The binding of G protein to the N-formyl peptide receptor of human neutrophils was investigated with site-specific synthetic peptides. Peptide CT336(322) (322RALTEDSTQTSDTAT336) from the carboxyl-terminal tail region of the receptor competed with the receptor for binding to bovine Gi protein. The peptide competition was assayed by dissociation of a GTP-sensitive, rapidly sedimenting (7S) form of receptor-G protein complex as analyzed by velocity sedimentation on linear sucrose density gradients. An IC50 of 590 microM was determined for CT336(322) peptide. A control peptide, with the reverse sequence, rCT322(336) (336TATDSTQTSDETLAR322), did not perturb the sedimentation of the reconstituted receptor-G protein complex up to the highest tested concentration, 3 mM. Other peptides tested, corresponding to central portions of the predicted intracellular loop regions CII140(127) (127VLHPVWTQNHRTVS140) and CIII239(227) (227KIHKQGLIKSSRP239) of the receptor, failed to dissociate the reconstituted receptor-G protein complex. Control peptides from the extracellular region EII184(170) (170KTGTVACTFNFSPWT184) and an unrelated sequence matching a portion of neutrophil cytochrome b, CYT306(296) (296KVVITKVVTHPFKTIE306), were also ineffective. Our results suggest that the cytoplasmic tail of the formyl chemotactic peptide receptor is involved in its coupling to the signal-transducing G protein.
The N-formyl peptide receptor (FPR) of human neutrophils is a member of the G protein-coupled receptor (GPCR) superfamily. Sites on agonist-occupied FPR involved in binding the Gi2 protein were investigated by competition with synthetic receptor-mimetic peptides. Twenty-three synthetic FPR-mimetic and control peptides were tested for their ability to disrupt functionally active complexes of FPR and Gi2 in octyl glucoside, assayed by changes in sedimentation rates of FPR in detergent-containing sucrose gradients. GPCRs are thought to contain seven transmembrane segments with three cytoplasmic connecting loops and a cytoplasmic tail. Only certain peptides from regions in or adjoining each of the four predicted cytoplasmic domains of the 350 amino acid FPR, including the first cytoplasmic loop, were able to disrupt the reconstituted FPR-Gi2 complex. The IC50s of the peptides that were able to fully disrupt the FPR-Gi2 complex ranged from 20 microM (C2W 122-134) to 1.4 mM (C3A 230-246), a range similar to peptide inhibition of other G protein-coupled receptor-G protein interactions. Detergent concentrations above and below the critical micelle concentration had no effect on the activity of even the most hydrophobic peptide, C3B, and there was no apparent correlation of activity with hydrophobic moment, hydrophilic index, or net charge of the peptides. Control peptides from irrelevant proteins with similar physical properties and FPR extracellular domains did not dissociate the reconstituted FPR-Gi2 complex up to 5 mM, the highest concentration tested.(ABSTRACT TRUNCATED AT 250 WORDS)
When human neutrophils become desensitized to formyl peptide chemoattractants, the receptors (FPR) for these peptides are converted to a high affinity, GTP-insensitive form that is associated with the Triton X-100-insoluble membrane skeleton from surface membrane domains. These domains are actin and fodrin-rich, but G protein-depleted suggesting that FPR shuttling between G protein-enriched and depleted domains may control signal transduction. To determine the molecular basis for FPR interaction with the membrane skeleton, neutrophil subcellular fractions were screened for molecules that could bind photoaffinity-radioiodinated FPR solubilized in Triton X-100. These receptors showed a propensity to bind to a 41- to 43-kDa protein band on nitrocellulose overlays of SDS-PAGE-separated cytosol and plasma membrane fractions of neutrophils. This binding, as well as FPR binding to purified neutrophil actin, was inhibited 50% by 0.6 microM free neutrophil cytosolic actin. Addition of greater than 1 microM G-actin to crude or lectin-purified Triton X-100 extracts of FPR from neutrophil membranes increased the sedimentation rate of a significant fraction of FPR two to three fold as measured by velocity sedimentation in Triton X-100-containing linear sucrose density gradients. Addition of anti-actin antibodies to FPR extracts caused a concentration-dependent immunoprecipitation of at least 65% of the FPR. More than 40% of the immunoprecipitated FPR was specifically retained on protein A affinity matrices. Membrane actin was stabilized to alkaline washing when membranes were photoaffinity labeled. Conversely, when purified neutrophil cytosolic actin was added to membranes or their digitonin extracts, after prior depletion of actin by an alkaline membrane wash, photoaffinity labeling of FPR was increased two- to fourfold with an EC50 of approximately 0.1 microM actin. We conclude that FPR from human neutrophils may interact with actin in membranes to form Triton X-100-stable physical complexes. These complexes can accept additional G-actin monomers to form higher order molecular complexes. Formation of FPR-actin complexes in the neutrophil may play a role in the regulation of chemoattractant-induced activation or actin polymerization.
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