%A Trosset,Jean-Yves %A Carbonell,Pablo %D 2013 %J Frontiers in Bioengineering and Biotechnology %C %F %G English %K Synthetic Biology,Synergy,polypharmacology,multidrug resistance,Metabolic Engineering,Metabolic Networks,synthetic lethality,coupling %Q %R 10.3389/fbioe.2013.00011 %W %L %M %P %7 %8 2013-October-16 %9 Review %+ Dr Pablo Carbonell,University of Evry-Val d'Essonne,Institute of Systems and Synthetic Biology,5 rue Henri Desbrueres,Evry,91300,France,pablo.carbonell@upv.es %+ Dr Pablo Carbonell,CNRS,Institute of Systems and Synthetic Biology,5 rue Henri Desbrueres,Evry,91300,France,pablo.carbonell@upv.es %# %! Synergistic Synthetic Biology: Units In Concert %* %< %T Synergistic Synthetic Biology: Units in Concert %U https://www.frontiersin.org/articles/10.3389/fbioe.2013.00011 %V 1 %0 JOURNAL ARTICLE %@ 2296-4185 %X Synthetic biology aims at translating the methods and strategies from engineering into biology in order to streamline the design and construction of biological devices through standardized parts. Modular synthetic biology devices are designed by means of an adequate elimination of cross-talk that makes circuits orthogonal and specific. To that end, synthetic constructs need to be adequately optimized through in silico modeling by choosing the right complement of genetic parts and by experimental tuning through directed evolution and craftsmanship. In this review, we consider an additional and complementary tool available to the synthetic biologist for innovative design and successful construction of desired circuit functionalities: biological synergies. Synergy is a prevalent emergent property in biological systems that arises from the concerted action of multiple factors producing an amplification or cancelation effect compared with individual actions alone. Synergies appear in domains as diverse as those involved in chemical and protein activity, polypharmacology, and metabolic pathway complementarity. In conventional synthetic biology designs, synergistic cross-talk between parts and modules is generally attenuated in order to verify their orthogonality. Synergistic interactions, however, can induce emergent behavior that might prove useful for synthetic biology applications, like in functional circuit design, multi-drug treatment, or in sensing and delivery devices. Synergistic design principles are therefore complementary to those coming from orthogonal design and may provide added value to synthetic biology applications. The appropriate modeling, characterization, and design of synergies between biological parts and units will allow the discovery of yet unforeseeable, novel synthetic biology applications.