Abstract
The nerve growth factor (NGF) family of neurotrophins binds two classes of cell-surface receptors, trk receptor tyrosine kinases and the shared p75 receptor. Rapid internalization and retrograde trafficking of neurotrophin-trk complexes have been demonstrated in a number of systems and are thought to transmit trophic signals from terminals to neuronal cell bodies. In contrast, the internalization and trafficking of neurotrophin-p75 complexes are not well understood. In this study, we used biotinylated NGF and a fluorescent-labeled anti-p75 antibody to follow the kinetics and route of ligand-induced internalization of the p75 receptor in cycling and differentiated PC12 cells. Binding of neurotrophins to p75 induced internalization at a rate approximately three times slower than that of transferrin and NGF-TrkA complexes in the same cells. The ligand-p75 complex was internalized via clathrin-coated pits into early endosomes and eventually accumulated in recycling endosomes in the cell body and vesicles colabeled by the cholera toxin B-subunit in the growth cones. Both internalized ligand and p75 were protected from proteolytic degradation and accumulated in vesicles that did not undergo acidification. Finally, NGF induced endosomal association of p75 and its MAGE interactors, necdin and NRAGE. These data suggest that signaling endosomes containing activated p75 are involved in neurotrophin signaling, and that such endosomes may be temporally and spatially distinct from those containing trk receptors.
Introduction
The nerve growth factor (NGF) family of neurotrophins interacts with specific members of the trk family of receptor tyrosine kinases to signal differentiation or survival of neuronal cells (Patapoutian and Reichardt, 2001). In addition, all neurotrophins bind to a shared p75 receptor (Hutson and Bothwell, 2001) that also binds other ligands (Fainzilber et al., 1996; Tuffereau et al., 1998; Della-Bianca et al., 2001; Lee et al., 2001). p75 has diverse roles in the nervous system, ranging from enhancement of axonal outgrowth through modulation of cell survival or cell death (Lee et al., 2001; Hempstead, 2002).
Neurotrophin signaling via trk receptors ultimately leads to activation of transcription factors, most notably cAMP response element-binding protein (CREB) (Riccio et al., 1997, 1999; Lonze et al., 2002). This nuclear response requires transduction of the target-derived neurotrophin signal along the full length of the axon (for review, seeMiller and Kaplan, 2001; Neet and Campenot, 2001; Ginty and Segal, 2002; Heerssen and Segal, 2002). Proposed mechanisms for such retrograde transduction include calcium/phosphorylation “waves” progressing along the axon (Senger and Campenot, 1997; MacInnis and Campenot, 2002), axonal transport of activated signaling molecules (Kuruvilla et al., 2000; Watson et al., 2001), or retrograde transport of activated neurotrophin-trk complexes (Bhattacharyya et al., 1997;Tsui-Pierchala and Ginty, 1999; Watson et al., 1999). The latter possibility has been elaborated as the “signaling endosome” hypothesis (Di Fiore and De Camilli, 2001). Potential TrkA-signaling endosomes in PC12 cells contain NGF and activated TrkA, are internalized via clathrin-coated pits, and are associated with activated signaling proteins of the Ras-MAP kinase pathway (Grimes et al., 1997; Howe et al., 2001). A direct interaction between trk receptors and dynein has been reported previously (Yano et al., 2001), providing a possible mechanism for trafficking of trk-signaling endosomes.
In contrast to the detailed studies on trk retrograde signaling, evidence for ligand-induced internalization and trafficking of the p75 receptor is rather weak. Anti-p75 monoclonal antibodies have been used to target toxins into cholinergic neurons (Heckers et al., 1994;Berger-Sweeney et al., 2001), and p75 may be involved in neurotrophin trafficking in certain neuronal subtypes (Curtis et al., 1995; von Bartheld et al., 1996; Kramer et al., 1999; Butowt and von Bartheld, 2001; Gatzinsky et al., 2001). However, a number of studies have failed to establish a role for p75 in NGF internalization (Eveleth and Bradshaw, 1992; Kahle et al., 1994; Gargano et al., 1997). Recent studies have emphasized independent signaling roles for p75 in both the nervous and vascular systems (Kaplan and Miller, 2000; von Schack et al., 2001; Hempstead, 2002). These findings, and the fact that p75 lacks intrinsic catalytic activities, rekindles the question as to how ligand binding to p75 might transmit a retrograde signal. We have addressed this issue by directly examining ligand-induced internalization of p75. Neurotrophin-p75 complexes internalize slowly and accumulate in nonacidified vesicles in PC12 cells. NGF enhances association of p75 with intracellular interactors on these vesicles, thus defining signaling endosomes that may be temporally and spatially distinct from those containing trk receptors.
