Enhanced Immunoaffinity Purification of Human Neutrophil Flavocytochrome B for Structure Determination by Electron Microscopy.

Determination of the structure of human neutrophil (PMN) flavocytochrome b (Cytb) is a necessary step for the understanding of the structure-function essentials of NADPH oxidase activity. This understanding is crucial for structure-driven therapeutic approaches addressing control of inflammation and infection. Our work on purification and sample preparation of Cytb has facilitated progress toward the goal of structure determination. Here we describe exploiting immunoaffinity purification of Cytb for initial examination of its size and shape by a combination of classical and cryoelectron microscopic (EM) methods. For these evaluations, we used conventional negative-stain transmission electron microscopy (TEM) to examine both detergent-solubilized Cytb as single particles and Cytb in phosphatidylcholine reconstituted membrane vesicles as densely packed random, partially ordered, and subcrystalline arrays. In preliminary trials, we also examined single particles by cryoelectron microscopy (cryoEM) methods. We conclude that Cytb in detergent and reconstituted in membrane is a relatively compact, symmetrical protein of about 100 Å in maximum dimension. The negative stain, preliminary cryoEM, and crude molecular models suggest that the protein is probably a heterotetramer of two p22phox and gp91phox subunits in both detergent micelles and membrane vesicles. This exploratory study also suggests that high-resolution 2D electron microscopic approaches may be accessible to human material collected from single donors.

Formyl Met-Leu-Phe-Stimulated FPR1 Phosphorylation in Plate-Adherent Human Neutrophils: Enhanced Proteolysis but Lack of Inhibition by Platelet-Activating Factor.

N-formyl-Met-Leu-Phe (fMLF) is a model PAMP/DAMP driving human PMN to sites of injury/infection utilizing the GPCR, FPR1. We examined a microtiter plate format for measurement of FPR1 phosphorylation in adherent PMN at high densities and found that a new phosphosensitive FPR1 fragment, 25K-FPR1, accumulates in SDS-PAGE extracts. 25K-FPR1 is fully inhibited by diisopropylfluorophosphate PMN pretreatment but is not physiologic, as its formation failed to be significantly perturbed by ATP depletion, time and temperature of adherence, or adherence mechanism. 25K-FPR1 was minimized by extracting fMLF-exposed PMN in lithium dodecylsulfate at 4°C prior to reduction/alkylation. After exposure of adherent PMN to a 5 log range of PAF before or after fMLF, unlike in suspension PMN, no inhibition of fMLF-induced FPR1 phosphorylation was observed. However, PAF induced the release of 40% of PMN lactate dehydrogenase, implying significant cell lysis. We infer that PAF-induced inhibition of fMLF-dependent FPR1 phosphorylation observed in suspension PMN does not occur in the unlysed adherent PMN. We speculate that although the conditions of the assay may induce PAF-stimulated necrosis, the cell densities on the plates may approach levels observed in inflamed tissues and provide for an explanation of PAF's divergent effects on FPR1 phosphorylation as well as PMN function.

Human neutrophil formyl peptide receptor phosphorylation and the mucosal inflammatory response.

Bacterial/mitochondrial fMLF analogs bind FPR1, driving accumulation/activation of PMN at sites of infection/injury, while promoting wound healing in epithelia. We quantified levels of UFPR1 and TFPR1 in isolated PMN by use of phosphosensitive NFPRb and phosphorylation-independent NFPRa antibodies. UFPR1 and total TFPR were assessed inflamed mucosa, observed in human IBD. In isolated PMN after fMLF stimulation, UFPR1 declined 70% ((fMLF)EC50 = 11 ± 1 nM; t1/2 = 15 s) and was stable for up to 4 h, whereas TFPR1 changed only slightly. Antagonists (tBoc-FLFLF, CsH) and metabolic inhibitor NaF prevented the fMLF-dependent UFPR1 decrease. Annexin A1 fragment Ac2-26 also induced decreases in UFPR1 ((Ac2-26)EC50 ∼ 3 µM). Proinflammatory agents (TNF-α, LPS), phosphatase inhibitor (okadaic acid), and G-protein activator (MST) modestly increased (fMLF)EC50, 2- to 4-fold, whereas PTX, Ca(2+) chelators (EGTA/BAPTA), H2O2, GM-CSF, ENA-78, IL-1RA, and LXA4 had no effect. Aggregation-inducing PAF, however, strongly inhibited fMLF-stimulated UFPR1 decreases. fMLF-driven PMN also demonstrated decreased UFPR1 after traversing monolayers of cultured intestinal epithelial cells, as did PMN in intestinal mucosal samples, demonstrating active inflammation from UC patients. Total TFPR remained high in PMN within inflamed crypts, migrating through crypt epithelium, and in the lamina propria-adjoining crypts, but UFPR1 was only observed at some peripheral sites on crypt aggregates. Loss of UFPR1 in PMN results from C-terminal S/T phosphorylation. Our results suggest G protein-insensitive, fMLF-dependent FPR1 phosphorylation in isolated suspension PMN, which may manifest in fMLF-driven transmigration and potentially, in actively inflamed tissues, except at minor discrete surface locations of PMN-containing crypt aggregates.

