Summary
Living cells are endowed with encoded programs that allow them to execute vital tasks and respond to relevant stimuli. The use of analogous (synthetic) programs has an enormous potential, yet we are highly limited in our ability to program cellular actions over time. We rely on precisely-timed human intervention or on molecular oscillators that control repetitive processes, but we are still unable to program cells to autonomously execute custom actions at desired times.
I now intend to make a big leap toward this goal by producing control systems (molecular timers) and associated, ready-to-use applications, for the precise and self-sufficient control of cellular actions over time. Specifically, I will engineer timer gene circuits into E. coli that compute time and perform desired actions at specified moments. Timers will be highly programmable, re-usable, and scalable, and I will exploit their potential by using them for different applications, including bioproduction and biosensing.
In sum, I will develop the highly-needed, ground-breaking ability to measure and program time in cells. My results will unleash a myriad of new possibilities, both fundamental and applied.
I now intend to make a big leap toward this goal by producing control systems (molecular timers) and associated, ready-to-use applications, for the precise and self-sufficient control of cellular actions over time. Specifically, I will engineer timer gene circuits into E. coli that compute time and perform desired actions at specified moments. Timers will be highly programmable, re-usable, and scalable, and I will exploit their potential by using them for different applications, including bioproduction and biosensing.
In sum, I will develop the highly-needed, ground-breaking ability to measure and program time in cells. My results will unleash a myriad of new possibilities, both fundamental and applied.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101114955 |
| Start date: | 01-07-2024 |
| End date: | 30-06-2029 |
| Total budget - Public funding: | 2 327 816,00 Euro - 2 327 816,00 Euro |
Cordis data
Original description
Living cells are endowed with encoded programs that allow them to execute vital tasks and respond to relevant stimuli. The use of analogous (synthetic) programs has an enormous potential, yet we are highly limited in our ability to program cellular actions over time. We rely on precisely-timed human intervention or on molecular oscillators that control repetitive processes, but we are still unable to program cells to autonomously execute custom actions at desired times.I now intend to make a big leap toward this goal by producing control systems (molecular timers) and associated, ready-to-use applications, for the precise and self-sufficient control of cellular actions over time. Specifically, I will engineer timer gene circuits into E. coli that compute time and perform desired actions at specified moments. Timers will be highly programmable, re-usable, and scalable, and I will exploit their potential by using them for different applications, including bioproduction and biosensing.
In sum, I will develop the highly-needed, ground-breaking ability to measure and program time in cells. My results will unleash a myriad of new possibilities, both fundamental and applied.
Status
SIGNEDCall topic
ERC-2023-STGUpdate Date
12-03-2024
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