Quantitative Analysis of Membrane Remodeling at the Phagocytic Cup

Warren L. Lee^*^,^,, David Mason^*, Alan D. Schreiber, and Sergio Grinstein^*

*Programme in Cell Biology, Hospital for Sick Children, Interdepartmental Division of Critical Care Medicine, and the Division of Respirology, Department of Medicine, University of Toronto, Toronto, Ontario, M5G 1X8 Canada; and Department of Medicine, University of Pennsylvania School of Medicine, Philadelphia, PA 19104

Submitted May 23, 2006; Revised April 16, 2007; Accepted May 7, 2007
Monitoring Editor: Ralph Isberg

ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Nascent phagosomes, which are derived from the plasma membrane,acquire microbicidal properties through multiple fusion andfission events collectively known as maturation. Here we showthat remodeling of the phagosomal membrane is apparent evenbefore sealing, particularly when large particles are ingested.Fluorescent probes targeted to the plasma membrane are clearedfrom the region lining the particle before engulfment is completed.Extensive clearance was noted for components of the inner aswell as outer monolayer of the plasmalemma. Segregation of lipidmicrodomains was ruled out as the mechanism underlying membraneremodeling, because markers residing in rafts and those thatare excluded were similarly depleted. Selective endocytosiswas also ruled out. Instead, several lines of evidence indicatethat endomembranes inserted by exocytosis at sites of ingestiondisplace the original membrane constituents from the base ofthe phagosomal cup. The Fc ${gamma}$ receptors that trigger phagocytosisremain associated with their ligands. By contrast, Src-familykinases that are the immediate effectors of receptor activationare flushed away from the cup by the incoming membranes. Togetherwith the depletion of phosphoinositides required for signaltransduction, the disengagement of receptors from their effectorsby bulk membrane remodeling provides a novel means to terminatereceptor signaling.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Phagocytosis is a specialized function of the innate immunesystem that is performed most efficiently by macrophages andneutrophils (so-called professional phagocytes). Engulfmentof invading microorganisms, foreign particles, and apoptoticbodies is initiated by engagement of specialized phagocyticreceptors. Activation of these receptors triggers polymerizationof actin and remodeling of the plasma membrane, leading to theformation of pseudopodia that ultimately grow to encircle andtrap the phagocytic target. Although many receptors are capableof mediating this process, the family of Fc ${gamma}$ receptors, whichrecognize particles opsonized with immunoglobulin G (IgG), remainsthe best studied. Clustering of Fc ${gamma}$ receptors, induced by bindingto multiple opsonic ligands on a particle, leads to phosphorylationof the Fc ${gamma}$ R immunoreceptor tyrosine-based activation motif (ITAM)by members of the Src family of kinases, followed by recruitmentof the kinase Syk. Syk activation in turn initiates a signalingcascade, including activation of phosphatidylinositol 3-kinase(PI 3-kinase) and of the small GTPases Rac and Cdc42, whichcoordinate actin remodeling (Henry et al., 2004).

Although the importance of cytoskeletal reorganization at thephagocytic cup has long been appreciated, the role of membraneremodeling has received less attention. Until recently, protrusionof membrane pseudopodia at the phagocytic cup was thought tobe mainly a passive event, reflecting pressure-induced deformationof the plasma membrane caused by the stimulated polymerizationof subjacent actin (Griffin et al., 1975). More recent data,however, suggest that actin polymerization at the phagocyticcup and pseudopod extension can be affected separately, supportingthe notion that membrane remodeling is an independent and importantcomponent of the phagocytic response (Lowry et al., 1998; Coxet al., 1999). Indeed, it is now appreciated that membrane remodelingduring phagocytosis is an active and complex process that involveslocalized pinocytosis (Botelho et al., 2002), segregation ofmembrane components into lipid rafts (Kwiatkowska et al., 2003),lateral diffusion of signaling molecules (Henry et al., 2004),and the insertion of endomembranes by focal exocytosis (Bajnoet al., 2000; Braun et al., 2004).

It is currently unclear how the combination of these eventsalters the composition of the plasma membrane, particularlythe specialized area immediately below the target particle,known as the phagocytic cup. Of particular interest is the fateof signaling molecules that are required for triggering andsubsequently terminating particle engulfment and the associatedinflammatory response. We therefore performed a quantitativeassessment of membrane remodeling at the phagocytic cup, usingmarkers of specific membrane microdomains. In addition, we analyzedseparately the behavior of the inner and outer leaflets of theplasma membrane, using selectively targeted fluorescent probesthat enabled us to perform dynamic measurements in live cells.We report the occurrence of marked changes in membrane compositionthat precede completion of phagocytosis, which vary greatlydepending on the size of the particle being internalized.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Reagents and Antibodies
Fetal bovine serum (FBS), DMEM, HEPES-buffered solution RPMI-1640(HPMI), and phosphate-buffered saline (PBS) were from Wisent(St. Bruno, Quebec, Canada). Alexa Fluor 555–conjugatedcholera toxin subunit B (recombinant), Alexa Fluor 633–conjugatedtransferrin, and FM4-64 were from Molecular Probes (Carlsbad,CA). Latex beads (3.1 or 8.3 µm in diameter) were fromBang's Laboratories (Fishers, IN). Rat anti-LAMP1 antibody (cloneID4B) was from the Developmental Hybridoma Bank. Goat anti-Lynpolyclonal antibody was from R&D Systems (Minneapolis, MN).Cy3-labeled Fab fragment of anti-mouse antibody was from JacksonImmunoResearch Laboratories (West Grove, PA). Human IgG, LY294002,and all other reagents were from Sigma Aldrich Canada (Oakville,Ontario, Canada).

