A formyl peptide substituted with a conformationally constrained phenylalanine residue evokes a selective immune response in human neutrophils

Formyl-Met-Leu-Phe-OH (fMLP) binds to formyl peptide receptors, FPR1 and FPR2, and evokes migration and superoxide anion production in human neutrophils. To obtain a more effective and selective ligand, fMLP analogs in which the Phe residue was substituted with four isomers of cyclopropanephenylalanine were synthesized. While Z-isomer peptides induced both migration and superoxide anion production, E-isomer peptides elicited only chemotaxis. Homologous receptor desensitization experiments revealed that E-isomer peptides bound to FPR2. Although a selective agonist of chemotaxis also binds to FPR2 without increasing intracellular calcium concentration, E-isomer peptide elevated the concentration to the same level as fMLP. Understanding of mechanisms responsible for the selectivity of the reported selective agonists and ?Phe-substituted analogs should prove useful for revealing the relationship between receptor–ligand interactions and biological responses of human neutrophils.     

Regulation of the Formyl Peptide Receptor 1 (FPR1) Gene in Primary Human Macrophages

The formyl peptide receptor 1 (FPR1) is mainly expressed by mammalian phagocytic leukocytes and plays a role in chemotaxis, killing of microorganisms through phagocytosis, and the generation of reactive oxygen species. A large number of ligands have been identified triggering FPR1 including formylated and non-formylated peptides of microbial and endogenous origin. While the expression of FPR1 in neutrophils has been investigated intensively, knowledge on the regulation of FPR1 expression in polarized macrophages is lacking. In this study we show that primary human neutrophils, monocytes and resting macrophages do express the receptor on their cell surface. Polarization of macrophages with IFNγ, LPS and with the TLR8 ligand 3M-002 further increases FPR1 mRNA levels but does not consistently increase protein expression or chemotaxis towards the FPR1 ligand fMLF. In contrast, polarization of primary human macrophages with IL-4 and IL-13 leading to the alternative activated macrophages, reduces FPR1 cell surface expression and abolishes chemotaxis towards fMLF. These results show that M2 macrophages will not react to triggering of FPR1, limiting the role for FPR1 to chemotaxis and superoxide production of resting and pro-inflammatory M1 macrophages.     

Activated N-formyl peptide receptor and high-affinity IgE receptor occupy common domains for signaling and internalization

Immune cells display multiple cell surface receptors that integrate signals for survival, proliferation, migration, and degranulation. Here, immunogold labeling is used to map the plasma membrane distributions of two separate receptors, the N-formyl peptide receptor (FPR) and the high-affinity IgE receptor (FepsilonRI). We show that the FPR forms signaling clusters in response to monovalent ligand. These domains recruit Gi, followed by the negative regulatory molecule arrestin2. There are low levels of colocalization of FPR with FcepsilonRI in unstimulated cells, shown by computer simulation to be a consequence of receptor density. Remarkably, there is a large increase in receptor coclustering when cells are simultaneously treated with N-formyl-methionyl-leucyl-phenylalanine and IgE plus polyvalent antigen. The proximity of two active receptors may promote localized cross-talk, leading to enhanced inositol-(3,4,5)-trisphosphate production and secretion. Some cointernalization and trafficking of the two receptors can be detected by live cell imaging, but the bulk of FPR and FcepsilonRI segregates over time. This segregation is associated with more efficient internalization of cross-linked FcepsilonRI than of arrestin-desensitized FPR. The observation of receptors in lightly coated membrane invaginations suggests that, despite the lack of caveolin, hematopoietic cells harbor caveolae-like structures that are candidates for nonclathrin-mediated endocytosis.     

The N-formylpeptide receptor (FPR) and a second G(i)-coupled receptor mediate fMet-Leu-Phe-stimulated activation of NADPH oxidase in murine neutrophils

N-Formylypeptides such as fMet-Leu-Phe (fMLF) potently induce superoxide production through NADPH oxidase activation. The receptors that mediate this response have not been defined. Here, we provide definitive proof using a mouse model that formyl peptide receptor (FPR) is a receptor, but not the only receptor, that mediates fMLF-induced oxidase activation. In wild-type (FPR(+/+)) mouse neutrophils, superoxide production is dependent on the concentration of fMLF with an EC(50) of approximately 5 microM and a peak at approximately 50 microM. In contrast, FPR-deficient (FPR(-/-)) mouse neutrophils produced markedly less superoxide with an EC(50) of approximately 50 microM and a peak at approximately 200 microM. Yet, FPR(+/+) and FPR(-/-) neutrophils showed similar oxidase activation kinetics and G(i) protein-dependent pharmacological sensitivities. These results suggested that a second receptor, likely FPR2, mediates superoxide production at high concentrations of fMLF. This less sensitive second pathway may permit continued oxidant generation in response to formyl peptides when FPR is desensitized in high concentrations of the chemotactic gradient.     

