Receptor recognition and specificity of interleukin-8 is determined by residues that cluster near a surface-accessible hydrophobic pocket.

To determine the regions of interleukin-8 (IL-8) that allow high affinity and interleukin-8 receptor type 1 (IL8R1)-specific binding of chemokines, we produced chimeric proteins containing structural domains from IL-8, which binds to both IL8R1 and interleukin-8 receptor type 2 (IL8R2) with high affinity, and from GRO gamma, which does not bind to IL8R1 and binds to IL8R2 with reduced affinity. Receptor binding activity was tested by competition of 125I-IL-8 binding to recombinant IL8R1 and IL8R2 cell lines. Substitution into IL-8 of the GRO gamma sequences corresponding to either the amino-terminal loop (amino acids 1-18) or the first beta-sheet (amino acids 18-32) reduced binding to both IL8R1 and IL8R2. The third beta-sheet of IL-8 (amino acids 46-53) was required for binding to IL8R1 but not IL8R2. Exchanges of the second beta-sheet (amino acids 32-46) or the carboxyl-terminal alpha-helix (amino acids 53-72) had no significant effect. When IL-8 sequences were substituted into GRO gamma, a single domain containing the second beta-sheet of IL-8 (amino acids 18-32) was sufficient to confer high affinity binding for both IL8R1 and IL8R2. The amino-terminal loop (amino acids 1-18) and the third beta-sheet (amino acids 46-53) of IL-8 had little effect when substituted individually but showed increased binding to both receptors when substituted in combination. Individual amino acid substitutions were made at positions where IL-8 and GRO gamma sequences differ within the regions of residues 11-21 and 46-53. IL-8 mutations L49A or L49F selectively inhibited binding to IL8R1. Mutations Y13L and F21N enhanced binding to IL8R1 with little effect on IL8R2. A combined mutation Y13L/S14Q selectively decreased binding to IL8R2. Residues Tyr13, Ser14, Phe21, and Lys49 are clustered in and around a surface-accessible hydrophobic pocket on IL-8 that is physically distant from the previously identified ELR binding sequence. A homology model of GRO gamma, constructed from the known structure of IL-8 by refinement calculations, indicated that access to the hydrophobic pocket was effectively abolished in GRO gamma. These studies suggest that the surface hydrophobic pocket and/or adjacent residues participate in IL-8 receptor recognition for both IL8R1 and IL8R2 and that the hydrophobic pocket itself may be essential for IL8R1 binding. Thus this region contains a second site for IL-8 receptor recognition that, in combination with the Glu4-Leu5-Arg6 region, can modulate receptor binding affinity and IL8R1 specificity.

IL-8 induces neutrophil chemotaxis predominantly via type I IL-8 receptors.

IL-8 is a potent proinflammatory cytokine that has a key role in the recruitment and activation of neutrophils during inflammation. IL-8 reacts with neutrophils via two distinct types of IL-8-R. Receptor-specific Abs were raised against peptides derived from the first extracellular domain of each IL-8-R. Anti-IL-8-R1 and anti-IL-8-R2 selectively block 125I-IL-8 binding to rIL-8-R type 1 or 2, respectively. The anti-peptide Abs were used to assess the role of each receptor in the chemotactic response of neutrophils to GRO alpha and to IL-8. Anti-IL-8-R2 blocks GRO alpha-induced chemotaxis of neutrophils. Chemotaxis to GRO alpha is not inhibited by anti-IL-8-R1. Thus GRO alpha stimulates chemotaxis exclusively through IL-8-R2 and independently of IL-8-R1. Surprisingly, anti-IL-8-R1 inhibits the majority (78 +/- 3%) of IL-8-induced neutrophil chemotaxis. Only a minor proportion of IL-8-induced chemotaxis (29 +/- 5%) is inhibited by anti-IL-8-R2. These findings indicate that chemotaxis to IL-8 is mediated predominantly by type 1 IL-8-Rs and suggest that IL-8-R1 is an appropriate target for therapeutic strategies to limit neutrophil influx in diseases where neutrophils contribute to pathophysiology.