DNA Constructs
The wild-type (WT) N-ethylmaleimide sensitive factor (NSF) anddominant-negative (DN) NSF constructs used in this study haveboth been described elsewhere (Coppolino et al., 2001). Briefly,DN-NSF contained a single codon mutation of glutamate at position329 to glutamine (E329Q) and was generated using site-directedmutagenesis. The activity of both WT and DN-NSF constructs hasbeen verified in vitro using an ATPase assay and transfectionof the constructs is known to result in exogenous NSF levelsthat are three times higher than the endogenous NSF levels asearly as 8 h later (Coppolino et al., 2001). Fc ${gamma}$ RIIA-CFP andgreen fluorescent protein (GFP) were constructed by cloninga cDNA of Fc ${gamma}$ RIIA into pEGFP-N1 (Clontech, Palo Alto, CA) orCFP at HindIII and SacII sites. PM-RFP was generated by digestingRFP with XhoI and BamHI and ligating the cut vector with annealedPM oligonucleotides that had been synthesized with the appropriatesticky ends using a commercial service. The GPI-yellow fluorescentprotein (YFP) construct was a gift from Dr. M. Edidin (JohnsHopkins University, Baltimore, MD). YFP-GT46 is a chimeric secretoryprotein containing a signal sequence fused to YFP, a consensusN-glycosylation site, the transmembrane domain of the LDL receptor,and the cytoplasmic tail of CD46 (Kenworthy et al., 2004). Thevectors encoding GFP-Rab5 and DN dynamin I (K44A) have beenpreviously described in Scott et al. (2005) and Damke et al.(1994), respectively. The plasmid encoding GFP-EEA1(1257-1411)was a gift from Dr. H. Stenmark (Norwegian Radium Hospital,Oslo, Norway). Kinase-dead Lyn (K275R) was a gift from Dr. J.Bolen (Bristol Myers Squibb). GFP-Sec61 was a gift from Dr.J. Brumell (Hospital for Sick Children, Toronto).

Cell Culture and Transfection
RAW264.7 cells were obtained from the American Type CultureCollection (Rockville, MD) and were grown in DMEM with 5% FBSat 37°C in 5% CO₂ under a humidified atmosphere. Transfectionswere performed using the Amaxa electroporation system (Gaithersburg,MD) following the manufacturer's guidelines, using 4 millioncells and 3 µg of cDNA per coverslip and program U14.Stable lines expressing the GPI-anchored yellow fluorescentprotein (YFP-GPI) were selected with G418 (0.5 mg/ml). Cellswere cotransfected with DN- or WT-NSF and EGFP (or RFP) in a9:1 ratio and were analyzed 8–10 h later. Immunofluorescencestaining using a polyclonal antibody, generated and kindly providedby Dr. W. Trimble (Hospital for Sick Children, Toronto), wasperformed to confirm that under these conditions greater than95% of the EGFP-positive cells ectopically expressed NSF (Coppolinoet al., 2001). Where indicated, cells were transfected withplasmids encoding dynamin I (K44A) and EGFP (5:1 ratio) andused between 24 and 48 h later. The effectiveness of the DNdynamin was confirmed by monitoring the uptake of fluorescentlylabeled transferrin.

Phagocytosis Assays and Endocytosis
Latex beads were opsonized with 3.75 mg/ml human IgG for 1 hat 37°C. Cells grown on glass coverslips were changed toprewarmed serum-free medium and were overlaid with 25 µlof opsonized latex beads and incubated at 37°C to initiatephagocytosis. In most experiments, phagocytosis was synchronizedby centrifugation of the cells at 1500 rpm for 1 min after theaddition of beads. RAW cells were pretreated with 10 µMcolchicine for 10 min or with 100 µM LY 294002 for 15min before phagocytosis.

Endocytosis at the phagocytic cup was detected by incubatingRAW cells with 10 µM FM4-64 for 30 s at 4°C then addingopsonized beads to the cells. Cells were incubated for 2.5 minat 37°C and then washed five times with cold PBS beforeimaging.

To label Fc ${gamma}$ RIIA in internal compartments, cells transfectedwith the GFP-conjugated receptor (see above) were incubatedwith 300 ng/ml anti-human Fc ${gamma}$ RIIA monoclonal Fab fragment for60 min, followed by a Cy3-conjugated secondary Fab fragment,both in the cold to prevent internalization. Cells were nextincubated at 37°C for 15 min to internalize the labeledreceptor, and the remaining surface label was removed usinga brief acid wash, as previously described (Tuma et al., 2002).Finally, opsonized beads were added to the cells for 6 min,at which point the macrophages were fixed in 4% paraformaldehydeand imaged.

Microscopy, Immunofluorescence, and Image Analysis
Analysis of the distribution and density of the membrane markerswas performed using an LSM510 laser scanning confocal microscope(Zeiss, Thornwood, NY) with a 100x oil immersion objective.Spectral separation of GFP from YFP was performed using theLSM510 Meta system. Quantitation of fluorescence was done usingImage J software (NIH) after subtracting for background.

Detection of LAMP1 in RAW cells by immunofluorescence was performedafter fixing cells in 4% paraformaldehyde, followed by permeabilizationin 0.1% Triton, blocking in 5% milk, then probing with rat anti-LAMP1(clone ID4B) at 1:100 for 1 h. After washing with PBS, sampleswere incubated with Cy3 anti-mouse antibody for 30 min, thenwashed, and mounted on slides using Dako mounting medium (Carpinteria,CA). Immunofluorescence staining of endogenous Lyn was performedas above, using ice-cold methanol as the fixative and blockingwith 5% donkey serum.

