Conformational plasticity and dynamic interactions of the N-terminal domain of the chemokine receptor CXCR1

Abstract

AbstractDynamic interactions between G protein-coupled receptors (GPCRs) and their cognate protein partners at the membrane interface control several cellular signaling pathways. An important example is the association of CXC chemokine receptor 1 (CXCR1) with its cognate chemokine, interleukin-8 (IL8 or CXCL8) that regulates neutrophil-mediated immune responses. Although the N-terminal domain of the receptor is known to confer ligand selectivity, the conformational dynamics of this intrinsically disordered region of CXCR1 in particular, and chemokine receptors in general, remains unresolved. In this work, we have explored the interaction of CXCR1 with IL8 by microsecond time scale coarse-grain simulations that were validated by atomistic models and NMR chemical shift predictions. We show that the conformational plasticity of theapo-receptorN-terminal region is restricted upon ligand binding, driving it to an open C-shaped conformation. Importantly, we validated the dynamic complex sampled in our simulations against chemical shift perturbations reported by previous NMR studies. Our results indicate that caution should be exercised when chemical shift perturbation is used as a reporter of residue contacts in such dynamic associations. We believe our results represent a step forward in devising a strategy to understand intrinsically disordered regions in GPCRs and how they acquire functionally important conformational ensembles in dynamic protein-protein interfaces.Author summaryHow cells communicate with the outside environment is intricately controlled and regulated by a large family of receptors on the cell membrane (G protein-coupled receptors or GPCRs) that respond to external signals (termed ligands). Chemokine receptors belong to this GPCR family and regulate immune responses. We analyze here the first step of binding of a representative chemokine receptor (CXCR1) with its natural ligand, interleukin 8 (IL8) by an extensive set of molecular dynamics simulations. Our work complements previous mutational and NMR experiments which lack molecular-level resolution. We show that in the inactive state, one of the extracellular domains of the CXCR1 receptor, namely the N-terminal domain, is highly flexible and like a “shape-shifter” can exist in multiple conformational states. However, when IL8 binds, the N-terminal domain undergoes a conformational freezing, and acquires a C-shaped “claw-like” structure. The complex between the receptor and IL8 is still quite dynamic as this C-shaped N-terminal domain forms an extensive but slippery interface with the ligand. We further validated these results by quantitative comparison with NMR and mutagenesis studies. Our work helps clarify the inherent disorder in N-terminal domains of chemokine receptors and demonstrates how this domain can acquire functionally important conformational states in dynamic protein-protein interfaces.