Second transmembrane domain of human uncoupling protein 2 is essential for its anion channel formation

Uncoupling proteins (UCP) are known to transport anions, such as Cl-, in addition to H+ transport. Although H+ transport by UCP is clearly involved in thermogenesis, the mechanism of its anion transport is not clearly understood. In this study, we examined the anion channel characteristics of the six individual helical transmembrane (TM) domains of the human UCP2. The second TM domain peptide (TM2) forms multi-state channels by assemblies of conductive oligomers. Furthermore, the TM2 exhibited voltage-dependent anion channels with properties comparable to those of UCP1 chloride channel. However, the other five TM peptides did not form UCP1-like channels. Moreover, an analog of TM2 in which two Arg residues were substituted by Ala residues did not form stable channels, implying the significance of Arg residues for anion transport. These results suggest that the anion channel structure of UCP2 protein is oligomeric and the second TM domain is essential for the voltage-dependence of this anion channel.     

An annexin 1 N-terminal peptide activates leukocytes by triggering different members of the formyl peptide receptor family

The human N-formyl peptide receptor (FPR) is a key modulator of chemotaxis directing granulocytes toward sites of bacterial infections. FPR is the founding member of a subfamily of G protein-coupled receptors thought to function in inflammatory processes. The other two members, FPR-like (FPRL)1 and FPRL2, have a greatly reduced affinity for bacterial peptides or do not bind them at all, with FPRL2 being considered an orphan receptor so far. In this study we show that a peptide derived from the N-terminal domain of the anti-inflammatory protein annexin 1 (lipocortin 1) can activate all three FPR family members at similar concentrations. The annexin 1 peptide initiates chemotactic responses in human monocytes that express all three FPR family members and also desensitizes the cells toward subsequent stimulation with bacterial peptide agonists. Experiments using HEK 293 cells stably expressing a single FPR family member reveal that all three receptors can be activated and desensitized by the N-terminal annexin 1 peptide. These observations identify the annexin 1 peptide as the first endogenous ligand of FPRL2 and indicate that annexin 1 participates in regulating leukocyte emigration into inflamed tissue by activating and desensitizing different receptors of the FPR family.     

Hetero-assembly between all-L- and all-D-amino acid transmembrane domains: forces involved and implication for inactivation of membrane proteins

Protein-protein interactions within the membrane, partially or fully mediated by transmembrane (TM) domains, are involved in many vital cellular processes. Since the unique feature of the membrane environment enables protein-protein assembly that otherwise is not energetically favored in solution, the structural restrictions involved in the assembly of soluble proteins are not necessarily valid for the assembly of TM domains. Here we used the N-terminal TM domain (Tar-1) of the Escherichia coli aspartate receptor as a model system for examining the stereospecificity of TM-TM interactions in vitro and in vivo in isolated systems, and in the context of the full receptor. For this propose, we synthesized Tar-1 all-l and all-d amino acid TM peptides, a mutant TM peptide and an unrelated TM peptide. The data revealed: (i) Tar-1 all-d specifically associated with Tar-1 all-l within a model lipid membrane, as determined by using fluorescence energy transfer experiments; (ii) Tar-1 all-l and all-d, but not the control peptides, demonstrated a dose-dependant dominant negative effect on the Tar-1 TM homodimerization in the bacterial ToxR assembly system, suggesting a wild-type-like interaction; and most interestingly, (iii) both Tar-1 all-l and all-d showed a remarkable ability to inhibit the chemotaxis response of the full-length receptor, in vivo. Peptide binding to the bacteria was confirmed through confocal imaging, and Western blotting confirmed that ToxR Tar-1 chimera protein levels are not affected by the presence of the exogenous peptides. These findings present the first evidence that an all-d TM domain peptide acts in vivo similarly to its parental all-l peptide and suggest that the dimerization of the TM domains is mainly mediated by side-chain interactions, rather than geometrically fitted conformations. In addition, the study provides a new approach for modifying the function of membrane proteins by proteolysis-free peptides.     