Electron Microscopy
RAW cells were preincubated with 2.2 mg/ml cationized ferritinin veronal buffer for 2.5 min at 4°C. The extracellularmedium was then changed to fresh HPMI, and opsonized beads wereadded to the cells, which were then incubated at 37°C for2.5 min. Cells were then fixed in 2% glutaraldehyde in 0.1 MSorenson's phosphate buffer, pH 7.2, for 10 min at 4°C,before fixation was continued at room temperature for at leasta further 1 h. Cells were then postfixed in 1% OsO₄ in phosphatebuffer at room temperature for 2 h, stained en bloc for 1 hwith 1% uranyl acetate in H₂O, and then dehydrated and embeddedin Epon resin. Sections were viewed using a FEI Tecnai 20 electronmicroscope (Beaverton, OR), and images were captured using aGatan Dualview camera (Pleasanton, CA).

Statistics
Unless otherwise stated, all experiments were performed at leastin triplicate. For comparisons of means, t tests were used.p < 0.05 was deemed significant.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Clearance of GPI-anchored Proteins from the Phagocytic Cup
We analyzed the fate of YFP-GPI as a measure of membrane remodelingduring formation of the phagocytic cup. We generated a lineof RAW264.7 murine macrophages stably transfected with thischimeric construct and observed its distribution before andduring phagocytosis using confocal microscopy of live cells.Consistent with earlier findings, YFP-GPI was largely foundat the plasma membrane of quiescent RAW cells, with little intracellularfluorescence. On the initiation of phagocytosis of large (8µm) opsonized latex beads, distinct membrane pseudopodscould be observed extending around the particle. Remarkably,there was an obvious clearance of YFP-GPI from the base of thephagocytic cup within minutes of particle contact, even beforethe pseudopods had fully surrounded the particle (Figure 1A).The fluorescence at the base of the cup dropped to 49 ±4% of that of the plasma membrane within 5 min after initiationof phagocytosis (mean ± SE of 30 determinations). Thispronounced and highly localized loss of fluorescence at thebase of the cup was not due to an optical artifact, as the distributionof fluorescently labeled opsonin around the surface of the latexbead was homogeneous, even in the area where YFP-GPI fluorescencewas greatly reduced (Figure 1B).

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Figure 1. Clearance of YFP-GPI from the base of the phagocytic cup. RAW264.7 macrophages stably transfected with YFP-GPI were allowed to internalize IgG-opsonized latex beads (8-µm diameter) while acquiring confocal fluorescence images. (A) Representative image acquired 1 min after engagement of the bead. (B) To rule out the possibility that the apparent clearance of YFP-GPI (indicated by arrows in A and B) is an optical artifact caused by the distinct refractive index of the bead, opsonized beads were labeled with donkey anti-human Cy3 secondary antibodies before phagocytosis. Despite clearance of YFP-GPI from the base of the phagocytic cup, the opsonin is visible continuously around the bead. For quantitation, see text. Insets show corresponding DIC images. Scale bars, 4 µm. Images are representative of over 30 cells from three experiments.

Endocytosis Occurs at the Phagocytic Cup, But Does Not Account for Clearance of YFP-GPI
The clearance of GPI-anchored proteins from the base of thephagocytic cup might be explained by localized endocytosis.Endocytosis at the cup is conceivable because neutrophils, whichare also professional phagocytes, were reported to perform activepinocytosis during phagocytosis (Botelho et al., 2002

). We devisedan assay to detect endocytosis at the cup by labeling the plasmamembrane of RAW cells with the amphiphilic fluorophore FM4–64.This solvochromic probe selectively exhibits fluorescence whenin the hydrophobic environment of the lipid bilayer, yet canbe removed from the plasma membrane by simply washing the cells.RAW cells were initially incubated with FM4-64 at 4°C, tolabel the plasmalemma while preventing endocytosis. This resultedin homogeneous labeling of the plasmalemma (not illustrated).The macrophages were then exposed to opsonized latex beads,allowing binding of the beads to Fc ${gamma}$ receptors. Phagocytosiswas then induced by sudden warming to 37°C, followed bytermination and washing of extracellular FM4-64 by repeatedwashing in the cold. Under these conditions, only dye trappedwithin sealed cellular compartments is retained. As illustratedin Figure 2A, when a brief (2.5 min) incubation at 37°Cis performed, most of the fluorescence is detected in a punctatedistribution near the base of the forming phagosome, implyingthat endocytic activity is much greater in this region thanelsewhere in the cell.

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Figure 2. Endocytosis occurs at the phagocytic cup but does not account for clearance of YFP-GPI. The impermeant dye FM4-64 (red) was added to either wild-type (A) or YFP-GPI transfected cells (B). Phagocytosis was initiated by the addition of opsonized latex beads. After 2.5 min the cells were washed repeatedly (five times) to remove any dye that had not been internalized by the cells, and images were acquired immediately. Note that no FM4-64 remains on the plasma membrane (dotted line in A, indicated by yellow arrow in A and B), whereas vesicles labeled by the dye are visible in the vicinity of the phagocytic cup (white arrow in A and B). Note also that most FM4-64–labeled vesicles in B contain little YFP-GPI (shown in green). Insets in A and B show corresponding DIC images. In C cells were transfected with the dominant negative (K44A) form of dynamin I plus soluble GFP (5:1 ratio). After allowing expression of the proteins (24–48 h) the cell membrane was labeled with fluorescent (red) B subunit of cholera toxin. Opsonized particles were then added and fluorescence was monitored by confocal microscopy. White arrows in C denote sites of cup formation, where clearance of the probe was readily apparent, whereas it was retained in the bulk membrane (yellow arrow). The dashed line shows the outline of the beads. The inset in C shows the presence of soluble GFP, used as an indicator of dynamin coexpression. Scale bars, 4 µm. Images are representative of over 30 cells from three experiments.

