable state. Due to loss of rigid structure and high stability, the protein can now obtain structural flexibility, befitting its function.

Structural and physical properties of collagen extracted from moon jellyfish under neutral pH conditions.

We extracted collagen from moon jellyfish under neutral pH conditions and analyzed its amino acid composition, secondary structure, and thermal stability. The content of hydroxyproline was 4.3%, which is lower than that of other collagens. Secondary structure analysis using circular dichroism (CD) showed a typical collagen helix. The thermal stability of this collagen at pH 3.0 was lower than those from fish scale and pig skin, which also correlates closely with jellyfish collagen having lower hydroxyproline content. Because the solubility of jellyfish collagen used in this study at neutral pH was quite high, it was possible to analyze its structural and physical properties under physiological conditions. Thermodynamic analysis using CD and differential scanning calorimetry showed that the thermal stability at pH 7.5 was higher than at pH 3.0, possibly due to electrostatic interactions. During the process of unfolding, fibrillation would occur only at neutral pH.

Crystal structure of an acetylesterase from Talaromyces cellulolyticus and the importance of a disulfide bond near the active site.

Carbohydrate esterase catalyzes the de-O or de-N-acylation of substituted saccharides in plant cell walls and thus has great potential for industrial biomass saccharification. We recently identified the putative carbohydrate esterase family 3 (CE3) from Talaromyces cellulolyticus. Here, we prepared the recombinant catalytic domain of the enzyme and crystallized it. The crystal structure was determined to 1.5 Å resolution. From the structural analysis, it was elucidated that a n-octyl-ß-D-glucopyranoside bound to near the catalytic triad (Ser10, Asp179 and His182) and was buried in the active site cavity. Site-directed mutagenesis showed that the N-terminal disulfide bond located near the catalytic triad is involved in the activity and structural stability of the enzyme.

The unexpected role of polyubiquitin chains in the formation of fibrillar aggregates.

Ubiquitin is known to be one of the most soluble and stably folded intracellular proteins, but it is often found in inclusion bodies associated with various diseases including neurodegenerative disorders and cancer. To gain insight into this contradictory behaviour, we have examined the physicochemical properties of ubiquitin and its polymeric chains that lead to aggregate formation. We find that the folding stability of ubiquitin chains unexpectedly decreases with increasing chain length, resulting in the formation of amyloid-like fibrils. Furthermore, when expressed in cells, polyubiquitin chains covalently linked to EGFP also form aggregates depending on chain length. Notably, these aggregates are selectively degraded by autophagy. We propose a novel model in which the physical and chemical instability of polyubiquitin chains drives the formation of fibrils, which then serve as an initiation signal for autophagy.

Role of the aminotransferase domain in Bacillus subtilis GabR, a pyridoxal 5'-phosphate-dependent transcriptional regulator.

MocR/GabR family proteins are widely distributed prokaryotic transcriptional regulators containing pyridoxal 5'-phosphate (PLP), a coenzyme form of vitamin B6. The Bacillus subtilis GabR, probably the most extensively studied MocR/GabR family protein, consists of an N-terminal DNA-binding domain and a PLP-binding C-terminal domain that has a structure homologous to aminotransferases. GabR suppresses transcription of gabR and activates transcription of gabT and gabD, which encode γ-aminobutyrate (GΑΒΑ) aminotransferase and succinate semialdehyde dehydrogenase, respectively, in the presence of PLP and GABA. In this study, we examined the mechanism underlying GabR-mediated gabTD transcription with spectroscopic, crystallographic and thermodynamic studies, focusing on the function of the aminotransferase domain. Spectroscopic studies revealed that GABA forms an external aldimine with the PLP in the aminotransferase domain. Isothermal calorimetry demonstrated that two GabR molecules bind to the 51-bp DNA fragment that contains the GabR-binding region. GABA minimally affected ΔG(binding) upon binding of GabR to the DNA fragment but greatly affected the contributions of ΔH and ΔS to ΔG(binding). GABA forms an external aldimine with PLP and causes a conformational change in the aminotransferase domain, and this change likely rearranges GabR binding to the promoter and thus activates gabTD transcription.

Intersubunit salt bridges with a sulfate anion control subunit dissociation and thermal stabilization of Bacillus sp. TB-90 urate oxidase.

The optimal activity of Bacillus sp. TB-90 urate oxidase (BTUO) is 45 °C, but this enzyme is one of the most thermostable urate oxidases. A marked increase (>10 °C) in its thermal stability is induced by high concentrations (0.8­1.2 M) of sodium sulfate. Calorimetric measurements and size exclusion chromatographic analyses suggested that sulfate-induced thermal stabilization is related to the binding of a sulfate anion that repressed the dissociation of BTUO tetramers into dimers. To determine the sulfate binding site, the crystal structure was determined at 1.75 Å resolution. The bound sulfate anion was found at the subunit interface of the symmetrical related subunits and formed a salt bridge with two Arg298 residues in the flexible loop that is involved in subunit assembly. Site-directed mutagenesis of Arg298 to Glu was used to extensively characterize the sulfate binding site at the subunit interface. The network of charged hydrogen bonds via the bound sulfate is suggested to contribute significantly to the thermal stabilization of both subunit dimers and the tetrameric assembly of BTUO. Knowledge of the mechanism of salt-induced stabilization will help to develop new strategies for enhancing protein thermal stabilization.

