Different behavior of Ferguson plot between agarose and polyacrylamide gels.

In this study, we conducted Ferguson plot analyses using both agarose and polyacrylamide gels in native electrophoresis and SDS-PAGE. The results revealed intriguing differences in the behavior of bovine serum albumin (BSA) and other model proteins. Specifically, BSA exhibited Ferguson plot slopes that were dependent on the oligomer size in agarose native gel electrophoresis, while such size-dependent behavior was not observed in native-PAGE or SDS-PAGE. These findings suggest that Ferguson plot analysis is a suitable approach when using agarose gel under the electrophoretic conditions employed in this study. Furthermore, our investigation extended to model proteins with acidic isoelectric points and larger molecular weights, namely Ferritin and caseinolytic peptidase B (ClpB). Notably, these proteins displayed distinct Ferguson plot slopes when subjected to agarose gel electrophoresis. Intriguingly, when polyacrylamide gel was employed, ClpB exhibited multiple bands, each with its unique Ferguson plot slope, deviating from the expected behavior based on molecular size. This divergence in Ferguson plot characteristics between agarose and polyacrylamide gels points to an interesting and complex interplay between protein properties and gel electrophoresis conditions.

Structure Analysis of Proteins and Peptides by Difference Circular Dichroism Spectroscopy.

Difference circular dichroism (CD) spectroscopy was used here to characterize changes in structure of flexible peptides upon altering their environments. Environmental changes were introduced by binding to a large target structure, temperature shift (or concentration increase) or so-called membrane-mimicking solvents. The first case involved binding of a largely disordered peptide to its target structure associated with chromatin remodeling, leading to a transition into a highly helical structure. The second example was a short 8HD (His-Asp) repeat peptide that can bind metal ions. Both Zn and Ni at µM concentrations resulted in different type of changes in secondary structure, suggesting that these metal ions provide different environments for the peptide to assume unique secondary structures. The third case is related to a few short neuroprotective peptides that were largely disordered in aqueous solution. Increased temperature resulted in induction of significant, though small, ß-sheet structures. Last example was the induction of non-helical structures for short neuroprotective peptides by membrane-mimicking solvents, including trifluoroethanol, dodecylphosphocholine and sodium dodecylsulfate. While these agents are known to induce α-helix, none of the neuropeptides underwent transition to a typical helical structure. However, trifluoroethanol did induce α-helix for the first peptide involved in chromatin remodeling described above in the first example.

Salt Mediated Modulation of Autolysis of Thermolysin-Like Proteinase, Salilysin, Isolated from a Moderate Halophile, Chromohalobacter salexigens DSM3043.

Halophilic salilysin is first synthesized as a pro-form, which has been shown autolysis activity to process pro-region (55 amino acids long) three times to form intermediate 1 (I1), intermediate 2 (I2) and final mature (M) salilysin. The autolysis of I1- to M-form salilysin in vitro was significantly accelerated with increasing NaCl concentration up to 4 M. Strong salting-out salts, (NH4)2SO4, Na2SO4 and MgSO4, were more effective, suggesting that autolysis is enhanced by inter-molecular association or structure compaction or both. However, MgCl2, a salting-in salt, was also effective, suggesting that other mechanisms, such as charge shielding and ionic binding to this halophilic protein, operated. Autolytic cleavage at site 3 resulted in mixed formation of correctly and incorrectly processed mature forms in the absence of salt, indicating that salt affected the accuracy of autolytic cleavage reaction. Far UV circular dichroism (CD) measurements indicated that E167A pro-salilysin showed an identical CD spectrum to the wild-type mature salilysin, suggesting pro-form has a proper fold for proteolytic activity. Thermal scanning indicated that E167A pro-salilysin was more heat-stable by ~ 10 °C than mature form. The CD spectra, thermal stability and modeling structure of salilysin clearly suggested that pro-salilysin is folded to the same structure as native form and is functional for autolysis.