Two methods were used to determine whether the observed endocytosiscould account for the acute disappearance of plasmalemmal markersfrom the base of the phagosome. First, endocytosis was studiedin cells transfected with YFP-GPI (Figure 2B). As before, clearanceof YFP-GPI was noted at the base of forming phagosomes and endocyticvesicles loaded with FM4-64 were clearly discernible; however,there was little colocalization of the two probes in endocyticvesicles. The possible contribution of endocytosis was alsostudied by transfecting the cells with a DN allele of dynamin,a GTPase that is required for both clathrin-dependent and caveolarendocytosis. The effectiveness of this approach was first testedby measuring the uptake of transferrin, which in untransfectedcells is internalized via clathrin-mediated endocytosis. Asreported earlier (Damke et al., 1994

), expression of dynaminI (K44A) prevented the endocytosis of transferrin by RAW cells(not shown). Under these conditions, clearance of the plasmamembrane from the base of the phagocytic cup was still observed(Figure 2C). Although the possible existence of dynamin-independentendocytic processes cannot be excluded, these two lines of evidencejointly argue against endocytosis as the primary mechanism underlyingthe removal of membrane markers from the base of the formingphagosome.

Dynamics of Other Membrane Markers during Phagocytosis
Localized endocytosis of YFP-GPI would explain its clearancefrom the phagocytic cup only if the internalization processwere selective for this lipoprotein, as nonselective endocytosiswould reduce membrane area while leaving the net concentrationof YFP-GPI unchanged. To further analyze the mechanism of membraneremodeling, we monitored the fate of other probes as well. RAWcells were labeled with fluorescent cholera toxin B subunitbefore phagocytosis. This subunit of the toxin binds to GM1gangliosides and is widely used as a plasma membrane marker.We observed rapid and efficient clearance of fluorescent B subunitfrom the base of the phagocytic cup, even before sealing ofthe phagosome was completed (Figure 3A). In three similar experiments,only 31 ± 5% of the original plasma membrane fluorescenceremained at the cup within 5 min after initiation of phagocytosis.This finding implies that the disappearance from the cup isnot restricted to YFP-GPI. Of note, both GPI-tagged proteinsand GM1 gangliosides reside in the outer leaflet of the plasmalemma.We therefore transfected RAW cells with a marker of the innerleaflet, plasma membrane GFP (PM-GFP; Teruel et al., 1999),to ensure that the phenomenon was not limited to the outer leaflet.PM-GFP, a diacylated probe containing the N-terminal domainof Lyn, behaved in a manner similar to that described abovefor the exofacial probes, becoming depleted from the base ofthe phagocytic cup before the bead was completely internalized(Figure 3B).

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Figure 3. Clearance of membrane markers from the phagocytic cup is not due to lipid raft segregation. RAW macrophages were allowed to ingest 8-µm IgG-opsonized beads, and confocal fluorescence images were acquired 1 min after particle engagement. (A) Cells were labeled with Alexa 555–conjugated cholera toxin B-subunit before phagocytosis, as described in Materials and Methods. (B) Cells were transfected with PM-GFP. (C) Cells were transfected with YFP-GT46. Arrows denote areas where clearance of the membrane marker has begun. For quantitation, see text. Insets show corresponding DIC images. Scale bar, 2 µm. Images are representative of over 30 cells from three experiments for each condition.

Segregation of Lipid Microdomains Fails To Account for Membrane Remodeling in Phagocytosis
We next considered the possibility that the membrane remodelingwe observed might reflect lateral segregation of lipid rafts,microdomains of the plasma membrane enriched in cholesteroland sphingolipids. A number of transmembrane receptors are preferentiallyassociated with lipid rafts, which have been postulated to serveas scaffolds on which signaling molecules assemble (Razzaq etal., 2004

). The three probes used above, GPI-linked YFP, choleratoxin bound to GM1 gangliosides, and PM-GFP, are all believedto reside predominantly in lipid rafts. It was therefore conceivablethat exclusion of rafts from sites of phagocytosis might accountfor the pronounced clearance we observed. To address this possibility,we transfected RAW cells with YFP-GT46, a chimeric transmembraneprotein that does not reside in lipid rafts (Kenworthy et al.,2004

). Macrophages expressing YFP-GT46 exhibited fluorescencemostly at the plasma membrane. The density of YFP-GT46 at thebase of the cup diminished drastically during the early stagesof phagocytosis (Figure 3C), as described for the other probes.In three similar experiments, 55 ± 7% of the originalplasma membrane fluorescence remained at the cup within 5 minafter initiation of phagocytosis.

Taken together, these observations indicate that clearance ofmembrane markers at the phagocytic cup cannot be accounted forby either selective endocytosis or by lateral segregation oflipid domains.

Clearance of Membrane Markers Is due to Exocytosis
The extensive and rapid clearance of fluorescent membrane markersfrom the base of forming phagosomes could result from the focalinsertion of unlabeled endomembranes. To test this hypothesiswe performed transmission electron microscopy (TEM) of RAW cellsthat had been briefly pulsed with cationized ferritin. Underthese conditions, cationized ferritin binds diffusely to theplasma membrane, where it can be readily detected as an electron-densecoating by TEM. After removal of unbound ferritin from the medium,the cells were exposed to opsonized beads and then fixed andprocessed for TEM after ${approx}$ 2 min, at a stage where the phagocyticcup has formed but not yet sealed around the bead. Althoughthe membrane of quiescent cells was labeled continuously andrather homogeneously throughout its surface (not shown), a drasticreduction of nearly 50% in the density of ferritin was notedin the surface membrane in the immediate vicinity of the phagocytictarget, whereas a 13% drop was noted on the membrane liningthe outer face of the pseudopods (Figure 4, A–D). Importantly,ferritin-bearing endosomes were only rarely seen near the cup,suggesting that depletion of the electron-dense probe is notcaused by selective internalization, which is consistent withthe conclusion reached using fluorescent probes. Instead, thedata suggest that ferritin and other components of the plasmamembrane are displaced laterally from the base of the cup byunlabeled endomembranes that are delivered focally by directedexocytosis. The resulting dilution would account for the decreaseddensity of both electron-dense and fluorescent probes observed.

