枯草芽孢杆菌
酶
化学
杆菌科
生物化学
芽孢杆菌目
古细菌
立体选择性
细胞外
立体化学
产量(工程)
细菌
嗜盐菌
生物合成
芽孢杆菌(形态)
炭疽杆菌
共价键
氨基酸
循环芽孢杆菌
丙酸盐类
水解酶
糖苷水解酶
放线菌
链霉菌科
极端微生物
活动站点
立体异构
底物特异性
代谢途径
作者
Onuma Chumsakul,Shu Ishikawa
摘要
Poly-γ-glutamic acid (γ-PGA) occurs in three stereochemical forms-L-, DL-, and D-polymers-and the D/L ratio profoundly affects crystallinity, degradability, and materials performance. Bacillus subtilis and related secretors typically produce DL-PGA, whereas halophilic archaea yield stereoregular L-PGA and Bacillus anthracis forms a covalently anchored D-PGA capsule. Recent work has clarified how the PgsBCA/CapBCA modules access these outputs: PgsB and PgsC build and export a purely L-Glu polymer, while the MslH-like enzyme PgsA/CapA introduces D-Glu, establishing the D/L ratio. In the extracellular space, the D/L composition of γ-PGA is shaped by stereoselective hydrolases-PgdS, NlpC/P60 DL-endopeptidases, phage-derived Pgh enzymes, and GGT-family proteins. We integrate these biosynthetic and degradative pathways into a stereochemical framework and outline how tuning epimerase activity and controlling these hydrolases may enable high-molecular-weight, L-rich γ-PGA in Bacillus for coatings, absorbents, biomedical applications, and personal-care formulations where L-PGA surpasses DL-PGA in moisture retention and stability.
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