Affinity purification and reconstitution of human phagocyte flavocytochrome B for detection of conformational dynamics in the membrane.

Human flavocytochrome b (Cyt b) is the core electron transferase of the NADPH oxidase in phagocytes and a number of other cell types. The oxidase complex generates superoxide, initiating production of a cascade of reactive oxygen species critical for the killing of infectious agents. Many fundamental questions still remain concerning its structural dynamics and electron transfer mechanisms. In particular, Cyt b structure/function correlates in the membrane have been relatively unstudied. In order to facilitate the direct analysis of Cyt b structural dynamics in the membrane, the following method provides rapid and efficient procedures for the affinity purification of Cyt b from isolated neutrophil membrane fractions and its functional reconstitution in purified lipid preparations. The protocol presented here contains some new optimized procedures that will facilitate Cyt b isolation and reconstitution. Additional methods are presented that facilitate examination of conformational dynamics of the membrane reconstituted purified Cyt b by fluorescence resonance energy transfer (FRET) as measured by steady-state and lifetime fluorescence techniques.

Identification of C-terminal phosphorylation sites of N-formyl peptide receptor-1 (FPR1) in human blood neutrophils.

Accumulation, activation, and control of neutrophils at inflammation sites is partly driven by N-formyl peptide chemoattractant receptors (FPRs). Occupancy of these G-protein-coupled receptors by formyl peptides has been shown to induce regulatory phosphorylation of cytoplasmic serine/threonine amino acid residues in heterologously expressed recombinant receptors, but the biochemistry of these modifications in primary human neutrophils remains relatively unstudied. FPR1 and FPR2 were partially immunopurified using antibodies that recognize both receptors (NFPRa) or unphosphorylated FPR1 (NFPRb) in dodecylmaltoside extracts of unstimulated and N-formyl-Met-Leu-Phe (fMLF) + cytochalasin B-stimulated neutrophils or their membrane fractions. After deglycosylation and separation by SDS-PAGE, excised Coomassie Blue-staining bands (∼34,000 Mr) were tryptically digested, and FPR1, phospho-FPR1, and FPR2 content was confirmed by peptide mass spectrometry. C-terminal FPR1 peptides (Leu(312)-Arg(322) and Arg(323)-Lys(350)) and extracellular FPR1 peptide (Ile(191)-Arg(201)) as well as three similarly placed FPR2 peptides were identified in unstimulated and fMLF + cytochalasin B-stimulated samples. LC/MS/MS identified seven isoforms of Ala(323)-Lys(350) only in the fMLF + cytochalasin B-stimulated sample. These were individually phosphorylated at Thr(325), Ser(328), Thr(329), Thr(331), Ser(332), Thr(334), and Thr(339). No phospho-FPR2 peptides were detected. Cytochalasin B treatment of neutrophils decreased the sensitivity of fMLF-dependent NFPRb recognition 2-fold, from EC50 = 33 ± 8 to 74 ± 21 nM. Our results suggest that 1) partial immunopurification, deglycosylation, and SDS-PAGE separation of FPRs is sufficient to identify C-terminal FPR1 Ser/Thr phosphorylations by LC/MS/MS; 2) kinases/phosphatases activated in fMLF/cytochalasin B-stimulated neutrophils produce multiple C-terminal tail FPR1 Ser/Thr phosphorylations but have little effect on corresponding FPR2 sites; and 3) the extent of FPR1 phosphorylation can be monitored with C-terminal tail FPR1-phosphospecific antibodies.