Expression and characterization of l-arabinose isomerase from Geobacillus stearothermophilus for improved activity under acidic condition.

A low-calorie sugar-substituting sweetener, d-tagatose, can be produced by l-arabinose isomerase (l-AI) from the substrate d-galactose. However, this process suffers from a Maillard reaction when performed at alkaline pH and high temperature. For industrial applications, therefore, a reaction under slightly acidic conditions is desirable to minimize the Maillard reaction. Previously, we obtained a mutant of l-AI, H18T, from Geobacillus stearothermophilus with greater substrate specificity. Although H18T possessed excellent thermostability, its activity under acidic conditions was not optimal. Here, we successfully obtained a potential variant of the H18T protein, H18T-Y234C, which achieved improved activity at pH 6.0, based on random mutagenesis using error-prone PCR around the binding pocket area of H18T. This double H18T-Y234C mutant possessed 1.8-fold and 3-fold higher activity at pH 6.0 than the parent H18T and the wild type, thereby broadening the optimal pH range to 6.0-8.0. Mutation from Tyr to Cys at residue 234 had little effect on the secondary structure of L-AI. Furthermore, the formation of disulfide bonds was not detected. Thus, the improvement of activity at pH 6.0 is probably caused by the change in the binding pocket area involving residue 234. This study offers insight into the importance of residue 234 in improving the activity under acidic conditions.

Salt-enhanced processing, proteolytic activity and stability of halophilic thermolysin-like proteinase, salilysin, isolated from a moderate halophile, Chromohalobacter salexigens DSM3043.

Moderately halophilic bacterium, Chromohalobacter salexigens DSM3043, has a gene Csal_2537 encoding thermolysin-like M4 proteinase. This gene was cloned to pET expression vectors, resulting in high expression of recombinant proteinase, named as salilysin (salinity-dependent thermolysin-like proteinase), in Escherichia coli cytoplasm. This gene encodes precursor form of salilysin containing 348 amino acid residues (Pro-salilysin) consisting of 55 amino acids pro-sequence and following mature proteinase. Pro-sequence was cleaved three times to form intermediate 1, intermediate 2 and final mature salilysin. The processing rate was greatly accelerated in a salt concentration-dependent manner. Purified inactive mutant Pro-E167A-salilysin was correctly processed by purified mature salilysin, indicating that autolysis and inter-molecular processing occurred in its maturation processes. Proteolytic activity of mature salilysin against both peptide and protein substrates was also enhanced along with the addition of higher concentration of salt, 0-3.2 M NaCl, consistent with its halophilic origin. Mature salilysin was stabilized by ~8 °C in the presence of 1 M NaCl by thermal scanning using circular dichroism. One of the precursor form, intermediate 1, showed ~20 °C higher denaturation temperature than mature form, suggesting rigid and stable structure of this precursor form.

Catalytic mechanism and evolutionary characteristics of thioredoxin from Halobacterium salinarum NRC-1.

Thioredoxin (TRX) is an important antioxidant against oxidative stress. TRX from the extremely halophilic archaeon Halobacterium salinarum NRC-1 (HsTRX-A), which has the highest acidic residue content [(Asp + Glu)/(Arg + Lys + His) = 9.0] among known TRXs, was chosen to elucidate the catalytic mechanism and evolutionary characteristics associated with haloadaptation. X-ray crystallographic analysis revealed that the main-chain structure of HsTRX-A is similar to those of homologous TRXs; for example, the root-mean-square deviations on Cα atoms were <2.3 Šfor extant archaeal TRXs and <1.5 Šfor resurrected Precambrian TRXs. A unique water network was located near the active-site residues (Cys45 and Cys48) in HsTRX-A, which may enhance the proton transfer required for the reduction of substrates under a high-salt environment. The high density of negative charges on the molecular surface (3.6 × 10-3 e Å-2) should improve the solubility and haloadaptivity. Moreover, circular-dichroism measurements and enzymatic assays using a mutant HsTRX-A with deletion of the long flexible N-terminal region (Ala2-Pro17) revealed that Ala2-Pro17 improves the structural stability and the enzymatic activity of HsTRX-A under high-salt environments (>2 M NaCl). The elongation of the N-terminal region in HsTRX-A accompanies the increased hydrophilicity and acidic residue content but does not affect the structure of the active site. These observations offer insights into molecular evolution for haloadaptation and potential applications in halophilic protein-related biotechnology.