Identification of functional domains in the formyl peptide receptor-like 1 for agonist-induced cell chemotaxis

Formyl peptide receptor-like 1 (FPRL1) is a seven transmembrane domain, G protein-coupled receptor that interacts with a variety of exogenous and host-derived agonists. In order to identify domains crucial for ligand recognition by FPRL1, we used chimeric receptors with segments in FPRL1 replaced by corresponding amino acid sequences derived from the prototype formyl peptide receptor FPR. The chimeric receptors were stably transfected into human embryonic kidney epithelial cells and the capacity of the cells to migrate in response to formyl peptide receptor agonists was evaluated. Our results showed that multiple domains in FPRL1 are involved in the receptor response to chemotactic agonists with the sixth transmembrane domain and the third extracellular loop playing a prominent role. Interestingly, the N-terminus and a segment between the fourth transmembrane domain and the third intracellular loop of FPRL1 are important for receptor interaction with a 42 amino acid amyloid beta peptide (Abeta42), an Alzheimer's disease-associated FPRL1 agonist, but not with MMK-1, a synthetic FPRL1 agonist, suggesting that diverse agonists may use different domains in FPRL1. Considering the potential importance of FPRL1 in inflammation and neurodegenerative diseases, the identification of functional domains in this receptor will provide valuable information for the design of specific receptor antagonists.     

The FPR2-specific ligand MMK-1 activates the neutrophil NADPH-oxidase,but triggers no unique pathway for opening of plasma membrane calcium channels

Human neutrophils express formyl peptide receptor 1 and 2 (FPR1 and FPR2), two highly homologous G-protein-coupled cell surface receptors important for the cellular recognition of chemotactic peptides. They share many functional as well as signal transduction features, but some fundamental differences have been described. One such difference was recently presented when the FPR2-specific ligand MMK-1 was shown to trigger a unique signal in neutrophils [S. Partida-Sanchez, P. Iribarren, M.E. Moreno-Garcia, et al., Chemotaxis and calcium responses of phagocytes to formyl peptide receptor ligands is differentially regulated by cyclic ADP ribose, J. Immunol. 172 (2004) 1896–1906]. This signal bypassed the emptying of the intracellular calcium stores, a route normally used to open the store-operated calcium channels present in the plasma membrane of neutrophils. Instead, the binding of MMK-1 to FPR2 was shown to trigger a direct opening of the plasma membrane channels. In this report, we add MMK-1 to a large number of FPR2 ligands that activate the neutrophil superoxide-generating NADPH-oxidase. In contrast to earlier findings we show that the transient rise in intracellular free calcium induced by MMK-1 involves both a release of calcium from intracellular stores and an opening of channels in the plasma membrane. The same pattern was obtained with another characterized FPR2 ligand, WKYMVM, and it is also obvious that the two formyl peptide receptor family members trigger the same type of calcium response in human neutrophils.     

A monocyte-specific peptide from herpes simplex virus type 2 glycoprotein G activates the NADPH-oxidase but not chemotaxis through a G-protein-coupled receptor distinct from the members of the formyl peptide receptor family

We have recently identified a peptide derived from the secreted portion of the HSV-2 glycoprotein G, gG-2p20, to be proinflammatory. Based on its ability to activate neutrophils and monocytes via the formyl peptide receptor (FPR) to produce reactive oxygen species (ROS) that down-regulate NK cell function, we suggested it to be of importance in HSV-2 pathogenesis. We now describe the effects of an overlapping peptide, gG-2p19, derived from the same HSV-2 protein. Also, this peptide activated the ROS-generating NADPH-oxidase, however, only in monocytes and not in neutrophils. Surprisingly, gG-2p19 did not induce a chemotactic response in the affected monocytes despite using a pertussis toxin-sensitive, supposedly G-protein-coupled receptor. The specificity for monocytes suggested that FPR and its homologue FPR like-1 (FPRL1) did not function as receptors for gG-2p19, and this was also experimentally confirmed. Surprisingly, the monocyte-specific FPR homologue FPRL2 was not involved either, and the responsible receptor thus remains unknown so far. However, the receptor shares some basic signaling properties with FPRL1 in that the gG-2p19-induced response was inhibited by PBP10, a peptide that has earlier been shown to selectively inhibit FPRL1-triggered responses. We conclude that secretion and subsequent degradation of the HSV-2 glycoprotein G can generate several peptides that activate phagocytes through different receptors, and with different cellular specificities, to generate ROS with immunomodulatory properties.     