Materials and Methods
Reagents. EZ-link biotin-PEO-amine (amino-biotin), 1-ethyl-3-(3-dimethyl aminopropyl)carbodiimide (EDC), and 2(4′-hydroxyazobenzene) benzoic acid (HABA) were from Pierce (Rockford, IL). Mouse NGF and the MC192 anti-p75 antibody conjugated to FITC were from Alomone Labs (Jerusalem, Israel). Recombinant human BDNF was a generous gift from Dr. Carlos Ibanez (Karolinska Institute, Stockholm, Sweden). Transferrin-Alexa-594, transferrin-Alexa-547, streptavidin-Alexa-594, streptavidin-Alexa-647, B-subunit of cholera toxin-Alexa-594, and LysoTracker Red DND-99 were from Molecular Probes (Eugene, OR). Rhodamine Red-X (RRX)-conjugated donkey-anti-goat, RRX-anti-mouse, goat RRX-anti-horseradish peroxidase (HRP), Cy5-conjugated donkey anti-rabbit, anti-goat and anti-mouse, IgG rat transferrin-HRP, and protease-free bovine serum albumin (BSA) were from Jackson ImmunoResearch (West Grove, PA). Rab7, Rab5, cathepsin D, hemagglutinin (HA), pan trk (C14), tyrosine-phospho-specific rabbit polyclonals, Clathrin heavy chain (Clathrin HC) goat polyclonal, and pan trk monoclonal (B3) were from Santa Cruz Biotechnology (Santa Cruz, CA). Early endosomal autoantigen1 (EEA1) rabbit polyclonal was from Affinity BioReagents (Golden, CO). Rabbit anti-p75 intracellular domain and neurotrophin receptor-interacting MAGE homolog (NRAGE) polyclonals were from Dr. Philip Barker (Montreal Neurological Institute, Montreal, Canada), rabbit anti-necdin was from Dr. Kazuaki Yoshikawa (Osaka University, Osaka, Japan), and rabbit r-TrkA polyclonal was from Dr. Louis Reichardt (University of California, San Francisco, San Francisco, CA). Magnetic particles were from Roche Products (Hertforshire, UK). The ABC/peroxidase kit was from Dako (Copenhagen, Denmark). All other reagents were from Sigma (St. Louis, MO).
Cell culture. PC12 cells were grown in DMEM containing glutamine and high glucose and supplemented with 6% horse serum, 6% fetal calf serum, and 100 U/ml penicillin–streptomycin. For differentiation experiments, cells were seeded at a concentration of 10–15,000 cells per square centimeter on poly-d-lysine-coated 16 mm coverslips and maintained for 4–5 d in the presence of 4 nm NGF in complete media. Differentiation was scored by morphological criteria and AChE activity determination (Bronfman et al., 2000). PC12–nnr5 (nnr5) cells were grown in collagen-coated dishes in RMPI-1640 media containing 4 mm glutamine, supplemented with 5% horse serum, 10% fetal calf serum and 100 U/ml penicillin–streptomycin. PC12 cells stably transfected with necdin-HA were established as described previously (Tcherpakov et al., 2002). Transient transfections of COS cells were with DEAE-dextran.
NGF iodination. NGF was iodinated by the lactoperoxidase method as described previously (Ryden et al., 1997). Steady-state competition-binding assays were performed on cells suspended in PBS supplemented with 1 mg/ml BSA, 1 mmMgCl2, and 0.5 mmCaCl2 in the presence or absence of native or biotinylated NGF. Binding was allowed to occur with gentle rocking at 4°C for 90 min, and the bound ligand was separated from free ligand by rapid pelleting of the cells in an Eppendorf microfuge (Eppendorf Scientific, Westbury, NY) at 4°C.