The leukocyte chemotactic receptor FPR1 is functionally expressed on human lens epithelial cells.

BACKGROUND: Lens degeneration in Fpr1(-/-) mice prompted us to search for functional FPR1 expression directly on lens epithelial cells. RESULTS: FPR1 is functionally expressed on human lens epithelial cells but has atypical properties compared with hematopoietic cell FPR1. CONCLUSION: Lens epithelial cell FPR1 may be involved in development and maintenance of the lens. SIGNIFICANCE: This is the first link between non-hematopoietic expression of FPR1 and an ophthalmologic phenotype. Formyl peptide receptor 1 (FPR1) is a G protein-coupled chemoattractant receptor expressed mainly on leukocytes. Surprisingly, aging Fpr1(-/-) mice develop spontaneous lens degeneration without inflammation or infection (J.-L. Gao et al., manuscript in preparation). Therefore, we hypothesized that FPR1 is functionally expressed directly on lens epithelial cells, the only cell type in the lens. Consistent with this, the human fetal lens epithelial cell line FHL 124 expressed FPR1 mRNA and was strongly FPR1 protein-positive by Western blot and FACS. Competition binding using FPR1 ligands N-formyl-Nle-Leu-Phe-Nle-Tyr-Lys (Nle = Norleucine), formylmethionylleucylphenylalanine, and peptide W revealed the same profile for FHL 124 cells, neutrophils, and FPR1-transfected HEK 293 cells. Saturation binding with fluorescein-labeled N-formyl-Nle-Leu-Phe-Nle-Tyr-Lys revealed ~2500 specific binding sites on FHL-124 cells (K(D) ~ 0.5 nm) versus ~40,000 sites on neutrophils (K(D) = 3.2 nm). Moreover, formylmethionylleucylphenylalanine induced pertussis toxin-sensitive Ca(2+) flux in FHL 124 cells, consistent with classic G(i)-mediated FPR1 signaling. FHL 124 cell FPR1 was atypical in that it resisted agonist-induced internalization. Expression of FPR1 was additionally supported by detection of the intact full-length open reading frame in sequenced cDNA from FHL 124 cells. Thus, FHL-124 cells express functional FPR1, which is consistent with a direct functional role for FPR1 in the lens, as suggested by the phenotype of Fpr1 knock-out mice.

Anionic lipid-induced conformational changes in human phagocyte flavocytochrome b precede assembly and activation of the NADPH oxidase complex.

Phagocyte NADPH oxidases generate superoxide at high rates in defense against infectious agents, a process regulated by second messenger anionic lipids using incompletely understood mechanisms. We reconstituted the catalytic core of the human neutrophil NADPH oxidase, flavocytochrome b (Cyt b) in 99% phosphatidylcholine vesicles in order to correlate anionic lipid-dependent conformational changes in membrane-bound Cyt b and oxidase activity. The anionic lipid 10:0 phosphatidic acid (10:0 PA) specifically induced conformational changes in Cyt b as measured by a combination of fluorescence resonance energy transfer methods and size exclusion chromatography. The fluorescence lifetime of a complex between Cyt b and Cascade Blue-derivatized anti-p22(phox) antibody (CCB-CS9), increased after exposure to 10:PA by ∼50% of the change observed when the complex is dissociated, indicating a structural rearrangement of p22(phox) and/or the Cyt b heme prosthetic groups. Half of the quenching relaxation occurred at 10:0 PA concentrations permissive to less than 10% full NADPH oxidase activity, but saturated near the saturation in activity in a matched cell-free oxidase assay. We conclude that anionic lipids modulate the conformation of Cyt b in the membrane and suggest they may serve to modulate the structure of Cyt b as a control mechanism for the NADPH oxidase.

Antigen-antibody interface properties: composition, residue interactions, and features of 53 non-redundant structures.

