Engineering transcription-based digital logic devices

Shetty, Reshma P., Knight, Thomas F. Jr

20 October 2005

The goal of Synthetic Biology is to engineer systems from biological parts. One class of systems are those whose purpose is to process information. My work seeks to build transcription-based devices for use in combinational digital logic. Preliminary characterization experiments show that existing devices fall short of desired device behavior. I propose to develop a novel implementation of transcription-based logic by designing synthetic transcription factors from well-characterized DNA binding and dimerization domains. Initial modeling work serves to inform design of these devices. / Poster presented at the 2005 ICSB meeting, held at Harvard Medical School in Boston, MA.

Synthetic Biology

Engineered Biological Systems

Transcription-based logic

Engineering transcription-based digital logic devices

Shetty, Reshma P., Knight, Thomas F. Jr

20 October 2005

The goal of Synthetic Biology is to engineer systems from biological parts. One class of systems are those whose purpose is to process information. My work seeks to build transcription-based devices for use in combinational digital logic. Preliminary characterization experiments show that existing devices fall short of desired device behavior. I propose to develop a novel implementation of transcription-based logic by designing synthetic transcription factors from well-characterized DNA binding and dimerization domains. Initial modeling work serves to inform design of these devices. / Poster presented at the 2005 ICSB meeting, held at Harvard Medical School in Boston, MA.

Synthetic Biology

Engineered Biological Systems

Transcription-based logic

Engineering the Interface Between Cellular Chassis and Integrated Biological Systems

Canton, Bartholomew, Endy, Drew

21 October 2005

The engineering of biological systems with predictable behavior is a challenging problem. One reason for this difficulty is that engineered biological systems are embedded within complex and variable host cells. To help enable the future engineering of biological systems, we are studying and optimizing the interface between an engineered biological system and its host cell or ``chassis''. Other engineering disciplines use modularity to make interacting systems interchangeable and to insulate one system from another. Engineered biological systems are more likely to work as predicted if system function is decoupled from the state of the host cell. Also, specifying and standardizing the interfaces between a system and the chassis will allow systems to be engineered independent of chassis and allow systems to be interchanged between different chassis. To this end, we have assembled orthogonal transcription and translation systems employing dedicated machinery, independent from the equivalent host cell machinery. In parallel, we are developing test systems and metrics to measure the interactions between an engineered system and its chassis. Lastly, we are exploring methods to``port'' a simple engineered system from a prokaryotic to a eukaryotic organism so that the system can function in both organisms. / Poster presented at the 2005 ICSB meeting, held at Harvard Medical School in Boston, MA.

Synthetic Biology

Engineered Biological Systems

Biological Virtual Machines

Cellular Chassis