Whole synthetic pathway engineering of recombinant protein production.

The output from protein biomanufacturing systems is a function of total host cell biomass synthetic capacity and recombinant protein production per unit cell biomass. In this study, we describe how these two properties can be simultaneously optimized via design of a product-specific combination of synthetic DNA parts to maximize flux through the protein synthetic pathway and the use of a host cell chassis with an increased capability to synthesize both cell and product biomass. Using secreted alkaline phosphatase (SEAP) production in Chinese hamster ovary cells as our example, we demonstrate how an optimal composition of input components can be assembled from a minimal toolbox containing rationally designed promoters, untranslated regions, signal peptides, product coding sequences, cell chassis, and genetic effectors. Product titer was increased 10-fold, compared with a standard reference system by (a) identifying genetic components that acted in concert to maximize the rates of SEAP transcription, translation, and translocation, (b) selection of a cell chassis with increased biomass synthetic capacity, and (c) engineering the host cell factory's capacity for protein folding and secretion. This whole synthetic pathway engineering process to design optimal expression cassette-chassis combinations should be applicable to diverse recombinant protein and host cell-type contexts.

Novel High-Throughput DNA Part Characterization Technique for Synthetic Biology.

This study presents a novel DNA part characterization technique that increases throughput by combinatorial DNA part assembly, solid plate-based quantitative fluorescence assay for phenotyping, and barcode tagging-based long-read sequencing for genotyping. We confirmed that the fluorescence intensities of colonies on plates were comparable to fluorescence at the single-cell level from a high-end, flow-cytometry device and developed a high-throughput image analysis pipeline. The barcode tagging-based long-read sequencing technique enabled rapid identification of all DNA parts and their combinations with a single sequencing experiment. Using our techniques, forty-four DNA parts (21 promoters and 23 RBSs) were successfully characterized in 72 h without any automated equipment. We anticipate that this high-throughput and easy-to-use part characterization technique will contribute to increasing part diversity and be useful for building genetic circuits and metabolic pathways in synthetic biology.

Assembling DNA Plasmids with the Multi-Kingdom (MK) Cloning System.

The Golden Gate cloning technique is used to assemble DNA parts into higher-order assemblies. Individual parts containing compatible overhangs generated by type IIS restriction enzymes are joined together using DNA ligase. The technique enables users to assemble custom transcription units (TUs) for a wide array of experimental assays. Several Golden Gate cloning systems have been developed; however, they are typically used with a narrow range of organisms. Here we describe the Multi-Kingdom (MK) cloning system that allows users to generate DNA plasmids for use in a broad range of organisms.