Department of Applied Chemistry and Bioengineering, Graduate School of Engineering, Osaka City University, Sugimoto 3-3-138, Osaka 558-8585, Japan.
Bioorg Med Chem. 2011 Jun 15;19(12):3855-63. doi: 10.1016/j.bmc.2011.04.038. Epub 2011 Apr 22.
1'-Acetoxychavicol acetate (ACA), isolated from the rhizomes and the seeds of the Zingiberaceae plant, has a variety of biological activities such as antitumor, antiallergic and repellent effects. However, ACA seems to have some disadvantages which may limit for future possible clinical applications, for example, its poor water solubility. Furthermore, ACA is not stable in aqueous solutions and undergoes hydrolysis and/or isomerization. To improve the solubility and stability of ACA in water, we prepared the inclusion complexes with various β-cyclodextrins (β-CDs).In aqueous solution, the association constants of ACA with various CDs were estimated at 662±95 (β-CD), 336±70 (methyl-β-CD, Meβ-CD), and 322±44M(-1) (hydroxypropyl-β-CD, HPβ-CD), respectively, by a spectrofluorometric displacement method based on competition between a guest and a fluorescent probe for CDs. It was revealed that almost all ACAs existed as a free molecule in the CD-containing aqueous solution. However, in the case of preparing the inclusion complexes of CDs with ACA by a solid phase 'high-speed vibration milling' technique, the average inclusion rates of the obtained water-soluble complexes were calculated as 88±13% (β-CD), 70±1% (Meβ-CD), and 63±2% (HPβ-CD), respectively, by (1)H NMR analysis. To characterize the structures of the CD·ACA complexes, 2,3,6-trimethyl-β-CD (TMeβ-CD)·ACA complex was prepared as a model compound (inclusion rate: 40%). As a result of 2D ROESY experiments, it was considered that the aromatic ring of ACA is located in the narrow side of the hydrophobic cavity of the TMeβ-CD and both 1'- and 4-acetoxy groups of ACA positioned in the vicinity of the secondary and primary methoxy groups of TMeβ-CD, respectively. Furthermore, we examined the apoptogenic activity of CD·ACA complexes to evaluate whether or not the bioactivities of ACA were affected by their inclusion. Although the cytotoxicity of all CD·ACA complexes in human epithelial carcinoma HeLa cells and murine adenocarcinoma colon26 cells were diminished as compared with the ACA alone, only HPβ-CD·ACA maintained high levels of activity. In addition, HPβ-CD·ACA, and Meβ-CD·ACA showed suppressive effect for the transcription factor NF-κB activation on LPS-activated murine macrophage RAW264.7 cells and the former was more active complex. Furthermore, HPβ-CD·ACA inhibited the in vivo tumor growth of tumor-bearing mice, although the activity was slightly weak compared with that of free ACA. These results indicate that HPβ-CD is the best host molecule for ACA to form a water-soluble complex with the similar biological activity of free ACA.
1'-乙酰氧基胡椒酚乙酸酯 (ACA) 从姜科植物的根茎和种子中分离出来,具有多种生物活性,如抗肿瘤、抗过敏和驱避作用。然而,ACA 似乎存在一些缺点,可能限制其未来在临床应用中的可能性,例如其水溶性差。此外,ACA 在水溶液中不稳定,会发生水解和/或异构化。为了提高 ACA 在水中的溶解度和稳定性,我们用各种β-环糊精 (β-CD) 制备了包合物。在水溶液中,通过基于荧光探针与客体竞争的分光荧光位移法,分别估算了 ACA 与各种 CD 的缔合常数为 662±95 (β-CD)、336±70 (甲基-β-CD,Meβ-CD) 和 322±44M(-1) (羟丙基-β-CD,HPβ-CD)。结果表明,在含 CD 的水溶液中,几乎所有的 ACA 都以游离分子的形式存在。然而,在通过固相“高速振动研磨”技术制备 CD 与 ACA 的包合物时,通过 (1)H NMR 分析,计算出所得水溶性包合物的平均包合率分别为 88±13% (β-CD)、70±1% (Meβ-CD) 和 63±2% (HPβ-CD)。为了表征 CD·ACA 配合物的结构,制备了 2,3,6-三甲基-β-CD (TMeβ-CD)·ACA 配合物作为模型化合物 (包合率:40%)。通过二维 ROESY 实验,认为 ACA 的芳环位于 TMeβ-CD 的疏水性空腔的窄边,ACA 的 1'-和 4-乙酰氧基分别位于 TMeβ-CD 的仲氧基和伯氧基附近。此外,我们研究了 CD·ACA 配合物的促凋亡活性,以评估 ACA 的生物活性是否受到其包合的影响。尽管所有 CD·ACA 配合物在人上皮癌细胞 HeLa 和鼠腺癌结肠 26 细胞中的细胞毒性均低于单独的 ACA,但只有 HPβ-CD·ACA 保持高活性。此外,HPβ-CD·ACA 和 Meβ-CD·ACA 对 LPS 激活的鼠巨噬细胞 RAW264.7 细胞中的转录因子 NF-κB 激活具有抑制作用,前者是更活跃的复合物。此外,HPβ-CD·ACA 抑制荷瘤小鼠的体内肿瘤生长,尽管其活性略低于游离 ACA。这些结果表明,HPβ-CD 是 ACA 形成具有游离 ACA 相似生物活性的水溶性配合物的最佳宿主分子。