The structures of protein antigen-antibody (Ag-Ab) interfaces contain information about how Ab recognize Ag as well as how Ag are folded to present surfaces for Ag recognition. As such, the Ab surface holds information about Ag folding that resides with the Ab-Ag interface residues and how they interact. In order to gain insight into the nature of such interactions, a data set comprised of 53 non-redundant 3D structures of Ag-Ab complexes was analyzed. We assessed the physical and biochemical features of the Ag-Ab interfaces and the degree to which favored interactions exist between amino acid residues on the corresponding interface surfaces. Amino acid compositional analysis of the interfaces confirmed the dominance of TYR in the Ab paratope-containing surface (PCS), with almost two fold greater abundance than any other residue. Additionally TYR had a much higher than expected presence in the PCS compared to the surface of the whole antibody (defined as the occurrence propensity), along with aromatics PHE, TRP, and to a lesser degree HIS and ILE. In the Ag epitope-containing surface (ECS), there were slightly increased occurrence propensities of TRP and TYR relative to the whole Ag surface, implying an increased significance over the compositionally most abundant LYS>ASN>GLU>ASP>ARG. This examination encompasses a large, diverse set of unique Ag-Ab crystal structures that help explain the biological range and specificity of Ag-Ab interactions. This analysis may also provide a measure of the significance of individual amino acid residues in phage display analysis of Ag binding.

Role of putative second transmembrane region of Nox2 protein in the structural stability and electron transfer of the phagocytic NADPH oxidase.

Flavocytochrome b(558) (cytb) of phagocytes is a heterodimeric integral membrane protein composed of two subunits, p22(phox) and gp91(phox). The latter subunit, also known as Nox2, has a cytosolic C-terminal "dehydrogenase domain" containing FAD/NADPH-binding sites. The N-terminal half of Nox2 contains six predicted transmembrane α-helices coordinating two hemes. We studied the role of the second transmembrane α-helix, which contains a "hot spot" for mutations found in rare X(+) and X(-) chronic granulomatous disease. By site-directed mutagenesis and transfection in X-CGD PLB-985 cells, we examined the functional and structural impact of seven missense mutations affecting five residues. P56L and C59F mutations drastically influence the level of Nox2 expression indicating that these residues are important for the structural stability of Nox2. A53D, R54G, R54M, and R54S mutations do not affect spectral properties of oxidized/reduced cytb, oxidase complex assembly, FAD binding, nor iodonitrotetrazolium (INT) reductase (diaphorase) activity but inhibit superoxide production. This suggests that Ala-53 and Arg-54 are essential in control of electron transfer from FAD. Surprisingly, the A57E mutation partially inhibits FAD binding, diaphorase activity, and oxidase assembly and affects the affinity of immunopurified A57E cytochrome b(558) for p67(phox). By competition experiments, we demonstrated that the second transmembrane helix impacts on the function of the first intracytosolic B-loop in the control of diaphorase activity of Nox2. Finally, by comparing INT reductase activity of immunopurified mutated and wild type cytb under aerobiosis versus anaerobiosis, we showed that INT reduction reflects the electron transfer from NADPH to FAD only in the absence of superoxide production.

Invariant local conformation in p22phox p.Y72H polymorphisms suggested by mass spectral analysis of crosslinked human neutrophil flavocytochrome b.

The NADPH oxidase of phagocytic leukocytes generates superoxide that plays a critical role in innate immunity and inflammatory responses. The integral membrane protein flavocytochrome b (Cyt b, a.k.a. cytochrome b(558/559)) is the catalytic core of the complex and serves as a prototype for homologs important in regulating signaling networks in a wide variety of animal and plant cells. Our analysis identifies a naturally-occurring Tyr72/His72 polymorphism (p.Y72H) in the p22(phox) subunit of Cyt b at the protein level that has been recognized at the nucleotide level (c.214T > C, formerly C242T) and implicated in cardiovascular disease. In the present study, Cyt b was isolated from human neutrophils and reacted with chemical crosslinkers for subsequent structure analysis by MALDI mass spectrometry. Following mild chemical modification of Cyt b with two pairs of isotopically-differentiated lysine crosslinkers: BS(2)G-d(0)/d(4) and BS(3)-d(0)/d(4), the reaction mixtures were digested with trypsin and purified on C(18)ZipTips to generate samples for mass analysis. MALDI analysis of tryptic digests from each of the above reactions revealed a series of masses that could be assigned to p22(phox) residues 68-85, assuming an intra-molecular crosslink between Lys71 and Lys78. In addition to the 30 ppm mass accuracy obtained with internal mass calibration, increased confidence in the assignment of the crosslinks was provided by the presence of the diagnostic mass patterns resulting from the isotopically-differentiated crosslinking reagent pairs and the Tyr72/His72 p22(phox) polymorphisms in the crosslinked peptides. This work identifies a novel, low-resolution distance constraint in p22(phox) and suggests that the medically-relevant p.Y72H polymorphism has an invariant structural motif in this region. Because position 72 in p22(phox) lies outside regions identified as interactive with other oxidase components, the structural invariance also provides additional support for maturational differences as the source of the wide variation in observed reactive oxygen species production by cells expressing p.Y72H.

