Marie-Josèphe Rabiet

Human Formyl Peptide Receptor 2 Senses Highly Pathogenic Staphylococcus aureus

Virulence of emerging community-associated methicillin-resistant Staphylococcus aureus (CA-MRSA) and other highly pathogenic S. aureus strains depends on their production of phenol-soluble modulin (PSM) peptide toxins, which combine the capacities to attract and lyse neutrophils. The molecular basis of PSM-stimulated neutrophil recruitment has remained unclear. Here, we demonstrate that the human formyl peptide receptor 2 (FPR2/ALX), which has previously been implicated in control of endogenous inflammatory processes, senses PSMs at nanomolar concentrations and initiates proinflammatory neutrophil responses to CA-MRSA. Specific blocking of FPR2/ALX or deletion of PSM genes in CA-MRSA severely diminished neutrophil detection of CA-MRSA. Furthermore, a specific inhibitor of FPR2/ALX and of its functional mouse counterpart blocked PSM-mediated leukocyte infiltration in vivo in a mouse model. Thus, the innate immune system uses a distinct FPR2/ALX-dependent mechanism to specifically sense bacterial peptide toxins and detect highly virulent bacterial pathogens. FPR2/ALX represents an attractive target for new anti-infective or anti-inflammatory strategies.

Serum amyloid A mediates human neutrophil production of reactive oxygen species through a receptor independent of formyl peptide receptor like-1.

Serum amyloid A (SAA) is one of the acute‐phase reactants, a group of plasma proteins that increases immensely in concentration during microbial infections and inflammatory conditions, and a close relationship between SAA levels and disease activity in rheumatoid arthritis (RA) has been observed. RA is an inflammatory disease, where neutrophils play important roles, and SAA is thought to participate in the inflammatory reaction by being a neutrophil chemoattractant and inducer of proinflammatory cytokines. The biological effects of SAA are reportedly mediated mainly through formyl peptide receptor like‐1 (FPRL1), a G protein‐coupled receptor (GPCR) belonging to the formyl peptide receptor family. Here, we confirmed the affinity of SAA for FPRL1 by showing that stably transfected HL‐60 cells expressing FPRL1 were activated by SAA and that the response was inhibited by the use of the FPRL1‐specific antagonist WRWWWW (WRW4). We also show that SAA activates the neutrophil NADPH‐oxidase and that a reserve pool of receptors is present in storage organelles mobilized by priming agents such as TNF‐α and LPS from Gram‐negative bacteria. The induced activity was inhibited by pertussis toxin, indicating the involvement of a GPCR. However, based on FPRL1‐specific desensitization and use of FPRL1 antagonist WRW4, we found the SAA‐mediated effects in neutrophils to be independent of FPRL1. Based on these findings, we conclude that SAA signaling in neutrophils is mediated through a GPCR, distinct from FPRL1. Future identification and characterization of the SAA receptor could lead to development of novel, therapeutic targets for treatment of RA.

Phagocyte Activation by Trp–Lys–Tyr–Met–Val–Met, Acting through FPRL1/LXA4R, is not Affected by Lipoxin A4

Lipoxin A4 (LXA4) has been shown to bind to the leucocyte formyl peptide receptor (FPR) homologue, FPRL1, without triggering the biological activities induced by other FPRL1 agonists. We investigated the direct effect of LXA4 as well as the effect on agonist‐induced biological responses using transfected HL‐60 cells expressing FPR, FPRL1 or FPRL2. LXA4 neither induced an intracellular rise in calcium in these transfectants nor affected the response induced by the peptide Trp–Lys–Tyr–Met–Val–Met (WKYMVM), an agonist that activates cells through FPRL1 and ‐2. Both agonists induced Erk‐2 activation; however, the eicosanoid‐induced activity was independent of FPRL1 and FPRL2. Moreover, LXA4 was unable to trigger neutrophil upregulation of complement receptor 3 and respiratory burst, and it had no effect on the responses induced by triggering with WKYMVM. We conclude that LXA4 is unable to affect the WKYMVM‐induced signalling through FPRL1 and suggest that it acts through a receptor different from FPRL1.

