Abstract
The human dopamine receptors D2S and D3 belong to the group of G protein-coupled receptors (GPCRs) and are important drug targets. Structural analyses and development of new receptor subtype specific drugs have been impeded by low expression yields or receptor instability. Fusing the T4 lysozyme into the intracellular loop 3 improves crystallization but complicates conformational studies. To circumvent these problems, we expressed the human D2S and D3 receptors in Escherichia coli using different N- and C-terminal fusion proteins and thermostabilizing mutations. We optimized expression times and used radioligand binding assays with whole cells and membrane homogenates to evaluate KD-values and the number of receptors in the cell membrane. We show that the presence but not the type of a C-terminal fusion protein is important. Bacteria expressing receptors capable of ligand binding can be selected using FACS analysis and a fluorescently labeled ligand. Improved receptor variants can thus be generated using error-prone PCR. Subsequent analysis of clones showed the distribution of mutations over the whole gene. Repeated cycles of PCR and FACS can be applied for selecting highly expressing receptor variants with high affinity ligand binding, which in the future can be used for analytical studies.
Highlights
For a better molecular understanding and characterization of the two human dopamine receptors D2S and D3, heterologous expression systems can help to select for stabilized variants that can be used to investigate the proteins in their active forms
We provide constructs for D2S and D3 which allow for successful expression of the functional receptors in E. coli
A directed evolution approach was established as a proof of principle for the selection of improved receptor variants
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. G protein-coupled receptors (GPCRs) are intensely studied drug targets since they regulate many physiological processes [1]. They are integral membrane proteins, harboring seven transmembrane helices that are connected by alternating intra- and extracellular loops with an extracellular Nand an intracellular C-terminus. GPCRs are highly flexible and can assume many different conformations [3]. They mediate cellular responses to hormones and neurotransmitters
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