Atypical regulation of an atypical chemokine receptor: ACKR3 ‘senses’ CXCR4 activation through phosphorylation

ACKR3 is an arrestin-biased 7-transmembrane receptor that is unable to activate G proteins. The receptor shares the chemokine agonist, CXCL12, with the canonical G protein-coupled receptor (GPCR), CXCR4. The receptor pair plays a critical role in mediating cell migration during cardiac and CNS development as well as contributing to cancer growth and metastasis. Whereas CXCR4 drives cellular migration through G protein signaling, ACKR3 primarily acts to scavenge chemokines, which indirectly regulates migration through shaping the extracellular chemokine gradient. Scavenging is driven by constitutive internalization and recycling of the receptor and concomitant shuttling of CXCL12 to lysosomes for degradation. Since internalization of GPCRs is often dependent on phosphorylation and β-arrestins, we set out to resolve how GPCR kinases (GRKs) and β-arrestins influence ACKR3 scavenging. Despite robust β-arrestin recruitment by ACKR3, knockouts of β-arrestins had little impact on CXCL12 scavenging by the receptor; nevertheless, GRK phosphorylation is essential. Employing GRK knockout cells, we discovered that GRK5 is the dominant kinase for ACKR3 phosphorylation and primary driver of chemokine scavenging in HEK293 cells. In comparison the responses elicited by GRK2 were much more limited. Because GRK2 requires free Gβγ released by heterotrimeric G protein activation, we hypothesized that the muted GRK2 impact may be due to the lack of G protein coupling by ACKR3. Indeed, addition of Gβγ significantly enhanced GRK2-mediated ACKR3 phosphorylation and scavenging of CXCL12. Additionally, co-activation of CXCR4 produced sufficient Gβγ to promote GRK2 phosphorylation of ACKR3. These results suggest a mechanism for ACKR3 to ‘sense’ CXCR4 activation through GRK2 activity. Likewise, this would allow CXCR4 to influence CXCL12 scavenging as well as its own signaling by promoting β-arrestin recruitment to ACKR3.