Thermodynamic effects of multiple protein conformations on stability and DNA binding.

The side-chain conformations of amino acids in the hydrophobic core are important for protein folding and function. A previous NMR study has shown that a mutant protein of transcriptional activator c-Myb, I155L/I181L R3, has multiple conformations and increased fluctuation in comparison with the wild type. To elucidate the quantitative correlation of structural fluctuation with stability and function, we analyzed the thermodynamic effects of I155L and I181L mutations, using R2R3 that encompasses the minimum specific DNA-binding region. Circular dichroism and differential scanning calorimetry measurements showed that the mutation of I155L had little effect on stability, while the I181L mutation significantly destabilized the protein. It is noteworthy that the decreased stability resulting from the I181L mutation was mainly due to decreased enthalpy change, which is partially compensated by decreased entropy change. Isothermal titration calorimetry measurements showed that the specific DNA-binding affinity was decreased owing to the I181L mutation, which was due to decreased binding entropy change. Entropy in the folded state, which corresponds to the DNA-free state, increases due to the I181L mutation because of the increased conformational fluctuation observed in I155L/I181L mutant of R2R3 by CLEANEX-PM NMR analysis, which in turn results in decreased folding entropy and DNA-binding entropy changes.

Utilization of lysine ¹³C-methylation NMR for protein-protein interaction studies.

Chemical modification is an easy way for stable isotope labeling of non-labeled proteins. The reductive (13)C-methylation of the amino group of the lysine side-chain by (13)C-formaldehyde is a post-modification and is applicable to most proteins since this chemical modification specifically and quickly proceeds under mild conditions such as 4 °C, pH 6.8, overnight. (13)C-methylation has been used for NMR to study the interactions between the methylated proteins and various molecules, such as small ligands, nucleic acids and peptides. Here we applied lysine (13)C-methylation NMR to monitor protein-protein interactions. The affinity and the intermolecular interaction sites of methylated ubiquitin with three ubiquitin-interacting proteins were successfully determined using chemical-shift perturbation experiments via the (1)H-(13)C HSQC spectra of the (13)C-methylated-lysine methyl groups. The lysine (13)C-methylation NMR results also emphasized the importance of the usage of side-chain signals to monitor the intermolecular interaction sites, and was applicable to studying samples with concentrations in the low sub-micromolar range.

Seven cysteine-deficient mutants depict the interplay between thermal and chemical stabilities of individual cysteine residues in mitogen-activated protein kinase c-Jun N-terminal kinase 1.

Intracellular proteins can have free cysteines that may contribute to their structure, function, and stability; however, free cysteines can lead to chemical instabilities in solution because of oxidation-driven aggregation. The MAP kinase, c-Jun N-terminal kinase 1 (JNK1), possesses seven free cysteines and is an important drug target for autoimmune diseases, cancers, and apoptosis-related diseases. To characterize the role of cysteine residues in the structure, function, and stability of JNK1, we prepared and evaluated wild-type JNK1 and seven cysteine-deficient JNK1 proteins. The nonreduced sodium dodecyl sulfate-polyacrylamide gel electrophoresis experiments showed that the chemical stability of JNK1 increased as the number of cysteines decreased. The contribution of each cysteine residue to biological function and thermal stability was highly susceptible to the environment surrounding the particular cysteine mutation. The mutations of solvent-exposed cysteine to serine did not influence biological function and increased the thermal stability. The mutation of the accessible cysteine involved in the hydrophobic pocket did not affect biological function, although a moderate thermal destabilization was observed. Cysteines in the loosely assembled hydrophobic environment moderately contributed to thermal stability, and the mutations of these cysteines had a negligible effect on enzyme activity. The other cysteines are involved in the tightly filled hydrophobic core, and mutation of these residues was found to correlate with thermal stability and enzyme activity. These findings about the role of cysteine residues should allow us to obtain a stable JNK1 and thus promote the discovery of potent JNK1 inhibitors.

Systematic interaction analysis of human lipocalin-type prostaglandin D synthase with small lipophilic ligands.

L-PGDS [lipocalin-type PG (prostaglandin) D synthase] is a multi-functional protein, acting as a PGD2-producing enzyme and a lipid-transporter. In the present study, we focus on the function of L-PGDS as an extracellular transporter for small lipophilic molecules. We characterize the binding mechanism of human L-PGDS for the molecules, especially binding affinity stoichiometry and driving force, using tryptophan fluorescence quenching, ICD (induced circular dichroism) and ITC (isothermal titration calorimetry). The tryptophan fluorescence quenching measurements revealed that haem metabolites such as haemin, biliverdin and bilirubin bind to L-PGDS with significantly higher affinities than the other small lipophilic ligands examined, showing dissociation constant (K(d)) values from 17.0 to 20.9 nM. We focused particularly on the extra-specificities of haem metabolites and L-PGDS. The ITC and ICD data revealed that two molecules of the haem metabolites bind to L-PGDS with high and low affinities, showing K(d) values from 2.8 to 18.1 nM and from 0.209 to 1.63 µM respectively. The thermodynamic parameters for the interactions revealed that the contributions of enthalpy and entropy change were considerably different for each haem metabolite even when the Gibbs energy change was the same. Thus we believe that the binding energy of haem metabolites to L-PGDS is optimized by balancing enthalpy and entropy change.