Synthetic Biology Approaches to Study Maize Signaling Pathways.

Abstract

Synthetic biology approaches merge the tenets of engineering with established biological techniques to answer fundamental questions about living systems and to engineer biological forms and functions. Following the engineering principle of design-build-test-iterate, this review serves as a guide to applying synthetic principles and approaches in maize. We outline strategies for (1) choosing the optimal model organism to serve as a heterologous chassis for maize signaling pathways, (2) designing and building biological parts and devices to express pathway components, (3) choosing an analytical technique to measure pathway function, and (4) optimizing and troubleshooting the designed system. Auxin is a hormone that is essential for plant growth and development, regulating cellular proliferation and differentiation. Considering the importance of auxin for maize development in aerial and underground tissue, it was an obvious starting point for synthetic biology approaches. We use the maize nuclear auxin response recapitulated in yeast (AuxInYeast) system to showcase the power of heterologous expression approaches for testing fundamental attributes of the evolution, genetics, and biochemistry of signaling pathways that may be challenging to assay in planta. This approach involves co-expression of maize auxin signaling components in Saccharomyces cerevisiae coupled with fluorescence flow cytometry to quantify signaling activity. We and others have used this system to interrogate the dynamics of pathway signaling, interactions between paralogous components, and the adaptation of auxin signaling over large evolutionary distances. Thus, the AuxInYeast system is a fast, high-throughput, hypothesis-generating platform that can be readily adapted by the maize community to creatively answer questions about fundamental maize biology and to drive development of novel tools for breeding and plant engineering.