The sustainable production of chemicals from renewable,
nonedible
biomass has emerged as an essential alternative to address pressing
environmental issues arising from our heavy dependence on fossil resources.
Microbial cell factories are engineered microorganisms harboring biosynthetic
pathways streamlined to produce chemicals of interests from renewable
carbon sources. The biosynthetic pathways for the production of chemicals
can be defined into three categories with reference to the microbial
host selected for engineering: native-existing pathways, nonnative-existing
pathways, and nonnative-created pathways. Recent trends in leveraging
native-existing pathways, discovering nonnative-existing pathways,
and designing
de novo
pathways (as nonnative-created
pathways) are discussed in this Perspective. We highlight key approaches
and successful case studies that exemplify these concepts. Once these
pathways are designed and constructed in the microbial cell factory,
systems metabolic engineering strategies can be used to improve the
performance of the strain to meet industrial production standards.
In the second part of the Perspective, current trends in design tools
and strategies for systems metabolic engineering are discussed with
an eye toward the future. Finally, we survey current and future challenges
that need to be addressed to advance microbial cell factories for
the sustainable production of chemicals.
Lactic acid bacteria (LAB) are significant groups of probiotic organisms in fermented food and are generally considered safe. LAB regulate soil organic matter and the biochemical cycle, detoxify hazardous chemicals, and enhance plant health. They are found in decomposing plants, traditional fermented milk products, and normal human gastrointestinal and vaginal flora. Exploring LAB identified in unknown niches may lead to isolating unique species. However, their classification is quite complex, and they are adapted to high sugar concentrations and acidic environments. LAB strains are considered promising candidates for sustainable agriculture, and they promote soil health and fertility. Therefore, they have received much attention regarding sustainable agriculture. LAB metabolites promote plant growth and stimulate shoot and root growth. As fertilizers, LAB can promote biodegradation, accelerate the soil organic content, and produce organic acid and bacteriocin metabolites. However, LAB show an antagonistic effect against phytopathogens, inhibiting fungal and bacterial populations in the rhizosphere and phyllosphere. Several studies have proposed the LAB bioremediation efficiency and detoxification of heavy metals and mycotoxins. However, LAB genetic manipulation and metabolic engineered tools provide efficient cell factories tailor-made to produce beneficial industrial and agro-products. This review discusses lactic acid bacteria advantages and limitations in sustainable agricultural development.
Bio-based production of industrially important chemicals and materials from non-edible and renewable biomass has become increasingly important to resolve the urgent worldwide issues including climate change. Also, bio-based production, instead of chemical synthesis, of food ingredients and natural products has gained ever increasing interest for health benefits. Systems metabolic engineering allows more efficient development of microbial cell factories capable of sustainable, green, and human-friendly production of diverse chemicals and materials. Escherichia coli is unarguably the most widely employed host strain for the bio-based production of chemicals and materials. In the present paper, we review the tools and strategies employed for systems metabolic engineering of E. coli. Next, representative examples and strategies for the production of chemicals including biofuels, bulk and specialty chemicals, and natural products are discussed, followed by discussion on materials including polyhydroxyalkanoates (PHAs), proteins, and nanomaterials. Lastly, future perspectives and challenges remaining for systems metabolic engineering of E. coli are discussed.
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