The Annexin I Sequence Gln9-Ala10-Trp11-Phe12 Is a Core Structure for Interaction with the Formyl Peptide Receptor 1

The N-terminal part of the calcium-regulated and phospholipid-binding protein annexin AI contains peptide sequences with pro- and anti-inflammatory activities. We have earlier shown that a proinflammatory signal triggered by one of these peptides, Gln9–Lys25, is mediated by FPR1, a member of the formyl peptide receptor family expressed in human neutrophils. To determine the core structure in Gln9–Lys25, smaller peptides were generated, and their capacity to activate neutrophils was determined. A peptide spanning from amino acid Glu14 to Lys25 was inactive, whereas the activity was retained in the Gln9–Tyr20 peptide. Removal of amino acids from the C and N terminus of Gln9–Tyr20 revealed that the first amino acid (Gln9) was of the utmost importance for activity. The core structure that activated the neutrophil NADPH oxidase to release superoxide anions was Gln9-Ala10-Trp11-Phe12. This peptide also inhibited the activity induced by N-formyl-Met-Leu-Phe and WKYMVM. A structural model of the peptide agonist-FPR1 complex suggests that the transmembrane part of the binding pocket of the receptor binds optimally to a tetrapeptide. According to the model and the results presented, the N-terminal amino acid glutamine in Gln9–Phe12 is located close to the bottom of the binding cleft, leaving for steric reasons insufficient space to extend the peptide at the N terminus. The addition of amino acids at the C terminus will not affect binding. The model presented may be helpful in developing specific FPR1 ligands.

Proteolytic Derivatives of Thrombin

Native a-thrombin, the end product of the clotting factor activation cascade, is a serine protease which not only catalyzes the conversion of fibrinogen into fibrin, but also clearly plays a central regulatory role in hemostasis by interacting with a wide variety of plasmatic and cellular components.’’2 Its catalytic mechanism seems rather similar to that of other serine proteases and like trypsin, thrombin cleaves preferentially peptide bonds involving the carboxyl group of basic amino acids, yet with a marked preference for arginine re~idues.3’~ Because of the number of its macromolecular substrates, thrombin cannot be considered a uniquely specific enzyme. However, unlike the pancreatic serine proteases, it exhibits for each given substrate a remarkably narrow specificity by cleaving only a very limited number of peptide bonds. Attempts to establish the molecular bases of thrombin specificity have generated a great deal of research in the past years. Its amino acid sequence has been determined in both the bovine5 and human6 species allowing comparisons with the other members of the serine protease family.’.’ Systematic mapping of the active and construction of computer-generated spatial models” have also provided a great deal of information. However, although thrombin has been crystallized,’ ‘J’ its exact three-dimensional structure, which would probably generate more definite elements, still remains to be elucidated. Limited proteolysis of thrombin gives rise to at least two definite derivative forms referred to as 6and y-thrombins.’p’6 In sharp contrast to a mostly preserved catalytic activity on small synthetic and some proteic substrates, these derivatives exhibit dramatic alterations in activity toward some other specific macromolecular substrates including fibrinogen. Although no physiological relevance has been demonstrated to date for these proteolytic derivatives, because of these remarkable features they have been extensively used as models in the general effort to define the structure-function relationship in the thrombin molecule. It is the purpose of this

The leukocyte chemotactic receptor FPR2, but not the closely related FPR1, is sensitive to cell-penetrating pepducins with amino acid sequences descending from the third intracellular receptor loop.

Lipidated peptides (pepducins) can activate certain G-protein coupled receptors (GPCRs) through a unique allosteric modulation mechanism involving cytosolic receptor domains. Pepducins with the amino acid sequence of the third intracellular loop of the neutrophil formyl peptide receptors (FPRs) as a common denominator were N-terminally conjugated with palmitic acid. F2Pal16, containing the 16 amino acids present in the third intracellular loop of FPR2, induced superoxide production in human neutrophils and the activity was sensitive to FPR2 antagonists. Cells over-expressing FPR2 were similarly responsive and responded with a transient increase in cytosolic calcium. No such effects were observed with the corresponding FPR1 pepducin. The peptide alone, lacking palmitic acid, did not activate neutrophils. A ten amino acid long pepducin F2Pal10, that was a more potent neutrophil activator than F2Pal16, was used for amino acid substitution studies. The sequences of FPR1 and FPR2 in the third intracellular loop differ by only two amino acids, and a pepducin with the FPR2-specific K231 replaced by the FPR1-specific Q231 lost all activity. The active F2Pal10 pepducin also triggered a response in cells expressing a mutated FPR2 with the third intracellular loop identical to that of FPR1. The data presented suggest that the same signaling pathways are activated when the signaling cascade is initiated by a classical receptor agonist (outside-in signaling) and when signaling starts on the cytosolic side of the membrane by a pepducin (inside-in signaling). A fundamental difference is also disclosed between the two neutrophil FPRs regarding their sensitivities to third intracellular loop pepducins.