Expression, Folding, and Activation of Halophilic Alkaline Phosphatase in Non-Halophilic Brevibacillus choshinensis.

Halophilic enzymes contain a large number of acidic amino acids and marginal large hydrophobic amino acids, which make them highly soluble even under strongly hydrophobic conditions. This characteristic of halophilic enzymes provides potential for their industrial application. However, halophilic enzymes easily degrade when used for industrial applications compared with enzymes from other extremophiles because of their instability in low-salt environments. We aimed to clarify the stabilization mechanism of halophilic enzymes. We previously attempted to express halophilic alkaline phosphatase from Halomonas (HaALP) in non-halophilic E. coli. However, the expressed HaALP showed little activity. Therefore, we overexpressed HaALP in Gram-positive non-halophilic Brevibacillus choshinensis in this study, which was successfully expressed and purified in its active form. HaALP was denatured in 6 M urea, refolded using various salts and the non-ionic osmolyte trimethylamine N-oxide (TMAO), and assessed by native polyacrylamide gel electrophoresis. HaALP refolded in 3 M NaCl or 3 M TMAO containing Na+ ions. Hydrophobic interactions due to a high salt concentration or TMAO enhanced the formation of the folding intermediate (the monomer precursor), and only Na+ ions activated the dimer form. This insight into the stabilization mechanism of HaALP may lead to the development of industrial applications of halophilic enzymes under low-salt conditions.

Insoluble expression of highly soluble halophilic metal binding protein for metal ion biosorption: Application of aggregation-prone peptide from hen egg white lysozyme.

Insoluble expression of intrinsically soluble proteins with native activity is potentially a promising alternative to soluble expression of folded protein or insoluble expression of unfolded protein requiring refolding. Here, we attempted to express highly soluble halophilic His-rich metal binding protein (HP) as insoluble inclusion bodies with native metal-binding activity using insolubilizing nona-peptide (Ins), GILQINSRW, derived from hen egg white lysozyme (His-InsHP). About 80% of expressed His-InsHP was localized in inclusion bodies in Na-phosphate/NaCl buffer, pH 7.4, while His-HP without Ins peptide was exclusively expressed in soluble supernatant. We report expression, purification and characterization of this insoluble His-InsHP, and its possible application for efficient biosorption and recovery of environmental metal ions, for example, by using whole bacterial cells expressing insoluble His-InsHP as a new cost-effective metal ion-adsorbent.

Two Elution Mechanisms of MEP Chromatography.

MEP (mercapto-ethyl-pyridine) HyperCel is one of the hydrophobic charge induction chromatography (HCIC) resins. Under normal operation, proteins are bound to the MEP resin at neutral pH, at which MEP is not charged, mostly via hydrophobic interaction. MEP has a pyridine group, whose pK is 4.8, and hence is positively charged at acidic pH range. Based on the binding mechanism (i.e., hydrophobic interaction) and the induced positive charge at acidic pH, there may be two ways to elute the bound proteins. One way is to bring the pH down to protonate both MEP resin and the bound protein, leading to charge repulsion and thereby elution. Another way is to use hydrophobic interaction modifiers, which are often used in hydrophobic interaction chromatography, to reduce hydrophobic interaction. Here, we summarize such two possible elution approaches.

Improved substrate specificity for D-galactose of L-arabinose isomerase for industrial application.