Characterization of superoxide overproduction by the D-Loop(Nox4)-Nox2 cytochrome b(558) in phagocytes-Differential sensitivity to calcium and phosphorylation events.

NADPH oxidase is a crucial element of phagocytes involved in microbicidal mechanisms. It becomes active when membrane-bound cytochrome b(558), the redox core, is assembled with cytosolic p47(phox), p67(phox), p40(phox), and rac proteins to produce superoxide, the precursor for generation of toxic reactive oxygen species. In a previous study, we demonstrated that the potential second intracellular loop of Nox2 was essential to maintaining NADPH oxidase activity by controlling electron transfer from FAD to O(2). Moreover, replacement of this loop by the Nox4-D-loop (D-loop(Nox4)-Nox2) in PLB-985 cells induced superoxide overproduction. In the present investigation, we demonstrated that both soluble and particulate stimuli were able to induce this superoxide overproduction. Superoxide overproduction was also observed after phosphatidic acid activation in a purified cell-free-system assay. The highest oxidase activity was obtained after ionomycin and fMLF stimulation. In addition, enhanced sensitivity to Ca(2+) influx was shown by thapsigargin, EDTA, or BTP2 treatment before fMLF activation. Mutated cytochrome b(558) was less dependent on phosphorylation triggered by ERK1/2 during fMLF or PMA stimulation and by PI3K during OpZ stimulation. The superoxide overproduction of the D-loop(Nox4)-Nox2 mutant may come from a change of responsiveness to intracellular Ca(2+) level and to phosphorylation events during oxidase activation. Finally the D-loop(Nox4)-Nox2-PLB-985 cells were more effective against an attenuated strain of Pseudomonas aeruginosa compared to WT-Nox2 cells. The killing mechanism was biphasic, an early step of ROS production that was directly bactericidal, and a second oxidase-independent step related to the amount of ROS produced in the first step.

New insight into the Nox4 subcellular localization in HEK293 cells: first monoclonal antibodies against Nox4.

Nox4, a member of Nox family of NADPH oxidase expressed in nonphagocytic cells, is a major source of reactive oxygen species in many cell types. But understanding of the role of Nox4 in the production of ROS and of regulation mechanism of oxidase activity is largely unknown. This study reports for the first time the generation and characterization of 5 mAbs against a recombinant Nox4 protein (AA: 206-578). Among 5 novel mAbs, 3 mAbs (8E9, 5F9, 6B11) specifically recognized Nox4 protein in HEK293 transfected cells or human kidney cortex by western blot analysis; mAb 8E9 reacted with intact tet-induced T-REx™ Nox4 cells in FACS studies. The other 2 mAbs 10B4 and 7C9 were shown to have a very weak reactivity after purification. Immunofluorescence confocal microscopy showed that Nox4 localized not only in the perinuclear and endoplasmic reticulum regions but also at the plasma membrane of the cells which was further confirmed by TIRF-microscopy. Epitope determination showed that mAb 8E9 recognizes a region on the last extracellular loop of Nox4, while mAbs 6B11 and 5F9 are directed to its cytosolic tail. Contrary to mAb 6B11, mAb 5F9 failed to detect Nox4 at the plasma membrane. Cell-free oxidase assays demonstrated a moderate but significant inhibition of constitutive Nox4 activity by mAbs 5F9 and 6B11. In conclusion, 5 mAbs raised against Nox4 were generated for the first time. 3 of them will provide powerful tools for a structure/function relationship of Nox4 and for physiopathological investigations in humans.

Agonist-dependent phosphorylation of the formyl peptide receptor is regulated by the membrane proximal region of the cytoplasmic tail.

