Abstract
Programming non-canonical organisms is more attractive due to the prospect of high-value chemical production. Among all, Shewanella oneidensis MR-1 possesses outstanding heme synthesis ability and is well-known for electron transfer, thus has high potential in microbial fuel cell and bioremediation. However, heme, as the final product of C4 and C5 pathways, is regulated by heme cluster for the high-value 5-aminolevulinic acid (ALA) for cancer photodynamic therapy, which has never been explored in MR-1. Herein, the heme metabolism in MR-1 was firstly optimized for ALA production. We applied CRISPR interference (CRISPRi) targeted on the genes to fine-tune carbon flux in TCA cycle and redirected the carbon out-flux from heme, leading to a significant change in the amino acid profiles, while downregulation of the essential hemB showed a 2-fold increasing ALA production via the C5 pathway. In contrast, the modular design including of glucokinase, GroELS chaperone, and ALA synthase from Rhodobacter capsulatus enhanced ALA production markedly in the C4 pathway. By integrating gene cluster under dual T7 promoters, we obtained a new strain M::TRG, which significantly improved ALA production by 145-fold. We rewired the metabolic flux of MR-1 through this modular design and successfully produced the high-value ALA compound at the first time.
Highlights
Shewanella species are famous for the dissimilatory metabolism of manganese and iron oxides (Ng et al 2014)
Genes in red were downregulated using the CRISPR interference (CRISPRi) system and to reduce the carbon flux bypassing, where the deactivated Cas9 protein (dCas9) mediated with ldhA for lactate, pflB for formate, and pta or ackA for acetate, respectively
We found that all 4 strains under the control of CRISPRi grew slowly, and biomass obtained after 12 h was lower than that of wild type (Fig. 2a)
Summary
Shewanella species are famous for the dissimilatory metabolism of manganese and iron oxides (Ng et al 2014). Shewanella is capable of electron transfer electron in Mtr pathway which has been widely applied in microbe fuel cells (MFC), remediation in wastewater, removal of organic compounds and azo-dyes and biofabrication of nanoparticles (Wu and Ng 2017; Fredrickson et al 2008; Hirose et al 2019; Huang et al 2019). Genetic MR-1 has mostly been applied to produce acetoin, butanol, bioelectricity and nanoparticles by utilizing. The development of metabolic engineering relies on synthetic biological tools, while the manipulation of. The partial downregulation of transcriptional factors by CRISPR interference (CRISPRi) is a compelling tool for cellular metabolic engineering (Qi et al 2013; Ting and Ng 2020). The drawbacks of essential metabolites or the bypassing of the accumulated pathways can be mitigated by engineered other relevant pathways
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