L-Arabinose isomerase isolated from Geobacillus stearothermophilus (GSAI) was modified to improve its substrate specificity for D-galactose for the production of D-tagatose, a potential reduced-energy sweetener. Among the selected residues, mutation at residue 18 produced a mutant strain, H18T, which exhibited increased activity for D-galactose compared with the wild-type (WT) enzyme. Analysis of the substrate specificity of H18T showed a 45.4% improvement for D-galactose. Replacing histidine with threonine at residue 18 resulted in approximately 2.7-fold and 1.8-fold higher substrate binding and catalytic efficiency, respectively, for D-galactose. Further enhancement of the specific activity and catalytic efficiency of H18T for D-galactose by up to 2.7-fold and 4.3-fold, respectively, was achieved by adding borate during L-arabinose isomerase catalysis. Moreover, H18T showed thermostability and no destabilization was detected, which is promising for the industrial production of D-tagatose.

Efficient production of Trastuzumab Fab antibody fragments in Brevibacillus choshinensis expression system.

The Brevibacillus expression system has been successfully employed for the efficient productions of a variety of recombinant proteins, including enzymes, cytokines, antigens and antibody fragments. Here, we succeeded in secretory expression of Trastuzumab Fab antibody fragments using B. choshinensis/BIC (Brevibacillus in vivocloning) expression system. In the fed-batch high-density cell culture, recombinant Trastuzumab Fab with amino-terminal His-tag (His-BcFab) was secreted at high level, 1.25 g/liter, and Fab without His-tag (BcFab) at ∼145 mg/L of culture supernatant. His-BcFab and BcFab were purified to homogeneity using combination of conventional column chromatographies with a yield of 10-13%. This BcFab preparation exhibited native structure and functions evaluated by enzyme-linked immunosorbent assay, surface plasmon resonance, circular dichroism measurements and size exclusion chromatography. To our knowledge, this is the highest production of Fab antibody fragments in gram-positive bacterial expression/secretion systems.

Expression and characterization of the Renilla luciferase with the cumulative mutation.

Luciferase from Renilla reniformis (RLuc) is a good research tool as a reporter protein and bioimaging probes, yielding blue light using the substrate coelenterazine. However, the applications are limited since RLuc is unstable under various conditions. Therefore, an attempt was made to increase RLuc thermostability. In this study, 5 mutations reported previously [1] and one mutation obtained using site-directed mutagenesis were combined. As a result of this combination, the thermostability effect increased, with the mutant showing approximately 10 °C higher stability. Furthermore, the mutant simultaneously improved a tolerance for protease digestion, e.g. trypsin and proteinase K, and for organic solvent. Residual activity of the mutant after treatment with 10% 2-propanol, 10% DMF and 20% DMSO at 35 °C for 1 h was 29.4, 24.8 and 91.3%, respectively, whereas that of the wild type was 0.4, 0.1 and 24.3%, respectively.

Reversible Activation of Halophilic ß-lactamase from Methanol-Induced Inactive Form: Contrast to Irreversible Inactivation of Non-Halophilic Counterpart.

Effects of a water-miscible organic solvent, methanol, on the structure and activity of halophilic ß-lactamase derived from Chromohalobacter sp.560 (HaBla), were investigated by means of circular dichroism (CD) measurement and enzymatic activity determination. Beta-lactamase activity was enhanced about 1.2-fold in the presence of 10-20% methanol. CD measurement of HaBla revealed different structures depending on the methanol concentration: native-like active form (Form I) in 10-20% methanol and methanol-induced inactive form at higher concentration (Form II in 40-60% and Form III in 75-80% methanol). Incubation of HaBla with 40% methanol led to the complete loss of activity within ~80 min accompanied by the formation of Form II, whose activity was recovered promptly up to ~80% of full activity upon dilution of the methanol concentration to 10%. In addition, when the protein concentration was sufficiently high (e.g., 0.7 mg/ml), HaBla activity of Form III in 75% methanol could be recovered in the same way (with slightly slower recovery rate), upon dilution of the methanol concentration. In contrast, non-halophilic ß-lactamase from Escherichia coli K12 strain MG1655 (EcBla) was irreversibly denatured in the presence of 40% methanol. HaBla showed remarkable ability to renature from the methanol-induced inactive states.