Formyl peptide receptor (FPR) is a chemoattractant G protein-coupled receptor (GPCR) involved in the innate immune response against bacteria. Receptor activation is terminated by receptor phosphorylation of two serine- and threonine-rich regions located in the distal half of the cytoplasmic tail. In this study we show that introduction of an amino acid with a bulky side chain (leucine or glutamine) adjacent to a single leucine, L320, in the membrane-proximal half of the cytoplasmic tail, significantly enhanced receptor phosphorylation, beta-arrestin1/2 translocation, and receptor endocytosis, without affecting G(i)-mediated ERK1/2 activation and release of intracellular calcium. In addition, the point mutations resulted in diminished susceptibility to trypsin, suggesting a conformation different from that of wild type FPR. Alignment of the FPR sequence with the rhodopsin sequence showed that L320 resides immediately C-terminal of an amphipathic region that in rhodopsin forms helix 8. Deletion of seven amino acids (Delta309-315) from the predicted helix 8 of FPR (G307-S319) caused reduced cell signaling as well as defects in receptor phosphorylation, beta-arrestin1/2 translocation and endocytosis. Thus, the amino acid content in the N-terminal half of the cytoplasmic tail influences the structure and desensitization of FPR.

New p22-phox monoclonal antibodies: identification of a conformational probe for cytochrome b 558.

The phagocyte NADPH oxidase, belonging to the NADPH oxidase family (Nox), is dedicated to the production of bactericidal reactive oxygen species. The enzyme catalytic center is the cytochrome b(558), formed by 2 subunits, Nox2 (gp91-phox) and p22-phox. Cytochrome b(558) activation results from a conformational change induced by cytosolic regulatory proteins (p67-phox, p47-phox, p40-phox and Rac). The catalytic subunit is Nox2, while p22-phox is essential for both Nox2 maturation and the membrane anchorage of regulatory proteins. Moreover, it has been shown to be necessary for novel Nox activity. In order to characterize both p22-phox topology and cytochrome b(558) conformational change, 6 monoclonal antibodies were produced against purified cytochrome b(558). Phage display epitope mapping combined with a truncation analysis of recombinant p22-phox allowed the identification of epitope regions. Some of these antibodies almost completely inhibited in vitro reconstituted NADPH oxidase activity. Data analysis identified antibodies that recognized epitopes involved in either Nox2 maturation or Nox2 activation. Moreover, flow cytometry analysis and confocal microscopy performed on stimulated neutrophils showed that the monoclonal antibody 12E6 bound preferentially active cytochrome b(558). These monoclonal antibodies provided novel and unique probes to investigate maturation, activation and activity, not only of Nox2 but also of novel Nox.

Mutational analysis reveals distinct features of the Nox4-p22 phox complex.

The integral membrane protein p22(phox) forms a heterodimeric enzyme complex with NADPH oxidases (Noxs) and is required for their catalytic activity. Nox4, a Nox linked to cardiovascular disease, angiogenesis, and insulin signaling, is unique in its ability to produce hydrogen peroxide constitutively. To date, p22(phox) constitutes the only identified regulatory component for Nox4 function. To delineate structural elements in p22(phox) essential for formation and localization of the Nox4-p22(phox) complex and its enzymatic function, truncation and point mutagenesis was used. Human lung carcinoma cells served as a heterologous expression system, since this cell type is p22(phox)-deficient and promotes cell surface expression of the Nox4-p22(phox) heterodimer. Expression of p22(phox) truncation mutants indicates that the dual tryptophan motif contained in the N-terminal amino acids 6-11 is essential, whereas the C terminus (amino acids 130-195) is dispensable for Nox4 activity. Introduction of charged residues in domains predicted to be extracellular by topology modeling was mostly tolerated, whereas the exchange of amino acids in predicted membrane-spanning domains caused loss of function or showed distinct differences in p22(phox) interaction with various Noxs. For example, the substitution of tyrosine 121 with histidine in p22(phox), which abolished Nox2 and Nox3 function in vivo, preserved Nox4 activity when expressed in lung cancer cells. Many of the examined p22(phox) mutations inhibiting Nox1 to -3 maturation did not alter Nox4-p22(phox) association, further accenting the differences between Noxs. These studies highlight the distinct interaction of the key regulatory p22(phox) subunit with Nox4, a feature which could provide the basis for selective inhibitor development.

Single-step immunoaffinity purification and functional reconstitution of human phagocyte flavocytochrome b.

