Abstract
The extraordinary fidelity, sensory and regulatory capacity of natural intracellular machinery is generally confined to their endogenous environment. Nevertheless, synthetic bio-molecular components have been engineered to interface with the cellular transcription, splicing and translation machinery in vivo by embedding functional features such as promoters, introns and ribosome binding sites, respectively, into their design. Tapping and directing the power of intracellular molecular processing towards synthetic bio-molecular inputs is potentially a powerful approach, albeit limited by our ability to streamline the interface of synthetic components with the intracellular machinery in vivo. Here we show how a library of synthetic DNA devices, each bearing an input DNA sequence and a logical selection module, can be designed to direct its own probing and processing by interfacing with the bacterial DNA mismatch repair (MMR) system in vivo and selecting for the most abundant variant, regardless of its function. The device provides proof of concept for programmable, function-independent DNA selection in vivo and provides a unique example of a logical-functional interface of an engineered synthetic component with a complex endogenous cellular system. Further research into the design, construction and operation of synthetic devices in vivo may lead to other functional devices that interface with other complex cellular processes for both research and applied purposes.
Highlights
The cellular machinery is orders of magnitude more complex than any synthetic biological device produced so far [1,2,3], the processing power of the vast majority of endogenous biomolecular machines has not been harnessed by synthetic devices
Synthetic biology often assimilates existing knowledge gained through basic research into new functional synthetic components and/or systems [12,13]
In this report we describe a utilization of the comprehensive understanding of bacterial mismatch repair molecular biology [14,15,16,17] for the design of a functional device
Summary
The cellular machinery is orders of magnitude more complex than any synthetic biological device produced so far [1,2,3], the processing power of the vast majority of endogenous biomolecular machines has not been harnessed by synthetic devices. This is partly due to the fact that even simple synthetic molecular devices have proven difficult to operate inside cells due to constraints placed by the highly evolved and optimized cellular environment. This engineered mechanism enables the identification and selection for any dominant DNA sequence within a large pool of mutated sequences
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