A Vaccinia -based system for directed evolution of GPCRs in mammalian cells

Low stability and poor expression levels are inherent in many G protein-coupled receptors, hindering structural and biophysical analyses. Directed evolution in bacterial or yeast display systems has been successfully used to overcome both limitations in some cases. Yet, some receptors cannot be tackled in microbial systems, due to their complex molecular composition or due to unfavorable ligand properties. Here, we report an approach to evolve G protein-coupled receptors in mammalian cells. To achieve clonality of individual mutants, and a rather uniform gene copy number, both prerequisites for strict genotype-phenotype linkage in mammalian cells, we developed a highly efficient viral transduction system based on Vaccinia virus. Using rational design of synthetic DNA libraries, we first evolved neurotensin receptor 1 for high stability and expression, reaching levels similar or higher to what has been achieved in bacterial systems. Second, using parathyroid hormone 1 receptor we demonstrate that also receptors with complex molecular architectures and large ligands can be readily evolved in mammalian cells. Furthermore, in our system, the physiological signaling environment in mammalian cells can be employed to evolve functional receptor properties. We obtained fully functional receptor variants exhibiting increased allosteric coupling between the ligand binding site and the G protein interface, resulting in higher signaling efficacy. Thus, our approach provides new means to readily improve the biophysical properties of receptors in a mammalian cellular environment. Moreover, it opens the possibility to modulate receptor signaling and to gain further insights into the intricate molecular interplay required for GPCR activation.