Mihoko Ui

A Structured Monodisperse PEG for the Effective Suppression of Protein Aggregation

Part of the solution: A PEG with a discrete triangular structure exhibits hydrophilicity/hydrophobicity switching upon increasing temperatures, and suppresses the thermal aggregation of lysozyme to retain nearly 80 % of the enzymatic activity. CD and NMR spectroscopic studies revealed that, with the structured PEG, the higher-order structures of lysozyme persist at high temperature, and the native conformation is recovered after cooling.

Mutations for decreasing the immunogenicity and maintaining the function of core streptavidin

The defining property of core streptavidin (cSA) is not only its high binding affinity for biotin but also its pronounced thermal and chemical stability. Although potential applications of these properties including therapeutic methods have prompted much biological research, the high immunogenicity of this bacterial protein is a key obstacle to its clinical use. To this end, we have successfully constructed hypoimmunogenic cSA muteins in a previous report. However, the effects of these mutations on the physicochemical properties of muteins were still unclear. These mutations retained the similar electrostatic charges to those of wild‐type (WT) cSA, and functional moieties with similar hydrogen bond pattern. Herein, we performed isothermal titration calorimetry, differential scanning calorimetry, and sodium dodecyl sulfate–polyacrylamide gel electrophoresis to gain insight into the physicochemical properties and functions of these modified versions of cSA. The results indicated that the hypoimmunogenic muteins retained the biotin‐binding function and the tetramer structure of WT cSA. In addition, we discuss the potential mechanisms underlying the success of these mutations in achieving both immune evasion and retention of function; these mechanisms might be incorporated into a new strategy for constructing hypoimmunogenic proteins.

How Protein Recognizes Ladder-like Polycyclic Ethers INTERACTIONS BETWEEN CIGUATOXIN (CTX3C) FRAGMENTS AND ITS SPECIFIC ANTIBODY 10C9

Ciguatoxins are a family of marine toxins composed of transfused polycyclic ethers. It has not yet been clarified at the atomic level on the pathogenic mechanism of these toxins or the interaction between a polycyclic ether compounds and a protein. Using the crystal structures of anti-ciguatoxin antibody 10C9 Fab in ligand-free form and in complexes with ABCD-ring (CTX3C-ABCD) and ABCDE-ring (CTX3C-ABCDE) fragments of the antigen CTX3C at resolutions of 2.6, 2.4, and 2.3Å, respectively, we elucidated the mechanism of the interaction between the polycyclic ethers and the antibody. 10C9 Fab has an extraordinarily large and deep binding pocket at the center of the variable region, where CTX3C-ABCD or CTX3C-ABCDE binds longitudinally in the pocket via hydrogen bonds and van der Waals interactions. Upon antigen-antibody complexation, 10C9 Fab adjusts to the antigen fragments by means of rotational motion in the variable region. In addition, the antigen fragment lacking the E-ring induces a large motion in the constant region. Consequently, the thermostability of 10C9 Fab is enhanced by 10 °C upon complexation with CTX3C-ABCDE but not with CTX3C-ABCD. The crystal structures presented in this study also show that 10C9 Fab recoginition of CTX3C antigens requires molecular rearrangements over the entire antibody structure. These results further expand the fundamental understanding of the mechanism by which ladder-like polycyclic ethers are recognized and may be useful for the design of novel therapeutic agents by antibodies, marine toxins, or new diagnostic reagents for the detection and targeting of members of the polycyclic ether family.

An Approach to Rational Ligand-Design Based on a Thermodynamic Analysis

Thermodynamic analysis is an effective tool in screening of lead-compounds for development of potential drug candidates. In most cases, a ligand achieve high affinity and specificity to a target protein by means of both favorable enthalpy and entropy terms, which can be reflected in binding profiles of Isothermal Titration Calorimetry (ITC). A favorable enthalpy change suggests the contribution of noncovalent contacts such as hydrogen bonding and van der Waals interaction between a ligand and its target protein. In general, optimization of binding enthalpy is more difficult than that of entropies in ligand-design; therefore, it is desirable to choose firstly a lead-compound based on its binding enthalpic gain. In this paper, we demonstrate the utility of thermodynamic approach to ligand screening using anti-ciguatoxin antibody 10C9 as a model of a target protein which possesses a large hydrophobic pocket. As a result of this screening, we have identified three compounds that could bind to the antigen-binding pocket of 10C9 with a few kcal/mol of favorable binding enthalpy. Comparison of their structure with the proper antigen ciguatoxin CTX3C revealed that 10C9 rigorously identifies their cyclic structure and a characteristic hydroxyl group. ITC measurement might be useful and powerful for a rational ligand screening and the optimization of the ligand; the enthalpic gain is an effective index for ligand-design studies.