Metabolic engineering
Natural cells have a whole set of endogenous metabolic processes, pathways that use small molecules for suporrting the natural cell’s metabolism and growth. One of the biggest challenges in modern metabolis engineering is to integrate newly constructed pathways with the host metabolism. When trying to discover a new pathway, or improve efficiency of an existing enzyme pathway, we often run into the problem of not being able to tell whether the changes have the desired effect in the background noise of endogenous cell metabolism.
Synthetic minimal cells have no endogenous metabolism beyond what is engineered into those cells in the first place. Therefore, we can understand and control flux of small molecule substrates within the synthetic cell. This makes designing new pathways and optimizing existing ones much easier. Additionally, the short turnaround time of a synthetic cell experiment, without needing to wait for transformants to grow to test each new plasmid combination, make iterating metabolic engineering designs much faster.
Our research focuses on engineering methods for high throughput, combinatorial design of multi-gene pathways using synthetic cells as the chassis for testing and optimizing expression.
For large scale natural product synthesis, synthetic cells are mostly research and development tool, at this point it is still cheaper and easier to perform industrial scale production in a live bug. Synthetic cell screens can help identify candidate pathways, and optimize it before scaling up for industrial manufacturing.
Synthetic cell systems can be a good tool for small scale, pilot studies, or for rapid prototyping of on-demand production of small batches of biologicals or precious small molecule compounds.