Thalidomide (TD) is a historically famous chiral drug. After prescription as a safe hypnotic, TD was suspected of contributing to teratogenicity, resulting in prohibition of the use of TD. TD and its derivatives, however, have attracted a renewed attention since their therapeutic effects for Hansen's disease and multiple myeloma were demonstrated. Meanwhile TD has been known to suffer from spontaneous hydrolysis with complicated pathways, leading to the production of various metabolites of TD. Therefore, we are now facing the difficulty in specifying the compounds which cause desired and/or adverse effects in the drug mechanism of TD. In a previous study, pure hydrolytic products of TD were synthesized and assayed for production-inhibitory activity of TNF-α, a kind of cytokine that induces inflammation. This study has showed that some products, especially α-(2-carboxybenzamido)glutarimide (CBG), exhibit high potency for the inhibition of TNF-α production compared to original TD. The hydrolytic products of TD thus are found to greatly attribute to the pharmacological effect of TD. For comprehending effects of the hydrolytic products, it is much significant to perform physicochemical analysis of them because their properties are deeply related to molecular stability and interaction with receptor proteins. In this study, we thus aim to investigate the physicochemical properties of CBG employing X-ray crystal structural analysis and thermal analyses. Single crystals of racemic and enantiomeric CBG were grown by solvent evaporation methods. On the crystallization, we chose alcoholic solvents such as methanol and ethanol. Surprisingly, crystals grown from the CBG solutions have indicated the same crystal structure of TD with high reproducibility. This unique result is likely to represent dehydration of CBG in non-aqueous solvents, which has not been reported so far. The detailed mechanism is under investigation.

Brazzein, a 6.5-kDa protein consisting of 54 amino acids and four disulfide bonds, is the smallest sweet-tasting protein yet isolated from the wild African plant Pentadiplandra brazzeana. Brazzein has various desirable properties for use as a low-calorie sweetener in the diets of individuals suffering from diabetes, obesity, and metabolic syndrome. For example, brazzein has a high water solubility and a high thermostability. In addition, brazzein is 2000-times sweeter than sucrose on a weight basis. Both the solution and crystal structures of brazzein have been reported. In the crystal structure [1], brazzein has a defensin-like fold containing two α-helices and a three-stranded antiparallel β-sheet. Defensins are small cysteine-rich cationic proteins found in both animals and plants, which function by binding to the microbial cell membrane, and, once embedded, forming pore-like membrane defects that allow efflux of essential ions and nutrients. In fact, Yount and Yeaman reported that brazzein has antimicrobial activity against Gram positive (Bacillus subtilis and Staphylococcus aureus) and negative (Escherichia coli) bacteria and a fungus (Candida albicans) at pH 7.5 rather than pH 5.5 [2]. A search for proteins with a similar backbone fold to brazzein using the DALI server shows that structurally similar proteins to brazzein include plant defensins, scorpion neurotoxins (K+ channel blockers), arthropod defensins, mollusc defensins, mold defensins, and a plant trypsin inhibitor. These proteins commonly have a γ-core sequence. Here we compare their sequences, structures and functions, which has led to a conclusion that the C-terminal half of brazzein is important for its antimicrobial activity, brazzein will not have a neurotoxin activity, and it will not act as a trypsin inhibitor.

Crystals are classified according to their symmetry operations into 230 space groups. A two-fold screw axis, 2₁, a symmetry operation, is frequently found in the crystal, especially non-centrosymmetric organic crystals. The two-fold screw axis shows a chiral character when molecules in the crystal tilt against the screw axis as shown in Figure. The crystals belonging to a chiral space group with two-fold screw axis such as a P2₁ or P2₁2₁2₁ exhibit two different types with opposite chirality. However, although the two crystals are not identical in a molecular arrangement, we cannot distinguish them with the present notation of space group. Recently, the idea of determining the handedness of two-fold screw axis have been successfully proposed using hierarchical interpretation of the crystals.(I. Hisaki, T. Sasaki et al., 2012) Nevertheless, the issue on a notation to distinguish chiral crystals with two-fold screw axis still remains unsettled as far as we know. Therefore, we attempt to propose a novel notation for the crystals belonging to chiral space groups with two-fold screw axis. We focus on the relationship between the absolute structure and optical activity of the crystals. We have selected alanine crystals, which belong to P2₁2₁2₁, as model crystals to discuss the notation. We have determined the absolute structure of the alanine crystals by X-ray diffraction and have measured their optical activity with Generalized High Accuracy Universal Polarimeter (G-HAUP).(M. Tanaka, N. Nakamura et al., 2012) G-HAUP is an apparatus that can measure simultaneously the linear birefringence, linear dichroism, circular birefringence, i.e., optical activity, and circular dichroism in any solid material. These experimental results have successfully correlated the absolute structure to the optical activity of the alanine crystals.

A crystal, which belongs to a lower crystal system than cubic one, exhibits optical anisotropies. The optical anisotropies originate from the difference in refraction and absorption between orthogonally linearly polarized lights. When molecules forming a crystal are enantiomers with the same chirality or form helical structures with the same handedness, the crystal shows chiroptical properties, which originate from the difference in refraction and absorption between right and left circularly polarized lights. The four optical phenomena are called linear birefringence (LB), linear dichroism (LD), circular birefringence (CB) and circular dichroism (CD), respectively. It had been difficult to measure CB and CD in chiral crystals with optical anisotropies because the signals of the anisotropies are three or four orders of magnitude larger than those of chiroptical properties. The Generalized High Accuracy Universal Polarimeter (G-HAUP) [1] enables us to simultaneously measure LB, LD, CB and CD of any anisotropic crystal. Nickel sulfate (NS) is achiral in the solution state. However, in the crystalline state, it forms hexahydrate and exhibits chirality since molecules are put in helical arrangements. The NS crystal belongs to an enantiomorphous space group, P4₁2₁2 or P4₃2₁2. Many researchers have reported the optical properties of NS crystal because large and good-quality crystals are readily grown. However, we consider the LB, LD, CB and CD in NS crystal should be simultaneously and completely investigated. The purpose of this study is to obtain LB, LD, CB and CD along the a axis with G-HAUP and compare the CB and CD with the results along the c axis. We measured optical rotatory power (ORP) along the c axis with G-HAUP, which agrees with the previous results [2,3]. We then prepared for some samples with chirality and anisotropy. We measured LB, LD, CB and CD spectra, respectively and will demonstrate the relation between their optical properties and structures.