Human neutrophil flavocytochrome b (Cyt b) is a heterodimeric, integral membrane protein that generates high levels of superoxide in the multisubunit NADPH oxidase complex. Since Cyt b is currently isolated in limited quantities, improved methods for purification from low levels of starting membranes (from both neutrophils and other expressing cell types) are important for the analysis of structure and catalytic mechanism. In the present study, the epitope-mapped monoclonal antibody CS9 was coupled to Sepharose beads and used as an affinity matrix for single-step immunoaffinity purification of Cyt b. Following solubilization of both human neutrophil and PLB-985 membrane fractions in the nonionic detergent octylglucoside, Cyt b was absorbed on the CS9-Sepharose affinity matrix and purified protein was eluted under non-denaturing conditions with an epitope-mimicking peptide. The high efficiency of this isolation procedure allowed Cyt b to be reproducibly purified from readily obtainable levels of starting membrane fractions (9x10(8) cell equivalents of neutrophil membranes and 2x10(9) cell equivalents of PLB-985 membranes). Since Cyt b could be affinity-purified in the detergent octylglucoside, high-level functional reconstitution was carried out directly on elution fractions by simple addition of solubilized phospholipid and subsequent dialysis for detergent removal. To our knowledge, this study describes the most efficient method for generating purified, functionally-reconstituted Cyt b and should facilitate analyses that require a highly-defined NADPH oxidase system.

Formyl peptide receptor-1 activation enhances intestinal epithelial cell restitution through phosphatidylinositol 3-kinase-dependent activation of Rac1 and Cdc42.

Inflammatory disorders of the gastrointestinal tract result in the breakdown of the intestinal epithelial barrier in the form of erosion and ulceration. To reestablish the epithelial barrier, the epithelium must efficiently migrate to reseal wounds. Numerous signaling cascades are involved in the induction and regulation of this complex process. N-formyl peptide receptors comprise a group of Gi-coupled receptors that regulate innate immune responses. Previously, we identified the expression of functional N-formyl peptide receptors in model SK-CO15 intestinal epithelial cells and observed a role for activation of these receptors in regulating cellular invasive behavior. In these studies, we performed formyl peptide receptor-1 (FPR) localization and evaluated its role in regulating intestinal epithelial cell wound closure. Immunolocalization studies using a recently developed specific monoclonal anti-FPR Ab demonstrated its localization along the lateral membrane of crypt epithelial cells in normal human colonic epithelium. In vitro studies using the classical FPR agonist fMLF showed that FPR activation significantly enhances model intestinal epithelial cell restitution and that FPR localized along actin filaments in lamellipodial and filopodial extrusions. The increase in cell migration was associated with activation of PI3K, Rac1, and Cdc42. Pharmacologic inhibition of PI3K activity abrogated the fMLF-induced increase in wound closure and activation of both Rac1 and Cdc42. Inhibition of Rac1 and Cdc42 using pharmacologic inhibitors and dominant negative mutants also inhibited the fMLF-induced increase in cell migration. Taken together, theses results support a novel role for FPR stimulation in enhancing intestinal epithelial cell restitution through PI3K-dependent activation of Rac1 and Cdc42.

Characterization of surface structure and p47phox SH3 domain-mediated conformational changes for human neutrophil flavocytochrome b.

The heterodimeric, integral membrane protein flavocytochrome b (Cyt b) is the catalytic core of the phagocyte NADPH oxidase and generates superoxide which plays a critical role in host defense. To better define the activation of superoxide production by this multisubunit enzyme complex, Cyt b-specific monoclonal antibodies (mAbs) and the p47phox SH3 domains (p47SH3AB) were used in the present study as probes to map surface structure and conformational dynamics in human neutrophil Cyt b. In pull-down and co-immunoprecipitation studies with detergent-solubilized Cyt b, the oxidase-inhibitory mAb CS9 was shown to share an overlapping binding site with p47SH3AB on the C-terminal region of the p22phox subunit. Similar studies demonstrated a surprising lack of overlap between the mAb 44.1 and CS9/p47SH3AB binding sites, and they indicated that the oxidase-inhibitory mAb NL7 binds a region physically separated from the p22phox C-terminal domain. Resonance energy transfer and size exclusion chromatography confirmed the above results for functionally reconstituted Cyt b and provided evidence that binding of both mAb CS9 and p47SH3AB altered the conformation of Cyt b. Further support that binding of the p47phox SH3 domains modulates the structure of Cyt b was obtained using a cell-free assay system where p47SH3AB enhanced superoxide production in the presence of a p67phox (1-212)-Rac1(Q61L) fusion protein. Taken together, this study further characterizes the structure of human neutrophil Cyt b in both detergent micelles and reconstituted membrane bilayers, and it provides evidence that the cytosolic regulatory subunit p47phox modulates the conformation of Cyt b (in addition to serving as an adapter protein) during oxidase activation.

