Abstract
Ergothioneine (ERG), a unique thiol compound, is suggested to function as an antioxidant and cytoprotectant. Despite several recent attempts to produce ERG using various organisms, its yield was still very low and the costs remained high. Since the level of ERG produced depends strictly on the availability of three distinct precursor amino acids (l-cysteine (Cys), l-histidine, and l-methionine (Met)), metabolic engineering for enhancement of the flux toward ERG biosynthesis is required. Herein, we took advantage of a high-Cys production system using Escherichia coli cells, in which Cys biosynthesis and excretion were activated, and applied it to the fermentative production of ERG from glucose. The Cys overproduction in E. coli cells carrying the egtBCDE genes from Mycobacterium smegmatis was effective for ERG production. Furthermore, coexpression of the egtA gene, which encodes γ-glutamylcysteine synthetase that synthesizes the γ-glutamylcysteine used as a sulfur source of ERG biosynthesis, enhanced ERG production even though E. coli intrinsically has γ-glutamylcysteine synthetase. Additionally, disruption of the metJ gene that encodes the transcriptional repressor involved in Met metabolism was effective in further increasing the production of ERG. Finally, we succeeded in the high-level production of 1.31 g/L ERG in a fed-batch culture process using a jar fermenter.
Highlights
To all living organisms, l-cysteine (Cys) is an essential amino acid that contributes to a number of biological processes, including oxidative stress tolerance and protein folding, assembly, and stability through disulfide-bond formation[1]
In order to further improve the producing system for ERG, we here constructed the plasmid pQE1a-egtBCDE, capable of facilitating the isopropyl β-D-1-thiogalactopyranoside (IPTG)-inducible polycistronic expression of the egtBCDE derived from M. smegmatis in E. coli
WT pQE1a pACYC184 did not produce ERG at all, whereas WT pQE1a-egtBCDE pACYC184 successfully produced 10 mg/L of ERG after 120 h of cultivation, indicating the successful genetic design and construction for ERG production based on the heterologous expression of egtBCDE from M. smegmatis
Summary
L-cysteine (Cys) is an essential amino acid that contributes to a number of biological processes, including oxidative stress tolerance and protein folding, assembly, and stability through disulfide-bond formation[1]. Animals cannot assimilate inorganic sulfur sources, and instead obtain sulfur in the organic form as Cys and l-methionine (Met) through food intake. This implies that animals are completely dependent on bacterial and plant sulfur metabolites for their sulfur intake. Organic sulfur-containing amino acids, including Cys, are industrially important. Studies carried out with cell-free extracts of Neurospora crassa demonstrated the requirement of three amino acids (viz., Cys, l-histidine (His), and l-methionine (Met)) for ERG biosynthesis[11,12]. Several further experiments to improve the biosynthetic flux of ERG succeeded in achieving its gram-scale production
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