Identification of a Salt Bridge That Is Functionally Important for Chemokine Receptor CXCR1 but not CXCR2.

CXC chemokine receptors 1 (CXCR1) and 2 (CXCR2) have high sequence similarity and overlapping chemokine ligand profiles. Residue positions 3.32 and 7.39 are critical for signal transduction in the related CXCR4, and in these positions CXCR1 and CXCR2 contain oppositely charged residues (Lys3.32 and Glu7.39). Experimental and computed receptor structures reveal the possible formation of a salt bridge between transmembrane (TM) helices 3 and 7 via these two residues. To investigate the functional importance of Lys1173.32 and Glu2917.39 in CXCR1, along with the flanking Glu1183.33, we performed a signaling study on 16 CXCR1 mutants using two different CXCL8 isoforms. While single Ala-mutation (K1173.32A, E2917.39A) and charge reversal (K1173.32E, E2917.39K) resulted in nonfunctional receptors, double (K1173.32E-E2917.39K) and triple (K1173.32E-E1183.33A-E2917.39K) mutants rescued CXCR1 function. In contrast, the corresponding mutations did not affect the CXCR2 function to the same extent. Our findings show that the Lys3.32-Glu7.39 salt bridge between TM3 and -7 is functionally important for CXCR1 but not for CXCR2, meaning that signal transduction for these highly homologous receptors is not conserved.

Selective Allosteric Modulation of N-Terminally Cleaved, but Not Full Length CCL3 in CCR1.

Chemokines undergo post-translational modification such as N-terminal truncations. Here, we describe how N-terminal truncation of full length CCL3(1-70) affects its activity at CCR1. Truncated CCL3(5-70) has 10-fold higher potency and enhanced efficacy in ß-arrestin recruitment, but less than 2-fold increased potencies in G protein signaling determined by calcium release, cAMP and IP3 formation. Small positive ago-allosteric ligands modulate the two CCL3 variants differently as the metal ion chelator bipyridine in complex with zinc (ZnBip) enhances the binding of truncated, but not full length CCL3, while a size-increase of the chelator to a chloro-substituted terpyridine (ZnClTerp), eliminates its allosteric, but not agonistic action. By employing a series of receptor mutants and in silico modeling we describe residues of importance for chemokine and small molecule binding. Notably, the chemokine receptor-conserved Glu2877.39 interacts with the N-terminal amine of truncated CCL3(5-70) and with Zn2+ of ZnBip, thereby bridging their binding sites and enabling the positive allosteric effect. Our study emphasizes that small allosteric molecules may act differently toward chemokine variants and thus selectively modulate interactions of specific chemokine subsets with their cognate receptors.