Ligand-selective small molecule modulators of the constitutively active vGPCR US28.

US28 is a broad-spectrum constitutively active G protein-coupled receptor encoded by the human cytomegalovirus (HCMV). It binds and scavenges multiple CC-chemokines as well as CX3CL1 (fractalkine) by constitutive receptor endocytosis to escape immune surveillance. We herein report the design and characterization of a novel library of US28-acting commercially available ligands based on the molecular descriptors of two previously reported US28-acting structures. Among these, we identify compounds capable of selectively recognizing CCL2-and CCL4-, but not CX3CL1-induced receptor conformations. Moreover, we find a direct correlation between the binding properties of small molecule ligands to CCL-induced conformations at the wild-type receptor and functional activity at the C-terminal truncated US28Δ300. As US28Δ300 is devoid of arrestin-recruitment and endocytosis, this highlights the potential usefulness of this construct in future drug discovery efforts aimed at specific US28 conformations. The new scaffolds identified herein represent valuable starting points for the generation of novel anti-HCMV therapies targeting the virus-encoded chemokine receptor US28 in a conformational-selective manner.

Structure-based discovery of novel US28 small molecule ligands with different modes of action.

The human cytomegalovirus-encoded G protein-coupled receptor US28 is a constitutively active receptor, which can recognize various chemokines. Despite the recent determination of its 2.9 Å crystal structure, potent and US28-specific tool compounds are still scarce. Here, we used structural information from a refined US28:VUF2274 complex for virtual screening of >12 million commercially available small molecule compounds. Using a combined receptor- and ligand-based approach, we tested 98 of the top 0.1% ranked compounds, revealing novel chemotypes as compared to the ~1.45 million known ligands in the ChEMBL database. Two compounds were confirmed as agonist and inverse agonist, respectively, in both IP accumulation and Ca2+ mobilization assays. The screening setup presented in this work is computationally inexpensive and therefore particularly useful in an academic setting as it enables simultaneous testing in binding as well as in different functional assays and/or species without actual chemical synthesis.