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Figure 4. Insertion of endomembranes by exocytosis detected by electron microscopy. RAW macrophages were labeled with cationized ferritin (see Materials and Methods) before exposure to 8-µm opsonized beads. After 2.5 min, the cells were fixed and subjected to conventional transmission electron microscopy. The areas boxed by the dotted lines in A are magnified in B (lower left box) and C (upper right box). (B) A portion of the pseudopod; (C) a region of the unengaged membrane. In D the density of ferritin at the cup and on the membrane lining the side of the pseudopods not in direct contact with the particle was quantified and normalized to that in the bulk, unengaged plasma membrane. Data are means ± SE densities from nine different determinations. Note the different density of ferritin in the regions indicated by the arrows. Scale bar, 2 µm. Micrographs are representative of three experiments.

Recent work has implicated microtubules in the delivery of endomembranevesicles to the phagocytic cup (Tapper et al., 2002

; Nishidaet al., 2005

). This enabled us to test experimentally the contributionof exocytosis to membrane remodeling during phagocytosis. WhenRAW macrophages stably expressing YFP-GPI were pretreated withcolchicine, binding of opsonized beads proceeded normally andphagocytic cups were formed. Clearance of YFP-GPI from the baseof such cups, however, was essentially ablated (Figure 5, Aand B); the fluorescence at the cup was indistinguishable fromthat elsewhere on the cell surface. The density of YFP-GPI atthe cup relative to that in unengaged regions of the membranewas significantly lower in control cells than in colchicine-treatedones (p < 0.01; Figure 5B).

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Figure 5. Inhibition of exocytosis prevents clearance of membrane markers. (A) YFP-GPI–transfected RAW cells were pretreated with 10 µM colchicine before exposure to 8-µm opsonized beads. Representative fluorescence (main panel) and DIC images (inset) are shown. (B) Quantitation of the fluorescence intensity at the base of the phagocytic cup (pc) relative to that of the plasma membrane (pm) in control ( ${blacksquare}$ ) versus colchicine-treated cells ( $sqdiagf$ ). (C) YFP-GPI–transfected RAW cells were pretreated with 100 µM LY294002 before exposure to 8-µm beads. (D) Quantitation of the fluorescence intensity at the base of the phagocytic cup relative to the plasma membrane in control ( ${blacksquare}$ ) versus LY294002-treated cells ( $sqdiagf$ ). (E) YFP-GPI-expressing RAW cells were cotransfected with DN-NSF and RFP at a 9:1 ratio. Transfected cells were identified by their red fluorescence. One such cell is illustrated. (F) Quantitation of the fluorescence intensity at the base of the phagocytic cup relative to the plasma membrane in cells transfected with either DN-NSF ( $sqdiagf$ ) or with WT-NSF ( ${blacksquare}$ ). Data in B, D, and F are means ± SE of over 30 determinations. For all comparisons, p < 0.05. Insets show corresponding DIC images. Scale bar, 2 µm.

These data are consistent with the premise that localized exocytosiscontributes to the dilution of plasmalemmal components at thecup. Additional support for this notion was obtained using LY294002,a specific and potent inhibitor of PI 3-kinase. Others havedemonstrated that blockade of this enzyme arrests phagocytosisof large (>3 µm) particles at the cup stage withoutpreventing actin polymerization, suggesting that it is importantfor membrane delivery to the cup (Cox et al., 1999

). As expected,YFP-GPI–transfected macrophages pretreated with LY294002were largely unable to internalize 8-µm beads, despiteforming distinct phagocytic cups. Clearance of YFP-GPI fromthe phagocytic cup was virtually eliminated (Figure 5, C andD). The difference in marker density at the cup between controland LY294002-treated cells was highly significant (p < 0.001).

Membrane fusion events, including exocytosis, are known to involvethe soluble-NSF attachment protein receptor (SNAREs) proteinfamily. SNARE proteins on the vesicular and target membranesform complexes that are thought to bring the membranes intoclose apposition, leading to fusion. Hexameric ATPase NSF isrequired for the uncoupling and repriming of these complexes,and inhibition of NSF has been shown to block exocytosis (Coppolinoet al., 2001). To further document the role of exocytosis inphagosomal remodeling, we transfected YFP-GPI–expressingmacrophages with either DN-NSF or WT-NSF. Cells (over)expressingWT-NSF exhibited normal phagocytic cup formation, with clearanceof YFP-GPI from the base of the cup that was indistinguishablefrom untransfected cells (Figure 5F). In contrast, cells expressingDN-NSF formed phagocytic cups but were unable to clear the membranemarker (Figure 5, E and F). The differential behavior of cellstransfected with WT- and DN-NSF was statistically significant(p < 0.05). Taken together, these data demonstrate that clearanceof the membrane marker at the phagocytic cup is due largelyto focal exocytosis.

Membrane Remodelling Is Size-dependent
As alluded to earlier, inhibition of PI 3-kinase arrests phagocytosiswhile the phagocytic cup is still unsealed. This effect is muchgreater for large particles (>3 µm) than for smallerones and has been attributed to a requirement for PI 3-kinasein exocytosis (Cox et al., 1999). This implies that the contributionof exocytosis to the formation of the phagocytic cup is differentfor different-sized particles. To test this hypothesis, RAWmacrophages were transfected with either YFP-GT46 or YFP-GPIand allowed to ingest opsonized 3-µm latex beads. In sharpcontrast to our results with 8-µm beads, neither of thetwo membrane markers cleared from the phagocytic cup (Figure 6,B–D). Indeed, both markers could be easily detected continuouslyon the perimeter of completely sealed phagosomes. The differencein membrane clearance between 3- and 8-µm beads was seenwith multiple membrane markers and was highly significant (p< 0.005 for all; see Figure 6D). The differential behaviorof the two types of beads was most apparent when cells wereexposed simultaneously to both 3- and 8-µm particles.As illustrated in Figure 6, A and D, when the plasmalemma wasprelabeled with fluorescent cholera toxin B subunit, clearanceof the marker from the phagocytic cup was much more pronouncedin the case of the large beads.