Characterization of peptides corresponding to the seven transmembrane domains of human adenosine A2a receptor

Human adenosine A(2)a receptor is a member of the G-protein-coupled receptor (GPCR) superfamily of seven-helix transmembrane (TM) proteins. To test general models for membrane-protein folding and to identify specific features of folding and assembly for this representative member of an important and poorly understood class of proteins, we synthesized peptides corresponding to its seven TM domains. We assessed the ability of the peptides to insert into micelles and vesicles and measured secondary structure for each peptide in aqueous and membrane-mimetic environments. CD spectra indicate that each of the seven TM peptides form thermally stable, independent alpha-helical structures in both micelles and vesicles. The helical content of the peptides depends on the nature of the membrane-mimetic environment. Four of the peptides (TM3, TM4, TM5, and TM7) exhibit very high-helical structure, near the predicted maximum for their TM segments. The TM1 peptide also adopts relatively high alpha-helical structures. In contrast, two of peptides, TM2 and TM6, display low alpha helicity. Similarly, the ability of the peptides to insert into membrane-mimetic environments, assayed by intrinsic tryptophan fluorescence and fluorescence quenching, varied markedly. Most peptides exhibit higher alpha helicity in anionic sodium dodecyl sulfate than in neutral dodecyl-beta-D-maltoside micelles, and TM2 was disordered in zwiterionic DMPC but was alpha-helical in negatively charged DMPC/DMPG vesicles. These findings strongly suggest that electrostatic interactions between lipids and peptides control the insertion of the peptides and may be involved in membrane-protein-folding events. The measured helical content of these TM domains does not correlate with the predicted helicity based on amino acid sequence, pointing out that, while hydrophobic interactions can be a major determinant for folding of TM peptides, other factors, such as electrostatic interactions or helix-helix interactions, may play significant roles for specific TM domains. Our results represent a comprehensive analysis of helical propensities for a human GPCR and support models for membrane-protein folding in which interactions between TM domains are required for proper insertion and folding of some TM helix domains. The tendency of some peptides to self-associate, especially in aqueous environments, underscores the need to prevent improper interactions during folding and refolding of membrane proteins in vivo and in vitro.     

Low-affinity receptor-mediated induction of superoxide by N-formyl-methionyl-leucyl-phenylalanine and WKYMVm in IMR90 human fibroblasts

We investigated in IMR90 cells the effects of N-formyl-Met-Leu-Phe (N-fMLP) and WKYMVm (W peptide) on activation of the NADPH oxidase-like enzyme. In serum-deprived human fibroblasts, exposure to 100 microM N-fMLP or 10 microM peptide W for 1 min induced both p47phox translocation and NADPH-dependent superoxide generation. These effects were in large part mediated by prevention of the rapid activation of extracellular signal-regulated kinases (ERKs) by preincubation with the MEK1 inhibitor PD098059. Furthermore, responses to N-fMLP or W peptide were inhibited by pertussis toxin, suggesting the involvement of a seven-transmembrane G protein-coupled receptor(s) for peptides. RT-PCR experiments demonstrated the expression in these cells of the low-affinity receptor FPRL1, but not the high-affinity receptor FPR. Incubation with radiolabeled WKYMVm, which had a higher efficiency on FPRL1, revealed that human fibroblasts express binding sites for 125I-WKYMVm that are specifically displaced by increasing concentrations of unlabeled ligand. Analysis of the binding data predicted a Kd of 155.99 nM and a receptor density of about 16,200 molecules/cell. HEK293 cells, which express a NADPH oxidase-like enzyme but not formyl peptide receptors, transiently transfected with FPRL1 cDNA produced superoxide on stimulation with N-fMLP or W peptide, demonstrating that this receptor is biologically functional.     

Activation of human monocytes by a formyl peptide receptor 2-derived pepducin

We synthesized and investigated the effect of formyl peptide receptor 2 (FPR2)-derived pepducins in human monocytes. The FPR2-based cell-penetrating lipopeptide, “pepducin” (F2pal-16), stimulated intracellular calcium increase in human monocytes via pertussis toxin (PTX)-sensitive G-protein and phospholipase C (PLC) activity. From a functional aspect, we showed that F2pal-16 stimulated monocyte chemotaxis. F2pal-16 also stimulated the generation of superoxide anion in human monocytes. Moreover, F2pal-16 dramatically increased the production of several kinds of pro-inflammatory cytokines (CXCL8, CCL2, IL-1β and TNF-α) in human monocytes via NF-κB activation. Since FPR2 plays an important role in immune responses, F2pal-16 can serve as a useful reagent for the study of FPR2-mediated immune modulation.     

