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High-efficiency production of 5-hydroxyectoine using metabolically engineered Corynebacterium glutamicum
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High-efficiency production of 5-hydroxyectoine using metabolically engineered Corynebacterium glutamicum
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High-efficiency production of 5-hydroxyectoine using metabolically engineered Corynebacterium glutamicum
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Journal Article
High-efficiency production of 5-hydroxyectoine using metabolically engineered Corynebacterium glutamicum
2022
Overview
Background
Extremolytes enable microbes to withstand even the most extreme conditions in nature. Due to their unique protective properties, the small organic molecules, more and more, become high-value active ingredients for the cosmetics and the pharmaceutical industries. While ectoine, the industrial extremolyte flagship, has been successfully commercialized before, an economically viable route to its highly interesting derivative 5-hydroxyectoine (hydroxyectoine) is not existing.
Results
Here
,
we demonstrate high-level hydroxyectoine production, using metabolically engineered strains of
C. glutamicum
that express a codon-optimized, heterologous
ectD
gene, encoding for ectoine hydroxylase, to convert supplemented ectoine in the presence of sucrose as growth substrate into the desired derivative. Fourteen out of sixteen codon-optimized
ectD
variants from phylogenetically diverse bacterial and archaeal donors enabled hydroxyectoine production, showing the strategy to work almost regardless of the origin of the gene. The genes from
Pseudomonas stutzeri
(PST) and
Mycobacterium smegmatis
(MSM) worked best and enabled hydroxyectoine production up to 97% yield. Metabolic analyses revealed high enrichment of the ectoines inside the cells, which,
inter alia
, reduced the synthesis of other compatible solutes, including proline and trehalose. After further optimization,
C.
glutamicum Ptuf ectD
PST
achieved a titre of 74 g L
−1
hydroxyectoine at 70% selectivity within 12 h, using a simple batch process. In a two-step procedure, hydroxyectoine production from ectoine, previously synthesized fermentatively with
C. glutamicum ectABC
opt
, was successfully achieved without intermediate purification.
Conclusions
C. glutamicum
is a well-known and industrially proven host, allowing the synthesis of commercial products with granted GRAS status, a great benefit for a safe production of hydroxyectoine as active ingredient for cosmetic and pharmaceutical applications. Because ectoine is already available at commercial scale, its use as precursor appears straightforward. In the future, two-step processes might provide hydroxyectoine de novo from sugar.
Publisher
BioMed Central,BioMed Central Ltd,BMC