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Figure 6. Clearance of membrane markers is size-dependent. (A) RAW cells were labeled with Alexa 555–conjugated cholera toxin B subunit before simultaneous exposure to 3- and 8-µm opsonized beads. (B) Cells transfected with YFP-GT46 exposed to 3-µm beads. (C) Cells transfected with YFP-GPI exposed to 3-µm beads. Insets show corresponding DIC images. Scale bar, 3 µm. (D) Quantitation of the fluorescence intensity at the base of the phagocytic cup relative to the plasma membrane, measured 1 min after exposure to the either small (3 µm) or large (8 µm) beads, as indicated. Cells labeled with cholera toxin ( ${square}$ ), YFP-GT46 ( ${blacksquare}$ ), or YFP-GPI ( $sqdiagf$ ) are shown. Data in D are means ± SE of over 30 determinations. The differences between small and large beads were statistically significant (p < 0.05) for all markers.

During Fc ${gamma}$ -receptor mediated phagocytosis both VAMP3 and VAMP7have been shown to be recruited to the phagocytic cup (Bajnoet al., 2000

; Braun et al., 2004

; Murray et al., 2005

). UsingGFP-tagged VAMP3 and VAMP7 transfected into RAW macrophages,we confirmed that recruitment of these SNAREs also occurs when8-µm beads are ingested (data not shown). We next investigatedwhether markers of additional endomembrane compartments werealso delivered to large phagosomal cups. Given the longer timerequired for large particles to be internalized, we consideredwhether the early stages of phagosomal maturation—normallyobserved after complete internalization of the particle—wereinitiated concomitantly with engulfment, possibly contributingto the clearance of plasmalemmal markers. GFP-tagged forms ofthe early endosomal markers Rab5 and EEA1 were transfected intoRAW macrophages, and their distribution was monitored duringphagocytosis of 8-µm beads. We were unable to detect anyaccumulation of Rab5 or EEA1 at the phagocytic cup in live cells(see Supplementary Figure S1). Using an analogous approach,we screened for the recruitment of late endosomes, lysosomes,and the endoplasmic reticulum to the phagocytic cup of largebeads (Supplementary Figure S1). None of these markers accumulatednoticeably at the cup. The data therefore suggest that the pronouncedclearance of the surface markers from the base of large phagocyticcups is either due to the more effective delivery of endomembranesfrom the same sources detected earlier (Bajno et al., 2000

;Braun et al., 2004

) or to the contribution of a specializedcompartment that remains to be identified.

Inhibition of Exocytosis Reduces Phagocytosis Preferentially of Large Particles
Delivery of endomembranes during the course of phagocytosisis likely intended to enable particle engulfment, while preservingthe cellular surface-to-volume ratio. Given that inhibitionof microtubules or of NSF function prevented exocytosis to thecup (as measured by lack of clearance of membrane markers),we postulated that particle internalization should be significantlyattenuated under these conditions. In particular, internalizationof large particles is expected to be preferentially affected,as these should require more endomembranes for engulfment thanwould smaller particles (Cox et al., 1999). To validate thispremise, RAW macrophages were pretreated with 10 µM colchicinefor 10 min before allowing them to ingest either 3- or 8-µmbeads. As predicted, the microtubule-dissociating drug attenuatedphagocytosis of the larger particles significantly (p < 0.05)compared with the ingestion of the smaller beads (Figure 7, ${blacksquare}$ ). Similarly, the inhibition induced by NSF was more profoundfor large than for small beads (Figure 7, $sqdiagf$ , p < 0.05).

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Figure 7. Inhibition of exocytosis attenuates phagocytosis in a size-dependent manner. YFP-GPI-transfected RAW cells were pretreated with 10 µM colchicine before exposure to 8- or 3-µm opsonized latex beads. Colchicine ( ${blacksquare}$ ) reduced phagocytosis of 8-µm opsonized beads (p < 0.05) but had no significant effect on uptake of 3-µm beads. YFP-GPI–transfected RAW cells were cotransfected with either DN-NSF or WT-NSF and RFP in a 9:1 ratio ( $sqdiagf$ ). Transfection with DN-NSF greatly inhibited phagocytosis of 8-µm beads (p < 0.05 relative to WT-NSF) with less effect on 3-µm beads.

Turnover of the Membrane Spares the Fc ${gamma}$ Receptor But Not Its Effectors
The extensive remodeling of the membrane at the phagocytic cupcould have profound effects on the phagocytic signaling apparatus,selectively retaining some components while depleting others.To examine this possibility, we compared the distribution ofphagocytic receptors with that of generic membrane markers atthe cup. We chose to study Fc ${gamma}$ RIIA because, unlike other Fc ${gamma}$ receptorspecies, it consists of a single polypeptidic chain and doesnot require ancillary subunits (Gessner et al., 1998

