Investigation Into Efficiency of a Novel Glycol Chitosan–Bestatin Conjugate to Protect Thymopoietin Oligopeptides From Enzymatic Degradation

结合 氨肽酶 化学 寡肽 生物化学 生物物理学 氨基酸 生物 数学 数学分析 亮氨酸
作者
Yong Zhang,Feng Jiao,Lili Cui,Yuebin Zhang,Wenzhao Li,Chunlei Li,Nian-Qiu Shi,Yan Chen,Wei Kong
出处
期刊:Journal of Pharmaceutical Sciences [Elsevier BV]
卷期号:105 (2): 828-837 被引量:6
标识
DOI:10.1002/jps.24567
摘要

In this study, a novel glycol chitosan (GCS)-bestatin conjugate was synthesized and evaluated to demonstrate its efficacy in protecting thymopoietin oligopeptides from aminopeptidase-mediated degradation. Moreover, the mechanism and relative susceptibility of three thymopoietin oligopeptides, thymocartin (TP4), thymopentin (TP5), and thymotrinan (TP3), to enzymatic degradation were investigated and compared at the molecular level. Initial investigations indicated that formation of the GCS-bestatin conjugate, with a substitution degree of 7.0% (moles of bestatin per mole of glycol glucosamine unit), could significantly protect all 3 peptides from aminopeptidase-mediated degradation in a concentration-dependent manner. The space hindrance and loss of one pair of hydrogen bonds, resulting from the covalent conjugation of chitosan with bestatin, did not affect the specific interaction between bestatin and aminopeptidase. Moreover, TP4 displayed a higher degradation clearance compared with those of TP5 and TP3 under the same experimental conditions. The varying levels of susceptibility of these 3 peptides to aminopeptidase (TP4 > TP5 > TP3) were closely related to differences in their binding energies to enzyme, which mainly involved Van der Waals forces and electrostatic interactions, as supported by the results of molecular dynamics simulations. These results suggest that GCS-bestatin conjugate might be useful in the delivery of thymopoietin oligopeptides by mucosal routes, and that TP3 and TP5 are better alternatives to TP4 for delivery because of their robust resistance against enzymatic degradation.

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