Structural Characterization and Inhibitory Profile of Formyl Peptide Receptor 2 Selective Peptides Descending from a PIP2-Binding Domain of Gelsolin

The neutrophil formyl peptide receptors, FPR1 and FPR2, play critical roles for inflammatory reactions, and receptor-specific antagonists/inhibitors can possibly be used to facilitate the resolution of pathological inflammatory reactions. A 10-aa-long rhodamine-linked and membrane-permeable peptide inhibitor (PBP10) has such a potential. This FPR2 selective inhibitor adopts a phosphatidylinositol 4,5-bisphosphate–binding sequence in the cytoskeletal protein gelsolin. A core peptide, RhB-QRLFQV, is identified that displays inhibitory effects as potent as the full-length molecule. The phosphatidylinositol 4,5-bisphosphate–binding capacity of PBP10 was not in its own sufficient for inhibition. A receptor in which the presumed cytoplasmic signaling C-terminal tail of FPR2 was replaced with that of FPR1 retained the PBP10 sensitivity, suggesting that the tail of FPR2 was not on its own critical for inhibition. This gains support from the fact that the effect of cell-penetrating lipopeptide (a pepducin), suggested to act primarily through the third intracellular loop of FPR2, was significantly inhibited by PBP10. The third intracellular loops of FPR1 and FPR2 differ in only two amino acids, but an FPR2 mutant in which these two amino acids were replaced by those present in FPR1 retained the PBP10 sensitivity. In summary, we conclude that the inhibitory activity on neutrophil function of PBP10 is preserved in the core sequence RhB-QRLFQV and that neither the third intracellular loop of FPR2 nor the cytoplasmic tail of the receptor alone is responsible for the specific inhibition.

House dust mite allergen activates human eosinophils via formyl peptide receptor and formyl peptide receptor-like 1.

The objective was to evaluate which receptors house dust mite (HDM) and birch pollen extracts engage to activate human eosinophils. Chemotaxis and degranulation were studied in eosinophils pretreated with pertussis toxin and other antagonists of G protein‐coupled receptors, e.g. the formyl peptide receptor (FPR), CC chemokine receptor 3 (CCR3) and leukotriene receptor B4 (LTB4R). Inhibition of the FPR as well as desensitization of the receptor rendered eosinophils anergic to activation by the allergens. Blockade of CCR3 or LTB4R did not affect eosinophilic reactivity. It was determined by PCR that human eosinophils express the FPR family members FPR and FPR‐like 1 (FPRL1). HDM, unlike birch pollen, evoked calcium fluxes in HL‐60 cells transfected with FPR or FPRL1. Although both allergens gave rise to calcium transients in neutrophils, which also express FPR and FPRL1, only the HDM response was decreased by the FPR antagonist. Moreover, neutrophils migrated toward HDM but not to birch pollen. Eosinophils pretreated with inhibitors of MAPK p38, ERK1/2 or protein kinase C exhibited diminished responsiveness to the aeroallergens. This study indicates that FPR and FPRL1 mediate the activation of eosinophils by HDM, whereas birch pollen employs other pathways shared with FPR to activate human eosinophils.

Injection of Pseudomonas aeruginosa Exo toxins into host cells can be modulated by host factors at the level of translocon assembly and/or activity.

Pseudomonas aeruginosa type III secretion apparatus exports and translocates four exotoxins into the cytoplasm of the host cell. The translocation requires two hydrophobic bacterial proteins, PopB and PopD, that are found associated with host cell membranes following infection. In this work we examined the influence of host cell elements on exotoxin translocation efficiency. We developed a quantitative flow cytometry based assay of translocation that used protein fusions between either ExoS or ExoY and the ß-lactamase reporter enzyme. In parallel, association of translocon proteins with host plasma membranes was evaluated by immunodetection of PopB/D following sucrose gradient fractionation of membranes. A pro-myelocytic cell line (HL-60) and a pro-monocytic cell line (U937) were found resistant to toxin injection even though PopB/D associated with host cell plasma membranes. Differentiation of these cells to either macrophage- or neutrophil-like cell lines resulted in injection-sensitive phenotype without significantly changing the level of membrane-inserted translocon proteins. As previous in vitro studies have indicated that the lysis of liposomes by PopB and PopD requires both cholesterol and phosphatidyl-serine, we first examined the role of cholesterol in translocation efficiency. Treatment of sensitive HL-60 cells with methyl-ß-cyclodextrine, a cholesterol-depleting agent, resulted in a diminished injection of ExoS-Bla. Moreover, the PopB translocator was found in the membrane fraction, obtained from sucrose-gradient purifications, containing the lipid-raft marker flotillin. Examination of components of signalling pathways influencing the toxin injection was further assayed through a pharmacological approach. A systematic detection of translocon proteins within host membranes showed that, in addition to membrane composition, some general signalling pathways involved in actin polymerization may be critical for the formation of a functional pore. In conclusion, we provide new insights in regulation of translocation process and suggest possible cross-talks between eukaryotic cell and the pathogen at the level of exotoxin translocation.

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.