C-terminal tail phosphorylation of N-formyl peptide receptor: differential recognition of two neutrophil chemoattractant receptors by monoclonal antibodies NFPR1 and NFPR2.

The N-formyl peptide receptor (FPR), a G protein-coupled receptor that binds proinflammatory chemoattractant peptides, serves as a model receptor for leukocyte chemotaxis. Recombinant histidine-tagged FPR (rHis-FPR) was purified in lysophosphatidyl glycerol (LPG) by Ni(2+)-NTA agarose chromatography to >95% purity with high yield. MALDI-TOF mass analysis (>36% sequence coverage) and immunoblotting confirmed the identity as FPR. The rHis-FPR served as an immunogen for the production of 2 mAbs, NFPR1 and NFPR2, that epitope map to the FPR C-terminal tail sequences, 305-GQDFRERLI-313 and 337-NSTLPSAEVE-346, respectively. Both mAbs specifically immunoblotted rHis-FPR and recombinant FPR (rFPR) expressed in Chinese hamster ovary cells. NFPR1 also recognized recombinant FPRL1, specifically expressed in mouse L fibroblasts. In human neutrophil membranes, both Abs labeled a 45-75 kDa species (peak M(r) approximately 60 kDa) localized primarily in the plasma membrane with a minor component in the lactoferrin-enriched intracellular fractions, consistent with FPR size and localization. NFPR1 also recognized a band of M(r) approximately 40 kDa localized, in equal proportions to the plasma membrane and lactoferrin-enriched fractions, consistent with FPRL1 size and localization. Only NFPR2 was capable of immunoprecipitation of rFPR in detergent extracts. The recognition of rFPR by NFPR2 is lost after exposure of cellular rFPR to f-Met-Leu-Phe (fMLF) and regained after alkaline phosphatase treatment of rFPR-bearing membranes. In neutrophils, NFPR2 immunofluorescence was lost upon fMLF stimulation. Immunoblotting approximately 60 kDa species, after phosphatase treatment of fMLF-stimulated neutrophil membranes, was also enhanced. We conclude that the region 337-346 of FPR becomes phosphorylated after fMLF activation of rFPR-expressing Chinese hamster ovary cells and neutrophils.

New insights into the membrane topology of the phagocyte NADPH oxidase: characterization of an anti-gp91-phox conformational monoclonal antibody.

Cytochrome b(558) is the catalytic core of the phagocyte NADPH oxidase that mediates the production of bactericidal reactive oxygen species. Cytochrome b(558) is formed by two subunits gp91-phox and p22-phox (1/1), non-covalently associated. Its activation depends on the interaction with cytosolic regulatory proteins (p67-phox, p47-phox, p40-phox and Rac) leading to an electron transfer from NADPH to molecular oxygen and to the release of superoxide anions. Several studies have suggested that the activation process was linked to a change in cytochrome b(558) conformation. Recently, we confirmed this hypothesis by isolating cytochrome b(558) in a constitutively active form. To characterize active and inactive cytochrome b(558) conformations, we produced four novel monoclonal antibodies (7A2, 13B6, 15B12 and 8G11) raised against a mixture of cytochrome b(558) purified from both resting and stimulated neutrophils. The four antibodies labeled gp91-phox and bound to both native and denatured cytochrome b(558). Interestingly, they were specific of extracellular domains of the protein. Phage display mapping combined to the study of recombinant gp91-phox truncated forms allowed the identification of epitope regions. These antibodies were then employed to investigate the NADPH oxidase activation process. In particular, they were shown to inhibit almost completely the NADPH oxidase activity reconstituted in vitro with membrane and cytosol. Moreover, flow cytometry analysis and confocal microscopy performed on stimulated neutrophils pointed out the capacity of the monoclonal antibody 13B6 to bind preferentially to the active form of cytochrome b(558). All these data suggested that the four novel antibodies are potentially powerful tools to detect the expression of cytochrome b(558) in intact cells and to analyze its membrane topology. Moreover, the antibody 13B6 may be conformationally sensitive and used as a probe for identifying the active NADPH oxidase complex in vivo.