NGF biotinylation. The water-soluble carbodiimide EDC can mediate coupling between free amine and carboxyl groups to form an amide linkage. We took advantage of this property to selectively biotinylate NGF on carboxyl groups, by reacting EDC with NGF in the presence of EZ-link biotin-PEO-amine. NGF (0.5 mg) was dissolved together with 20 mg of amino-biotin in 710 μl of MES-NaOH buffer, pH 5.0. Forty microliters of EDC (0.5 m) were added to this solution, and the reaction was allowed to proceed for 2 hr with vigorous shaking at room temperature (RT). Biotinylated NGF (NGFb) was then purified from the reaction mixture by reverse-phase HPLC over a C4 column (Vydac) and quantified by spectroscopy. The degree of NGF biotinylation was then measured by competitive displacement of HABA dye from avidin, yielding an average 9.2 mol biotin per mole NGF.
NGFb binding and internalization in PC12 and nnr5 cells.Cells were grown in monolayers and harvested in PBS with 2 mm EDTA, pelleted, and resuspended in ice-cold DMEM HEPES with 1 mg/ml BSA and 4–6 nm NGFb. Cells from one confluent plate (6–9 × 106 cells) were used for each experimental point. NGFb was allowed to bind for 90 min at 4°C with gentle rotation, followed by four washes in PBS. The final cell pellet was resuspended in lysis buffer, composed of 20 mmTris-HCl, pH 8.0, 150 mm NaCl, 0.1% Igepal, 10% glycerol, 2 mm EDTA, and protease inhibitors mix (Roche Products). After clearing by 15 min centrifugation at 18,000 × g, the supernatant was adsorbed with streptavidin magnetic particles (Roche Products) overnight at 4°C. The particles were washed three times in lysis buffer for 10 min at 4°C, followed by one wash in water. Bound NGFb was then eluted by 10 min of boiling in 100 μl of SDS-PAGE sample buffer, followed by separation on 17.5% SDS-PAGE and blotting to nitrocellulose. NGFb was visualized with ABC/peroxidase using enhanced chemiluminescence (ECL) detection (Pierce). For internalization experiments, cells were incubated for the desired times (2–180 min) at 37°C, followed by rapid chilling on ice and centrifugation for 2 min at 1200 ×g. Cell pellets were then acid washed by resuspension in 0.2m acetic acid and 0.5 mNaCl for 7 min on ice, followed by three PBS washes. Internalized NGFb was then identified by lysis of the cell pellet and streptavidin pull-downs as described above. The band corresponding to NGFb was quantified with Image Gauge V3.41 software (Fuji, Tokyo, Japan) and regression analysis of the curves obtained was performed as described by Shogomori and Futerman (2001).
Tyrosine phosphorylation and Western blot analysis for TrkA.PC12 cells were treated with NGF at the indicated concentrations for 15 min at 37°C, washed with ice-cold PBS, and lysed with 10 mm Tris, pH 8.0, 150 mmNaCl, 10% glycerol, 1 mm orthovanadate, and proteinase inhibitors (Roche Products) containing 0.1% Igepal. Lysates were spun at 10,000 × g for 5 min and then precleared with 100 μl of a 50% suspension of protein-A agarose beads (Roche Products) for 1 hr at 4°C. The beads were removed and the supernatant (1 ml) was incubated with 6 μg of C14 primary antibody overnight at 4°C, followed by 100 μl of protein-A agarose for 1 hr at 4°C. Beads were precipitated and washed three times in lysis buffer, and proteins were eluted by 10 min of boiling in 60 μl of SDS-PAGE sample buffer, followed by separation on 10% SDS-PAGE and blotting to nitrocellulose. Tyrosine phosphorylation of immunoprecipitated TrkA was determined with a specific phosphotyrosine antibody and a secondary antibody conjugated to HRP and developed with ECL. The presence of TrkA in transfected COS cells was determined by immunoprecipitation as described above and development of the nitrocellulose membrane with a pan trk B3 monoclonal.