Unique Features of Halophilic Proteins.

Proteins from moderate and extreme halophiles have unique characteristics. They are highly acidic and hydrophilic, similar to intrinsically disordered proteins. These characteristics make the halophilic proteins soluble in water and fold reversibly. In addition to reversible folding, the rate of refolding of halophilic proteins from denatured structure is generally slow, often taking several days, for example, for extremely halophilic proteins. This slow folding rate makes the halophilic proteins a novel model system for folding mechanism analysis. High solubility and reversible folding also make the halophilic proteins excellent fusion partners for soluble expression of recombinant proteins.

Stabilization of luciferase from Renilla reniformis using random mutations.

We expressed luciferase (RLuc) from Renilla reniformis in Escherichia coli RLuc was purified using a Ni-NTA column and subsequently characterized. It was unstable in acidic solutions and at 30°C. To increase the stability of RLuc, the Rluc gene was randomly mutated using error-prone polymerase chain reaction. E. coli harboring the mutated gene was screened by detecting luminescence on a plate containing the substrate coelenterazine at 34°C. Three mutants, i.e. N264SS287P, N178D and F116LI137V, were obtained. The solubilities and specific activities of these mutants were higher than those of the wild type. Furthermore, the N264SS287P mutant maintained stability at a temperature approximately 5°C higher than that of the wild type, while denaturation of the F116LI137V mutant started at a temperature that was 5°C lower than the wild type, and ended at a temperature that was 7°C higher. We examined the obtained mutations using thermal shift assays and a computer program Coot in this study.

Nucleoside Diphosphate Kinase from Psychrophilic Pseudoalteromonas sp. AS-131 Isolated from Antarctic Ocean.

Nucleoside diphosphate kinase isolated from psychrophilic Pseudoalteromonas sp. AS-131 (ASNDK) was expressed in Escherichia coli and purified to homogeneity. Comparing to mesophilic NDK isolated from Pseudomonas aeruginosa, ASNDK exhibited highly elevated thermolability: E. coli expression at 37 °C as a denatured insoluble form, 30 °C lower optimum temperature of enzymatic activity, and greatly reduced heat stability with 38 °C lower Tm value, fourfold higher Km and reduced Kcat/Km by 0.4-fold upon reaction temperature increase from 20 to 37 °C. The subunit structure of ASNDK was suggested to be dimer, as in NDKs isolated from moderate halophiles.

Structure of a highly acidic ß-lactamase from the moderate halophile Chromohalobacter sp. 560 and the discovery of a Cs(+)-selective binding site.

Environmentally friendly absorbents are needed for Sr(2+) and Cs(+), as the removal of the radioactive Sr(2+) and Cs(+) that has leaked from the Fukushima Nuclear Power Plant is one of the most important problems in Japan. Halophilic proteins are known to have many acidic residues on their surface that can provide specific binding sites for metal ions such as Cs(+) or Sr(2+). The crystal structure of a halophilic ß-lactamase from Chromohalobacter sp. 560 (HaBLA) was determined to resolutions of between 1.8 and 2.9 Šin space group P31 using X-ray crystallography. Moreover, the locations of bound Sr(2+) and Cs(+) ions were identified by anomalous X-ray diffraction. The location of one Cs(+)-specific binding site was identified in HaBLA even in the presence of a ninefold molar excess of Na(+) (90 mM Na(+)/10 mM Cs(+)). From an activity assay using isothermal titration calorimetry, the bound Sr(2+) and Cs(+) ions do not significantly affect the enzymatic function of HaBLA. The observation of a selective and high-affinity Cs(+)-binding site provides important information that is useful for the design of artificial Cs(+)-binding sites that may be useful in the bioremediation of radioactive isotopes.

Highly efficient production of VHH antibody fragments in Brevibacillus choshinensis expression system.

