Rebecca P. Chen scite author profile

Inspired by the remarkable ability of natural protein switches to sense and respond to a wide range of environmental queues, here we report a strategy to engineer synthetic protein switches by using DNA strand displacement to dynamically organize proteins with highly diverse and complex logic gate architectures. We show that DNA strand displacement can be used to dynamically control the spatial proximity and the corresponding fluorescence resonance energy transfer between two fluorescent proteins. Performing Boolean logic operations enabled the explicit control of protein proximity using multi-input, reversible and amplification architectures. We further demonstrate the power of this technology beyond sensing by achieving dynamic control of an enzyme cascade. Finally, we establish the utility of the approach as a synthetic computing platform that drives the dynamic reconstitution of a split enzyme for targeted prodrug activation based on the sensing of cancer-specific miRNAs.

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Synthetic scaffolds for pathway enhancement

Siu

Chen

Sun

et al. 2015

Current Opinion in Biotechnology

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Controlling local concentrations of reactants, intermediates, and enzymes in synthetic pathways is critical for achieving satisfactory productivity of any desired products. An emerging approach to exert control over local concentrations is the use of synthetic biomolecular scaffolds to co-localize key molecules of synthetic pathways. These scaffolds bring the key molecules into close proximity by recruiting pathway enzymes via ligand binding and/or physically sequestrating enzymes and metabolites into isolated compartments. Novel scaffolds made of proteins, nucleic acids, and micro-compartments with increasingly complex architecture have recently been explored and applied to a variety of pathways, with varying degrees of success. Despite these strides, precise assembly of synthetic scaffolds remains a difficult task, particularly in vivo, where interactions both intended and unexpected can lead to unpredictable results. Additionally, because heterologous enzymes often have lowered activities in their new hosts, an ideal scaffold should provide a flexible platform that can adapt to kinetic imbalances in different contexts. In this review, we discuss some of the notable advances in the creation of these synthetic scaffolds and highlight the current challenges in their application.

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Synthetic biology approaches for targeted protein degradation

Chen

Gaynor

Chen

2019

Biotechnology Advances

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Controlling metabolic flux by toehold-mediated strand displacement

Chen

Hunt

Mitkas

et al. 2020

Current Opinion in Biotechnology

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Bispecific antibodies for immune cell retargeting against cancer

Chen

Shinoda

Rampuria

et al. 2022

Expert Opinion on Biological Therapy

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Rebecca P. Chen

Dynamic protein assembly by programmable DNA strand displacement

Synthetic scaffolds for pathway enhancement

Synthetic biology approaches for targeted protein degradation

Controlling metabolic flux by toehold-mediated strand displacement

Bispecific antibodies for immune cell retargeting against cancer

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