A novel "reverse screening" to identify refolding additives for activin-A

A general approach for refolding recombinant proteins from inclusion bodies (IBs) is to screen conditions, that facilitate a conversion of unfolded to folded structure and minimize a conversion of unfolded to misfolded and aggregated structures. In this simplified model, such conditions may be those that stabilize the native protein and/or reduce aggregation. In this paper, a novel screening approach, termed reverse screening, was developed using a native activin. Activin-A, a member of transforming growth factor beta superfamily, is a homodimeric protein with nine disulfide bonds. We examined partial unfolding process of native activin-A dissolved in a buffer containing moderate concentrations of denaturant and reducing reagent (i.e., 1.5 M urea and 0.2 mM dithiothreitol). The recovery of the protein was followed by reverse-phase high performance chromatography analysis. Without additives, activin-A showed about 60% loss of the protein due to aggregation after 12-h incubation in the above condition. We then tested various additives for their effects on the recovery after partial unfolding. One of these additives, sodium taurodeoxycholate (TDCA), greatly increased recovery and suppressed aggregation of the protein. These additives were then tested for refolding activin-A from IBs. TDCA among others is proved to be a highly effective refolding additive. These results strongly suggest that reverse screening using native proteins, if available, may be another approach to discovering effective refolding additives.     

Identification of a cell-active non-peptide sirtuin inhibitor containing N-thioacetyl lysine

To identify cell-active sirtuin inhibitors containing N-thioacetyl lysine, we synthesized compound 1, which was designed based on the structure of the reported N-ethoxycarbonylacetyl lysine-based sirtuin inhibitor NCS-12k. Compound 1 selectively inhibited SIRT1 in enzyme assays. Compound 1 also caused a dose-dependent increase in p53 acetylation in human colon cancer HCT116 cells, indicating the inhibition of SIRT1 in these cells.     

Improved performance of column chromatography by arginine: dye-affinity chromatography

Arginine has been effectively used in various column chromatographies for improving recovery and resolution, and suppressing aggregation. Here, we have tested the effectiveness of arginine as an eluent in dye-affinity column chromatography using Blue-Sepharose, which binds enzymes requiring adenyl-containing cofactors (e.g., NAD). A common eluent, NaCl, showed a broad elution peak with low recovery of lactate dehydrogenase, at most approximately 60% using 2M salt. The recovery decreased as the NaCl concentration was either decreased or increased; i.e., the recovery was maximum at 2M. On the contrary, addition of arginine to the eluent resulted in more than 80% recovery above 0.5M and the recovery was nearly independent of the arginine concentration. The elution peak was much sharper with arginine, leading to elution of more concentrated protein solution. Successful elution of proteins bound to the ATP-agarose resins by arginine was also described.     

A Pore-Forming Toxin Requires a Specific Residue for Its Activity in Membranes with Particular Physicochemical Properties

The physicochemical landscape of the bilayer modulates membrane protein function. Actinoporins are a family of potent hemolytic proteins from sea anemones acting at the membrane level. This family of cytolysins preferentially binds to target membranes containing sphingomyelin, where they form lytic pores giving rise to cell death. Although the cytolytic activity of the actinoporin fragaceatoxin C (FraC) is sensitive to vesicles made of various lipid compositions, it is far from clear how this toxin adjusts its mechanism of action to a broad range of physiochemical landscapes. Herein, we show that the conserved residue Phe-16 of FraC is critical for pore formation in cholesterol-rich membranes such as those of red blood cells. The interaction of a panel of muteins of Phe-16 with model membranes composed of raft-like lipid domains is inactivated in cholesterol-rich membranes but not in cholesterol-depleted membranes. These results indicate that actinoporins recognize different membrane environments, resulting in a wider repertoire of susceptible target membranes (and preys) for sea anemones. In addition, this study has unveiled promising candidates for the development of protein-based biosensors highly sensitive to the concentration of cholesterol within the membrane.     

Improvement of antibody affinity by introduction of basic amino acid residues into the framework region

Antibodies are widely used not only as therapeutic agents but also as research tools and diagnostic agents, and extensive efforts have been made to generate antibodies that have higher affinity. It was recently reported that introduction of charged residues into the framework region of an antibody improved its affinity; however, the underlying molecular mechanism has not been elucidated. In this study, we used kinetic and thermodynamic analyses of the antibody–antigen interaction to investigate the molecular mechanism by which an antibody with introduced charged residues recognizes its antigen with higher affinity. The introduction of basic amino acid residues resulted in improvement of the affinity whereas the introduction of acidic residues weakened the interaction. For two mutant antigen-binding fragments (Fabs) with improved affinity (named K5- and R5-mutants), the balance between the association rate constant k_on and the dissociation rate constant k_off was distinct despite each mutant having the same number of charged residues. Moreover, thermodynamic analysis of the interactions in the transition state revealed a difference between the K5- and R5-mutants in terms of enthalpic energy change following formation of the encounter complex with the antigen. These results suggest that the affinity of the K5- and R5-mutants is improved by distinct mechanisms. Although the mutations destabilize the Fab and necessitate further studies, our strategy is expected to become a versatile and simple means to improve the affinity of antibodies to their antigens.     

Effects of subclass change on the structural stability of chimeric,humanized, and human antibodies under thermal stress

To address how changes in the subclass of antibody molecules affect their thermodynamic stability, we prepared three types of four monoclonal antibody molecules (chimeric, humanized, and human) and analyzed their structural stability under thermal stress by using size‐exclusion chromatography, differential scanning calorimetry (DSC), circular dichroism (CD), and differential scanning fluoroscopy (DSF) with SYPRO Orange as a dye probe. All four molecules showed the same trend in change of structural stability; the order of the total amount of aggregates was IgG1 < IgG2 < IgG4. We thus successfully cross‐validated the effects of subclass change on the structural stability of antibodies under thermal stress by using four methods. The T_h values obtained with DSF were well correlated with the onset temperatures obtained with DSC and CD, suggesting that structural perturbation of the CH2 region could be monitored by using DSF. Our results suggested that variable domains dominated changes in structural stability and that the physicochemical properties of the constant regions of IgG were not altered, regardless of the variable regions fused.     

Identification and determination of urinary acetylpolyamines in cancer patients by electrospray ionization and time-of-flight mass spectrometry

A method for the quantification of acetylpolyamines, N¹,N¹²-diacetylspermine (DiAcSpm), monoacetylspermidine (AcSpd), and N¹,N⁸-diacetylspermidine (DiAcSpd), identifying each compound simultaneously, was developed with the goal of evaluating these acetylpolyamines as potential biomarkers of cancer. The method consists of prepurification of acetylpolyamines in urine with commercially available cartridges and derivatization with heptafluorobutyric (HFB) anhydride. HFB derivatives of acetylpolyamines were determined simultaneously using ¹⁵N-labeled acetylpolyamines as internal standards by electrospray ionization and time-of-flight mass spectrometry (ESI-TOF MS). After the method was validated, the urinary acetylpolyamines of 38 cancer patients were quantified with this method. A comparison of the concentrations of DiAcSpm with those measured by a colloidal gold aggregation method demonstrated a correlation coefficient of 0.996, showing that the two methods were equally satisfactory. Analysis of the correlation between DiAcSpd or AcSpd and DiAcSpm, performed for the first time, indicated the usefulness of DiAcSpm as a urinary biomarker of cancer. During the course of this work, two simple methods for the preparation of α,ω-diacetylpolyamines were developed, and a possibility to separate and determine the concentrations of the two isomers, N¹-acetylspermidine and N⁸-acetylspermidine in AcSpd, was shown by tandem mass spectrometry (MS/MS).