Anti-IZUMO1PFF VHH (variable domain of camelid heavy chain antibody) clones, N6 and N15, from immunized alpaca (Lama pacos) phage library were efficiently expressed and their VHH products were secreted into the culture medium of Brevibacillus choshinensis HPD31-SP3, e.g., at a level of 26-95mg in 100ml conventional flask culture. With a 3-L scale fed-batch culture for 65h, the N15 VHH protein with C-terminal His-tag was produced at ∼3g/l culture medium. The N6 and N15 proteins were easily purified to apparent homogeneity by cation exchange and Ni-affinity chromatographies. Both proteins showed specific antigen-binding activity by ELISA and high antigen binding affinity, KD=6.0-8.6nM, by surface plasmon resonance analysis. Size exclusion chromatography-multi-angle laser light scattering analysis revealed that N6 and N15 proteins purified were exclusively monomeric form in phosphate buffered saline. CD spectrum showed beta-sheet rich structure, consistent with a typical antibody structure and also suggested aromatic-aromatic interactions, as indicated by a positive peak at 232nm. Thermal melting analysis of the N15 protein with C-terminal His-tag demonstrated a clear thermal transition with a Tm at 67°C. The heat-denatured sample recovered antigen binding activity upon cooling, indicating a reversible denaturation.

Structural characteristics of alkaline phosphatase from the moderately halophilic bacterium Halomonas sp. 593.

Alkaline phosphatase (AP) from the moderate halophilic bacterium Halomonas sp. 593 (HaAP) catalyzes the hydrolysis of phosphomonoesters over a wide salt-concentration range (1-4 M NaCl). In order to clarify the structural basis of its halophilic characteristics and its wide-range adaptation to salt concentration, the tertiary structure of HaAP was determined by X-ray crystallography to 2.1 Šresolution. The unit cell of HaAP contained one dimer unit corresponding to the biological unit. The monomer structure of HaAP contains a domain comprised of an 11-stranded ß-sheet core with 19 surrounding α-helices similar to those of APs from other species, and a unique `crown' domain containing an extended `arm' structure that participates in formation of a hydrophobic cluster at the entrance to the substrate-binding site. The HaAP structure also displays a unique distribution of negatively charged residues and hydrophobic residues in comparison to other known AP structures. AP from Vibrio sp. G15-21 (VAP; a slight halophile) has the highest similarity in sequence (70.0% identity) and structure (C(α) r.m.s.d. of 0.82 Šfor the monomer) to HaAP. The surface of the HaAP dimer is substantially more acidic than that of the VAP dimer (144 exposed Asp/Glu residues versus 114, respectively), and thus may enable the solubility of HaAP under high-salt conditions. Conversely, the monomer unit of HaAP formed a substantially larger hydrophobic interior comprising 329 C atoms from completely buried residues, whereas that of VAP comprised 264 C atoms, which may maintain the stability of HaAP under low-salt conditions. These characteristics of HaAP may be responsible for its unique functional adaptation permitting activity over a wide range of salt concentrations.

Cys139Ser mutation in dimeric nucleoside diphosphate kinase generates catalytically competent monomer.

Nucleoside diphosphate kinase from a moderate halophile Halomonas sp. 593 (HaNDK) is dimer, while NDK from different origins has been shown to assemble into hexamer, or tetramer. Similar to HaNDK, halophilic NDK from Chromohalobacter salexigens DSM3043 (CsNDK) formed dimeric structure. Cysteine139 conserved between HaNDK and CsNDK is located in the monomer/monomer interface. Substitution of Cys139 for Ser caused dissociation of dimeric CsNDK into monomer in Tris buffer, as determined by field flow fractionation technique. Circular dichroism (CD) profile of the mutant CsNDK was nearly identical to the wild type CsNDK: however, the mutant CsNDK became more susceptible to "endproteinase GluC" cleavage, which could be suppressed by an NDK substrate, ATP. The monomer was enzymatically active, although it is possible that active structure is dimer in the presence of substrate.