生物合成
调节器
生物
次生代谢物
基因簇
生物化学
辅因子
巢状曲霉
基因表达调控
血红素
下调和上调
代谢物
细胞生物学
还原酶
基因
代谢工程
加氧酶
磷酸戊糖途径
转录组
次生代谢
白霉素类
化学
生物发生
变构调节
生产过剩
细胞色素P450
酿酒酵母
真菌蛋白
转录因子
计算生物学
作者
Xiaomin Yang,Jie Gao,Dandan Shen,Y Zhang,H Chen,Min Zhou,Junping Zhou,Aiping Pang,Lianggang Huang,Zhi‐Qiang Liu,Yuguo Zheng
摘要
ABSTRACT Echinocandin B (ECB), a fungal non‐ribosomal lipopeptide, serves as the exclusive natural precursor of the front‐line antifungal anidulafungin. Despite its clinical importance, ECB production remains suboptimal due to incomplete understanding of its biosynthesis mechanism. The global regulator LaeA has been implicated in secondary metabolite production, yet its specific role in ECB biosynthesis remains unexplored. To address this, we successfully constructed laeA deletion and overexpression strains, and demonstrated that LaeA functionally couples morphological development with ECB productivity. Transcriptomic analysis revealed LaeA directly activated the sterigmatocystin cluster via pathway‐specific regulator AflR, but indirectly influenced ECB through iron‐heme cofactor synchronization rather than direct gene cluster activation. LaeA overexpression upregulated siderophore iron transporters and heme biosynthetic genes, with supplementation of Fe 2 + or 5‐ALA further boosting titers to 2487 ± 123 and 2697 ± 16 mg/L, respectively. To overcome P450s catalytic constraints, we screened out a novel cytochrome P450 reductase CPR2 as the optimal redox partner. Co‐expression of CPR2 with bacterial hemoglobin VHb achieved synergistic enhancement, improving the ECB titer to 3170 ± 41 mg/L. This study provided a practical strategy for improving ECB production and offering insights into the versatile regulatory modes of global secondary metabolite regulators.
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