Immuno-endocytosis assay. MC192-FITC was used in an immuno-endocytosis assay to visualize ligand-induced internalization of p75. PC12 or nnr5 cells were seeded onto poly-d-lysine-coated coverslips at high density and used for endocytosis assays after 24–48 hr. Cells were cultured as described above with the exception that the DMEM medium did not contain phenol red. After preincubation for 1 hr at 37°C with incubation buffer (DMEM HEPES, 1 mg/ml BSA) to deplete endogenous transferrin and growth factors, cells were incubated with MC192-FITC (3 μg/ml), NGF (6–20 nm), and transferrin-Alexa-647 (60 μg/ml) in incubation buffer for 15–180 min at 37°C, followed by three washes in ice-cold PBS and fixation in 3% paraformaldehyde for 20 min. The fixation reaction was quenched in 0.1 mm glycine for 10 min. Cells were then washed in PBS and incubated for 60 min at RT with Cy5 or RRX anti-mouse (1:500; to label cell surface-associated MC192), washed, and mounted in Moviol. For cointernalization studies of p75 and NGF, differentiated PC12 cells were incubated with MC192-FITC (3 μg/ml) and NGFb (20 nm) for 90 min at 4°C, followed by 30 min incubation with streptavidin-Alexa-647 (1:100) in the presence of NGF (6 nm). Cells were then washed three times with PBS, and the coverslip was inverted in 100 μl ice-cold incubation buffer in a silicon rubber chamber on a microscope slide. Internalization was then induced by warming the slide for 10–60 min at 37°C, followed by in vivo visualization of the cells.
Fluorescence microscopy and quantitative analysis. Labeled cells were examined under an Olympus (Olympus Optical, Tokyo, Japan) laser-scanning microscope FV500 equipped with anOlympus IX70 inverted microscope (Olympus Optical) and Argon ion 488 nm, He-Ne 543 nm, and He-Ne 633 nm lasers. For fluorescein, Rhodamine Red-X and Alexa-594, Alexa-647, and Cy5 visualization, BA505IF, BA610If, and BA610IF filters were used.
Digital images of cell-associated fluorescence were acquired with a high-aperture objective (PLAPO 60×, numerical aperture 1.4). To quantify the fluorescence intensity associated with cells after MC192-FITC, transferrin-Alexa-647, and HRP internalization, six to eight digital images were taken from at least two different coverslips at 6× magnification for each time point. Cells presenting good morphology in phase images were chosen without bias as to their level of fluorescence and optically sectioned at 1 μm resolution. A total of 12–15 cells were imaged per experimental point. Cell-associated fluorescence was quantified with Fluoview Olympus (OlympusOptical) software station, after cell borders were defined with the help of the contrast phase image. Total cellular fluorescence was determined after subtracting nonspecific fluorescence of images obtained with the same illumination and exposure conditions in untreated cells.
Internalized transferrin and HRP were expressed as total cellular fluorescence (arbitrary units). Internalized MC192-FITC was expressed as a ratio of the internalized receptor (intracellular fluorescence) versus the cell surface-associated receptor (cell surface-associated fluorescence). Cell surface-associated MC192 was labeled by incubation with Cy5 or RRX-conjugated anti-mouse. Absence of internalization was defined as the fluorescence value obtained with cells treated with MC192-FITC for 90 min at 4°C. This value was subtracted from the different time points at 37°C. The regression analysis of the curves obtained was performed according to Shogomori and Futerman (2001). Colocalization of MC192-FITC and transferrin-Alexa-647 was quantified with ImagePro Plus software (Media Cybernetics, Silver Spring, MD).
Cointernalization of TrkA and p75. Differentiated PC12 cells were treated with MC192-FITC (3 μg/ml, green), r-TrkA antibody (1:500) (Clary et al., 1994), and BDNF (4 nm) for 60 min at 4°C; washed and incubated for 30 min at 4°C with anti-rabbit-Cy5 (1:250, red) and BDNF (4 nm); and then washed and incubated for different times (15–60 min) at 37°C in the presence of BDNF (4 nm). Cells were fixed and mounted as described above. The presence of vesicles positive for p75 or TrkA, or both, was quantified by measuring the fluorescence intensity levels for each dye (FITC for p75, Cy5 for TrkA) along a line through the respective vesicles. Results are presented as a percentage of total vesicles containing the receptors per cell; 12–15 different cells were analyzed per time point in each experiment.
