Engineering Biomolecular Systems - NCCR MSE

Engineering Biomolecular Systems

Operon frameworks for complex synthetic systems need to be explored in a multiplexed and multilevel approach to develop design rules.
A: Several operon design elements can influence final protein expression levels.
B: E. coli expressing various fluorescent reporter protein combinations.
C: A selected set of fluorescent proteins can be quantified in an orthogonal fashion via flowcytometry.
Operon frameworks for complex synthetic systems need to be explored in a multiplexed and multilevel approach to develop design rules. A: Several operon design elements can influence final protein expression levels. B: E. coli expressing various fluorescent reporter protein combinations. C: A selected set of fluorescent proteins can be quantified in an orthogonal fashion via flowcytometry.

Molecular systems derive their functional breadth from the interplay of multiple elements. The successful cooperation of these elements is often limited to narrow windows of operation, which are often difficult to identify.

We are optimizing complex in vitro systems so they can successfully operate in these windows. For this, we develop cell free systems that allow the synthesis of multiple catalysts and other protein-based elements, and compartmentalize the synthesis in nanoliter or picoliter-sized droplets. This helps us to investigate thousands of system compositions per minute. We use this to develop design rules for multi-membered systems and prepare such droplets for analysis in a classical way (i.e., by fluorescence) and by label-free methods, such as mass-spectrometry. This way we can optimize system function for a variety of objectives, ranging from enzyme evolution to the engineering of smart systems for metabolic diseases.

Publications

M. JeschekD. GerngrossS. Panke “Rationally reduced libraries for combinatorial pathway optimization minimizing experimental effort“ Nat. Commun. 2016, 7:doi:10.1038/ncomms11163. [DOI]