). Thisis technically advantageous, because transfection of a singleGFP-tagged construct suffices for analysis of receptor distribution.The ectopically expressed receptor was located largely in theplasmalemma (73 ± 4%), with the remainder found in endomembranevesicles. Fc ${gamma}$ RIIA-GFP was readily detected at the phagocyticcup (Figure 8A). In fact, in a fraction of cells ( ${approx}$ 30%) the receptoraccumulated at the cup attaining densities that clearly surpassedthat of the bulk, unengaged plasma membrane (Figure 8B). Remarkably,unlike the markers tested earlier, the receptors did not clearfrom the base of the cup as the particle was being internalized.To prove that membrane remodeling at the phagocytic cup preferentiallyspared Fc ${gamma}$ receptors, we cotransfected CFP-tagged Fc ${gamma}$ RIIA andYFP-tagged GT46. Although both Fc ${gamma}$ RIIA and GT46 are single-spantransmembrane proteins, they behaved quite distinctly at thephagocytic cup. Although GT46 underwent extensive clearancefrom the cup well before the phagosome had sealed, Fc ${gamma}$ RIIA-CFPremained present (Figure 8, C and D). In other experiments,we expressed Fc ${gamma}$ RIIA-GFP and PM-RFP, a hydrophobically anchoredmarker of the inner leaflet of the plasma membrane. As seenfor the transmembrane marker, GT46, the hydrophobic probe PM-RFPwas depleted from the nascent phagocytic cup, whereas Fc ${gamma}$ RIIA-GFPremained (data not shown).

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Figure 8. Fc ${gamma}$ RIIA receptors are selectively retained during remodeling. (A) RAW cells transfected with Fc ${gamma}$ RIIA-GFP were exposed simultaneously to 3- and 8-µm opsonized latex beads. A representative confocal image acquired 1 min after addition of particles is illustrated. Arrow indicates retention of the receptor at the base of a large phagocytic cup. Inset is corresponding DIC image. (B) Accumulation of Fc ${gamma}$ RIIA-GFP at the phagocytic cup. Enrichment of receptors at the cup, such as the one illustrated here, was noted in ${approx}$ 30% of the cells. (C and D) RAW cells cotransfected with Fc ${gamma}$ RIIA-CFP and YFP-GT46 were allowed to internalize 8-µm beads. The distribution of the receptor (C) and of YFP-GT46 (D) during the course of internalization is illustrated.

We considered the possibility that the persistence of Fc ${gamma}$ RIIAat the cup was due to ongoing delivery of intracellular receptorsduring the course of phagocytosis. To analyze this possibility,we selectively labeled the intracellular recycling pool of receptorsusing a Fab fragment obtained from a Fc ${gamma}$ RIIA-specific antibody(IV.3), coupled with a secondary Cy3-labeled Fab fragment. Labelattached to exofacial receptors after the period allowed forinternalization was then displaced by a rapid acid pulse, asdescribed in Materials and Methods. The cells were next exposedto particles and the distribution of total receptors was studiedby monitoring the fluorescence of GFP, whereas that of the internalrecycling pool was followed monitoring the red fluorescenceof Cy3. Although green fluorescence persisted at the cup, nodelivery of previously internalized receptors was detectablein the membrane lining the bead (not illustrated). These observationssuggest that Fc ${gamma}$ RIIA are not dynamically replaced by deliveryof receptors stored in endomembranes, but that they are insteadretained by interaction with their ligands on the particle surface.

Membrane Remodeling Results in Physical Separation of the Fc Receptor from Lyn
The first step in the signaling cascade triggered by Fc ${gamma}$ receptorsinvolves activation of Src-family kinases such as Lyn, Hck,and Fgr (Fitzer-Attas et al., 2000). These are targeted to themembrane by means of hydrophobic interactions and are not tightlyattached to the receptors. We therefore wondered if the kinasesremain attached to the receptors during phagosomal remodelingor whether they are displaced by the bulk membrane flow, whichmight terminate their signaling at the cup. We coexpressed Fc ${gamma}$ RIIA-GFPand Lyn tagged with YFP (Lyn-YFP) in RAW cells. Because heterologousexpression of wild-type Lyn-YFP had toxic effects on the macrophages,a kinase-dead version of the enzyme (K275R) was used instead.The transfected RAW cells exhibited normal targeting to theplasma membrane of both constructs and were capable of phagocytosisof large beads. Importantly, we observed that although the Fc ${gamma}$ receptors remained at the cup during phagocytosis (Figure 9A),there was extensive clearance of the kinase (Figure 9B). Toensure that the ectopically expressed kinase-dead Lyn reflectedthe behavior of the WT kinase, we repeated the experiments inuntransfected cells and analyzed the distribution of endogenousLyn by immunostaining. As shown in Figure 9C, the endogenouskinase was also largely cleared from the membrane underlyingthe large particles during the advanced stages of cup formation.

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Figure 9. Differential depletion of Fc ${gamma}$ RIIA and Lyn from forming phagosomes. RAW cells were cotransfected with Fc ${gamma}$ RIIA-GFP (A) and Lyn-KD-YFP (B) and then allowed to ingest 8-µm opsonized beads, while monitoring fluorescence by confocal microscopy. A representative image acquired (using the LSM510 Meta to achieve spectral separation) ${approx}$ 1 min after engagement of the bead is illustrated. In C untransfected cells were allowed to engage opsonized beads and were then fixed, permeabilized, and immunostained for endogenous Lyn. The dashed lines show the bead outlines. Arrows point to the base of the phagocytic cup. Scale bars, 4 µm.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The central finding from this study is that the membrane ofthe phagocytic cup is almost completely remodeled during thecourse of internalization of large but not small particles.The extensive depletion from the cup applied to multiple markers,but was much less pronounced for Fc ${gamma}$ receptors, which are anchoredto ligands on the particle. This rules out optical artifactsas the explanation for clearance, which was also confirmed independentlyby labeling the particles (Figure 1). Remodelling of the phagocyticcup is due to insertion of endomembranes and results in thephysical separation of Fc ${gamma}$ receptors from their most proximaland important effectors, the Src-family kinases. We also foundthat extensive, localized endocytosis occurs at the phagocyticcup in macrophages.