Heptad repeat 2-based peptides inhibit avian sarcoma and leukosis virus subgroup a infection and identify a fusion intermediate

Fusion proteins of enveloped viruses categorized as class I are typified by two distinct heptad repeat domains within the transmembrane subunit. These repeats are important structural elements that assemble into the six-helix bundles characteristic of the fusion-activated envelope trimer. Peptides derived from these domains can be potent and specific inhibitors of membrane fusion and virus infection. To facilitate our understanding of retroviral entry, peptides corresponding to the two heptad repeat domains of the avian sarcoma and leukosis virus subgroup A (ASLV-A) TM subunit of the envelope protein were characterized. Two peptides corresponding to the C-terminal heptad repeat (HR2), offset from one another by three residues, were effective inhibitors of infection, while two overlapping peptides derived from the N-terminal heptad repeat (HR1) were not. Analysis of envelope mutants containing substitutions within the HR1 domain revealed that a single amino acid change, L62A, significantly reduced sensitivity to peptide inhibition. Virus bound to cells at 4 degrees C became sensitive to peptide within the first 5 min of elevating the temperature to 37 degrees C and lost sensitivity to peptide after 15 to 30 min, consistent with a transient intermediate in which the peptide binding site is exposed. In cell-cell fusion experiments, peptide inhibitor sensitivity occurred prior to a fusion-enhancing low-pH pulse. Soluble receptor for ASLV-A induces a lipophilic character in the envelope which can be measured by stable liposome binding, and this activation was found to be unaffected by inhibitory HR2 peptide. Finally, receptor-triggered conformational changes in the TM subunit were also found to be unaffected by inhibitory peptide. These changes are marked by a dramatic shift in mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, from a subunit of 37 kDa to a complex of about 80 kDa. Biotinylated HR2 peptide bound specifically to the 80-kDa complex, demonstrating a surprisingly stable envelope conformation in which the HR2 binding site is exposed. These experiments support a model in which receptor interaction promotes formation of an envelope conformation in which the TM subunit is stably associated with its target membrane and is able to bind a C-terminal peptide.     

Ligand/receptor internalization: a spectroscopic analysis and a comparison of ligand binding, cellular response, and internalization by human neutrophils

We have compared the kinetics of the responses of neutrophils to the kinetics of ligand-receptor interaction and internalization, using as a model ligand the fluoresceinated hexapeptide N-CHO-Nle-Leu-Phe-Nle-Tyr-Lys-Fluorescein (Nle, norleucine). Cellular responses, ie, membrane depolarization, enzyme (elastase) secretion, and superoxide anion (O-2) generation, are all initiated within 10 sec of the exposure of cells to stimulus. In the cases of membrane depolarization and secretion (in cytochalasin B-treated cells), full responses are elicited by binding which occurs within 15 sec of peptide addition. Ligand binding and internalization have been analyzed over the same time frame with new spectroscopic techniques. The association of ligand and receptor is monitored using an antibody to fluorescein. The antibody to fluorescein specifically quenches the ligand which is in solution, but receptor-bound ligand is inaccessible to the antibody. The internalization of the receptor-bound ligand is monitored by the accessibility of the fluoresceinated peptide to quenching by an external pH change (7.4 leads to 4.0). Ligand which is either outside or on the cell surface is instantaneously quenched while intracellular peptide (or intracellular fluorescein derived from fluorescein diacetate) is only slowly quenched. No internalization is observed until 1 min after binding begins and internalization proceeds at a rate of up to 5,000 receptors/min/cell following a near optimal stimulatory ligand concentration (approximately 1 nM) while the occupied receptors are being cleared from the surface. A comparison of the kinetics of internalization and the cellular responses suggests that internalization of the ligand is too slow to be involved in the triggering of the cellular responses.     

Neutrophil chemoattractant receptors and the membrane skeleton

Signal transduction via receptors for N-formylmethionyl peptide chemoattractants (FPR) on human neutrophils is a highly regulated process which involves participation of cytoskeletal elements. Evidence exists suggesting that the cytoskeleton and/or the membrane skeleton controls the distribution of FPR in the plane of the plasma membrane, thus controlling the accessibility of FPR to different proteins in functionally distinct domains. In desensitized cells, FPR are restricted to domains which are depleted of G proteins but enriched in cytoskeletal proteins such as actin and fodrin. Thus, the G protein signal transduction partners of FPR become inaccessible to the agonist-occupied receptor, preventing cell activation. The mechanism of interaction of FPR with the membrane skeleton is poorly understood but evidence is accumulating that suggests a direct binding of FPR (and other receptors) to cytoskeletal proteins such as actin.     

