Abstract
Polyhydroxyalkanoates (PHAs) are promising biopolymers for biomedical applications due to their excellent biocompatibility and biodegradability. However, the high production cost mainly resulting from the pure sugar substrate limits PHA commercialization. It makes various carbon-rich wastes potential substrates for PHA production. The integration and optimization of metabolic pathways can further enhance the conversion of carbon-rich wastes to PHAs. Genetic engineering strategies focusing on carbon flux and energy metabolism have improved the PHA production capacities of targeted strains by promoting substrate assimilation, enhancing PHA synthesis, and reducing branch metabolism. CRISPR/Cas9-based systems have also served as efficient genome editing tools to improve the efficiency of metabolic modification. Genetic modification requires fitness among strains, substrates, and products. Therefore, this review outlined various efficient genetic engineering approaches to promote PHA production and discussed their feasibility in valorizing representative carbon-rich wastes. To further illustrate the widespread applicability of metabolic modification to support microbial cell factories with core PHA production, this review also involved advanced fermentation approaches and co-production systems for PHA production by engineered strains.
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•Various genetic engineering strategies promote PHA production.•CRISPR/Cas9-based technics improve the performance of PHA production.•Various wastes serve as carbon sources for PHA production by engineered strains.•Advanced fermentation approaches support PHA production by engineered strains.•Genetic engineering technology improves the performance of co-production systems.