Decoding Specificity of Cyanobacterial MysDs in Mycosporine-Like Amino Acid Biosynthesis through Heterologous Expression in Saccharomyces cerevisiae

Xiaoyou Zheng, Peifeng Xie, Andrew Chen Cai, Yuze Jiang, Sirui Huang, Xiaochong Ma, Honghao Su, Boxiang Wang
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Abstract

Mycosporine-like amino acids (MAAs) are potent natural UV-protectants, but their industrial production is hindered by efficiency and sustainability issues of large-scale extraction of their native hosts. Heterologous expression of MAA biosynthesis pathway genes in chassis organisms provides a promising alternative route, though the substrate promiscuity of the ATP-grasp ligase MysD complicates the biosynthesis of specific MAAs. In this study, we developed a Saccharomyces cerevisiae strain with enhanced capacity of producing mycosporine-glycine (MG), through genomic expression of biosynthesis pathway genes and knockout of competing pathway genes. This strain serves as an efficient MysD expression platform, which converts MG into shinorine and porphyra-334. Through structural modelling, site-directed mutagenesis and mutant characterization, we identified two residues on the omega-loop of MysD involved in determining product specificity. We further characterized the product specificity of 20 MysDs from diverse cyanobacterial lineages and confirmed the residue pattern-product specificity correlation. Our findings provide guidance for screening, selecting, and designing novel MysDs for industrial-scale MAA production through heterologous expression.
通过在酿酒酵母中异源表达解码蓝藻 MysDs 在类霉菌素氨基酸合成过程中的特异性
类霉菌素氨基酸(MAAs)是一种有效的天然紫外线防护剂,但其工业化生产却受到从其原生宿主中大规模提取的效率和可持续性问题的阻碍。在底盘生物中异源表达 MAA 生物合成途径基因提供了一条很有前景的替代途径,但 ATP-抓取连接酶 MysD 的底物杂合性使特定 MAA 的生物合成变得复杂。在这项研究中,我们通过生物合成途径基因的基因组表达和竞争途径基因的敲除,培育出了一株具有更强生产霉菌素-甘氨酸(MG)能力的酿酒酵母菌株。该菌株是一个高效的 MysD 表达平台,可将 MG 转化为鞘氨醇和卟啉-334。通过结构建模、定点突变和突变体表征,我们确定了 MysD ω-环上两个参与决定产物特异性的残基。我们进一步鉴定了来自不同蓝藻品系的 20 个 MysD 的产物特异性,并证实了残基模式与产物特异性之间的相关性。我们的发现为筛选、选择和设计新型 MysDs 提供了指导,以便通过异源表达实现工业规模的 MAA 生产。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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