| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 6451607 | Current Opinion in Biotechnology | 2017 | 8 Pages |
â¢Yeast is a major producer of biopharmaceutical proteins.â¢Rational metabolic engineering is an efficient approach for strain improvement.â¢Systematically understanding the cellular machinery is essential to fully exploit yeast's potential.â¢Mathematical model-guided comprehensive strain development is promising.â¢Introducing trackable perturbations helps to interpret the cell machinery and identify novel targets.
Production of recombinant proteins by yeast plays a vital role in the biopharmaceutical industry. It is therefore desirable to develop yeast platform strains for over-production of various biopharmaceutical proteins, but this requires fundamental knowledge of the cellular machinery, especially the protein secretory pathway. Integrated analyses of multi-omics datasets can provide comprehensive understanding of cellular function, and can enable systems biology-driven and mathematical model-guided strain engineering. Rational engineering and introduction of trackable genetic modifications using synthetic biology tools, coupled with high-throughput screening are, however, also efficient approaches to relieve bottlenecks hindering high-level protein production. Here we review advances in systems biology and metabolic engineering of yeast for improving recombinant protein production.
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