AI Article Synopsis
- Cell factory development is essential for producing chemicals, biofuels, and pharmaceuticals efficiently, often requiring multiple Design-Build-Test-Learn cycles to create engineered strains suitable for industrial use.
- The bioindustry favors secreted products because they lower processing costs and metabolic stress on cell hosts, but this approach creates challenges in identifying desired variants due to the disconnect between phenotype and genotype.
- Droplet microfluidic screening enhances throughput by encapsulating single cells in droplets, allowing for efficient processing and sorting, and this chapter outlines a protocol for using this technology to improve protein secretion in yeast libraries.
Article Abstract
Cell factory development is critically important for efficient biological production of chemicals, biofuels, and pharmaceuticals. Many rounds of the Design-Build-Test-Learn cycles may be required before an engineered strain meeting specific metrics required for industrial application. The bioindustry prefer products in secreted form (secreted products or extracellular metabolites) as it can lower the cost of downstream processing, reduce metabolic burden to cell hosts, and allow necessary modification on the final products , such as biopharmaceuticals. Yet, products in secreted form result in the disconnection of phenotype from genotype, which may have limited throughput in the Test step for identification of desired variants from large libraries of mutant strains. In droplet microfluidic screening, single cells are encapsulated in individual droplet and enable high-throughput processing and sorting of single cells or clones. Encapsulation in droplets allows this technology to overcome the throughput limitations present in traditional methods for screening by extracellular phenotypes. In this chapter, we describe a protocol/guideline for high-throughput droplet microfluidics screening of yeast libraries for higher protein secretion . This protocol can be adapted to screening by a range of other extracellular products from yeast or other hosts.
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