Different endocytosis pathways of the C5a receptor and the N-formyl peptide receptor

Two chemoattractant receptors, C5aR (the complement fragment C5a receptor) and FPR (the N-formyl peptide receptor), are involved in neutrophil activation at sites of inflammation. In this study, we found major differences in the intracellular trafficking of the receptors in transfected Chinese hamster ovary (CHO) cells. Western blot analysis showed that FPR was stable during a 3 h stimulation with ligand, but C5aR was reduced in quantity by 50%. Not all C5aR was targeted directly for degradation however; a small, but visible fraction of the receptor became re-phosphorylated upon subsequent addition of ligand, suggesting that some of the receptor had cycled to the cell surface. Light membrane fractions isolated from activated cells showed C5aR distribution at the bottom of a glycerol gradient, colocalizing with the main distribution of the late endosomal/lysosomal marker LAMP2, whereas FPR was found at the bottom of the gradient as well as in the middle of the gradient, where it cofractionated with the early/sorting endosomal marker Rab5. Using fluorescence microscopy, we observed ligand-dependent redistribution of C5aR-EGFP from the plasma membrane to LAMP2-positive compartments, whereas FPR-EGFP showed significant colocalization with the early/sorting endosomes. Analysis of endogenous C5aR and FPR in neutrophils revealed a pattern similar to the CHO transfectants: C5aR underwent degradation after prolonged ligand stimulation, while FPR did not. Finally, we confirmed the down-regulation of C5aR in a functional assay by showing reduced chemotaxis toward C5a in both CHO transfectants and neutrophils after preincubation with C5a. A similar decrease in FPR-mediated chemotaxis was not observed.     

N-formyl peptide receptor 3 (FPR3) departs from the homologous FPR2/ALX receptor with regard to the major processes governing chemoattractant receptor regulation, expression at the cell surface, and phosphorylation

Among human N-formyl peptide chemoattractant receptors, FPR2/ALX and FPR3 share the highest degree of amino acid identity (83%), and trigger similar cell responses upon ligand binding. Although FPR2/ALX is a promiscuous receptor, FPR3 has only one specific high affinity ligand, F2L, and a more restricted tissue/cell distribution. In this study, we showed that FPR2/ALX behaved as the prototypical receptor FPR1. The agonist-dependent phosphorylation used a hierarchical mechanism with a prominent role of Ser(329), Thr(332), and Thr(335). Phosphorylation of FPR2/ALX was essential for its desensitization but the lack of phosphorylation did not result in enhanced or sustained responses. In contrast, resting FPR3 displayed a marked level of phosphorylation, which was only slightly increased upon agonist stimulation. Another noticeable difference between the two receptors was their subcellular distribution in unstimulated cells. Although FPR2/ALX was evenly distributed at the plasma membrane FPR3 was localized in small intracellular vesicles. By swapping domains between FPR2/ALX and FPR3, we uncovered the determinants involved in the basal phosphorylation of FPR3. Experiments aimed at monitoring receptor-bound antibody uptake showed that the intracellular distribution of FPR3 resulted from a constitutive internalization that was independent of C terminus phosphorylation. Unexpectedly, exchanging residues 1 to 53, which encompass the N-terminal extracellular region and the first transmembrane domain, between FPR2/ALX and FPR3 switched localization of the receptors from the plasma membrane to intracellular vesicles and vice versa. A clathrin-independent, possibly caveolae-dependent, mechanism was involved in FPR3 constitutive internalization. The peculiar behavior of FPR3 most probably serves distinct physiological functions that remain largely unknown.     

Human formyl peptide receptor function role of conserved and nonconserved charged residues.

In this study, we investigated the role of charged residues in ligand binding interactions of f-Met-Leu-Phe receptors (FPR). Charged residues of FPR, both conserved and nonconserved, which are located close to the membrane interface were mutated to alanine to determine their role in ligand binding. The mutated residues belonged to specific domains of FPR which have previously been implicated in FPR ligand binding interactions. We demonstrate that nonconserved charged residues such as Arg84, Lys85, Arg205 and Asp284 and conserved charge residue Arg163 seem to play a role in ligand binding. However, alteration of nonconserved charged residue Asp106 did not have any effect. In conclusion, specific charged residues of FPR, both conserved nonconserved, may contribute to FPR function either directly or indirectly.