The mechanism responsible for cup remodeling was studied indetail, using a variety of markers and approaches. Selectiveremoval of cup components by the activated endocytosis was considered,but was discounted based on the paucity of membrane markersin the endocytic vesicles and the persistence of clearance incell transfected with dominant negative dynamin I. We attributethis observation to "kiss and run" events where some of theendomembranes undergo only transient fusion with the plasmalemma,allowing uptake of the extracellular dye, but little intermixingwith components of the cup membrane. We also considered whetherclearance was caused by segregation of lipid microdomains suchas rafts, wherein Fc ${gamma}$ receptors are proposed to partition afterclustering (Kwiatkowska et al., 2003). However, markers knownto distribute selectively to rafts were displaced from the phagocyticcup at a rate and to an extent similar to those found for nonraftmarkers. In addition, we observed that constituents of the innerand outer monolayer were affected similarly, arguing againstuncoupling of the two aspects of the membrane bilayer. Instead,using multiple independent methods, we concluded that exocytosisof endomembranes was largely responsible for membrane remodeling.Several lines of evidence buttress this conclusion. First, markersof endomembrane compartments, particularly VAMP-3, were foundto appear at the phagocytic cup (Bajno et al., 2000; Murrayet al., 2005 and data not shown). Second, the density of ferritin-labeledplasmalemmal components decreased in the membrane surroundingthe particle. Third, conditions that inhibit exocytosis, suchas expression of DN-NSF, precluded clearance of plasma membranecomponents from the cup. The greater need for insertion of endomembranesto completely surround the particles also explains why largebeads are more susceptible to inhibition than their smallercounterparts. This applied to both DN-NSF and colchicine andparallels the differential sensitivity of beads of varying sizeto wortmannin, which likely impairs exocytosis at the phagocyticcup (Cox et al., 1999). Macrophages may sense particle sizeby a combination of membrane curvature (Champion and Mitragotri,2006), the number of receptors engaged, and the time requiredto complete phagosome sealing. Taken together, our data implicatingexocytosis are in good agreement with earlier demonstrationsthat the membrane capacitance often increases during engulfment(Holevinsky and Nelson, 1998; Di et al., 2003) and that thebinding of styryl dyes increases when macrophages spread ontoIgG-coated surfaces (Cox et al., 1999).

Given the requirement for insertion of additional membrane tocomplete engulfment of large particles, the concomitant stimulationof endocytosis would appear paradoxical. Its role may be theselective retrieval of components required for additional roundsof exocytosis, as is believed to be the case at neuronal synapsesafter release of neurotransmitter-containing vesicles. On theother hand, endocytosis at the phagocytic cup could serve aspecialized immune function, sampling antigens for presentationin a manner analogous to the pinocytic uptake performed by dendriticcells.

What are the functional consequences of the extensive turnoverof the membrane at the phagocytic cup? Fc ${gamma}$ receptor-mediatedsignaling begins with recruitment of effector tyrosine kinases.Src-family kinases are initially activated and they, in turn,trigger recruitment of Syk and the activation of multiple signalingpathways, including stimulation of various protein and lipidkinases as well as phospholipases and the engagement of multipleGTPases, culminating with cytoskeletal and membrane remodeling.The exocytic insertion of endomembranes must impact on thissequence, to the extent that the Fc ${gamma}$ receptors are physicallyseparated from (the bulk of) the Src-kinases, as indicated bythe redistribution of Lyn and of the PM-GFP probe, which isbased on the motif that targets Src-family kinases to the membrane(Hof and Resh, 1997). It is most likely that exclusion of Lynand other membrane-anchored kinases from the cup will contributeto termination of signaling, despite the retention of engagedreceptors. Though the receptors are phosphorylated early duringphagosome formation, active phosphatases such as SHP are recruitedto the site (Strzelecka-Kiliszek et al., 2002) and will likelyeliminate phosphotyrosine residues rapidly if displacement ofthe kinases prevents continued phosphorylation. In this regard,it is noteworthy that following the initial burst of polymerization,actin disassembles from the cup with a time course and spatialdistribution that closely parallel the remodeling of the membraneillustrated here (see Supplementary Movie 1).

In summary, our findings suggest a new mode of termination ofsignaling, mediated by the physical separation between receptorsand their effectors and caused by massive delivery of endomembranesto sites of activation (Figure 10). The accompanying changesin phospholipid composition of the membrane are also likelyto contribute to signal termination, since the phosphoinositidecontent of endomembranes differs markedly from that of the plasmalemma.

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Figure 10. Schematic representation of membrane remodeling at the phagocytic cup. Focal insertion of endomembranes by exocytosis results in extensive turnover of the membrane at the base of the cup, including lipid raft and nonraft membrane constituents. This results in physical separation of the Fc receptors, which are immobilized by interaction with particulate ligands, from its membrane-associated effectors, such as Lyn kinase.

ACKNOWLEDGMENTS

We thank Dan Petrescu, Abhilasha Sharma, Farzana Bacchus, andRobert Temkin for technical assistance. This work was supportedby grants from the Canadian Institutes of Health Research (CIHR)and the Canadian Arthritis Society. W.L.L. is the recipientof a postdoctoral fellowship award from the CIHR in partnershipwith the Canadian Lung Association, postgraduate awards fromthe Faculty of Medicine (University of Toronto), and a MedicalScientist Training Fellowship from the McLaughlin Centre forMolecular Medicine. S.G. is the current holder of the PitbladoChair in Cell Biology and is cross-appointed to the Departmentof Biochemistry, University of Toronto.

Footnotes

This was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E06-05-0450)on May 16, 2007.

The online version of this article contains supplementalmaterial at MBC Online (http://www.molbiolcell.org).

Address correspondence to: Sergio Grinstein (sga{at}sickkids.ca).

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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