Inhibition of receptor-mediated endocytosis via clathrin-coated pits. Internalization via the clathrin route was assessed by two separate methods: potassium depletion (Larkin et al., 1983) and cytosol acidification (Sandvig et al., 1987). All manipulations were performed at 37°C. Potassium depletion was performed by passing cells through hypotonic medium (DMEM/water, 1:1) for 5 min, followed by 30 min in potassium depletion buffer (PDF) consisting of 50 mm HEPES and 100 mm NaCl, pH 7.4. This was followed by 90 min of incubation in PDF containing 1 mg/ml BSA, 6 nm NGF, and 3 μg/μl MC192-FITC, or 15 min in PDF with 60 μg/ml transferrin-Alexa-594 or 2 mg/ml HRP. Controls underwent the same procedure in PDF supplemented with 10 mm KCl. For cytosol acidification, cells were incubated for 30 min in DMEM HEPES, pH 7.0, with 40 mm NH4Cl, followed by 5 min in cytosol acidification buffer (CAB) composed of 20 mm HEPES, 140 mm KCl, 2 mm CaCl2, 1 mm MgCl2, pH 7.0. p75 internalization was assessed after 90 min of incubation in CAB with 1 mg/ml BSA, 6 nm NGF, and 3 μg/ml MC192-FITC, whereas transferrin receptor and HRP internalization were visualized after 15 min of incubation in CAB containing 60 μg/ml tranferrin-Alexa-594 and 2 mg/ml HRP, respectively. Controls were incubated with the ligands in DMEM HEPES. After the treatments, cells were washed and fixed as described above, followed by 30 min of blocking with 5% donkey serum in PBS (blocking buffer). Cell surface-associated MC192 was then labeled by 60 min of incubation with Cy5-conjugated donkey anti-mouse (1:500), and the cells were then washed and mounted in Moviol for confocal analysis. To visualize HRP, cells were treated as described below for double labeling. Quantification of receptor internalization was performed as described above.
Double labeling. Colocalization of p75 and markers for fluid phase (HRP), early endosomes (EEA1), lysosomes (cathepsin D), late endosomes (rab7), or acid organelles (LysoTracker Red DND-99) was assessed in differentiated PC12 cells. To label early endosomes, cells were incubated for 30 min at 37°C with MC192-FITC (3 μg/ml), NGF (6 nm), and HRP (2 mg/ml). For EEA1, cells were incubated for 60 min at 37°C with MC192-FITC (3 μg/ml) and NGF (6 nm). To label the late endosome and lysosome compartments, cells were first incubated for 15 min with HRP (2 mg/ml), washed, and then incubated with MC192-FITC (3 μg/ml) and NGF (6 nm) for 3 hr at 37°C. For cathepsin D or rab7, cells were incubated with MC192-FITC (3 μg/ml) and NGF (6 nm) for 3 hr at 37°C, followed by fixing and immunostaining with the relevant marker antibody. Cells were blocked for 30 min in 10% goat or donkey serum, 1 mg/ml BSA, and 0.2% saponin, followed by 2 hr in 0.05% saponin and primary antibodies: Rhodamine Red-X-Goat anti-HRP (1/100) or rabbit polyclonals for EEA1 (1/500) cathepsin D and rab7 (1/100). The latter were visualized with Cy5-donkey anti-rabbit (1:100). Loading of acidic organelles with LysoTracker Red DND-99 was performed according to the manufacturer's instructions, followed by wash, fixation, and direct mounting in Moviol. The association of cell-surface p75 after ligand stimulation with clathrin matrices was assessed by patching MC192-FITC on the cell surface with rabbit anti-mouse antibody (1:25; Dako), followed by washes and 15 min of incubation at 37°C and fixation and immunostaining with goat anti-Clathrin HC (1:250) as described above.
Subcellular fractionation. PC12 or PC12-necdin cells (15–20 confluent 10 cm plates) were preincubated for 1 hr at 37°C with incubation buffer (DMEM HEPES, 1 mg/ml BSA) to deplete endogenous transferrin and growth factors, followed by 2 hr at 37°C with NGF (4 nm) and 15 min at 37°C with HRP (1 mg/ml) in the presence of NGF, or 1 hr at 37°C with iron-loaded rat transferrin-HRP (8 μg/ml). After labeling, cells were washed extensively with ice-cold PBS and, after a final wash with 320 mm sucrose and 20 mm HEPES buffer (HB), pH 7.4, were scraped and sedimented at 800 ×g for 5 min. The pellet (∼0.5 ml) was resuspended in 1.2 ml of HB and homogenized with a ball-bearing homogenizer (cell cracker; European Molecular Biology Laboratory, Heidelberg, Germany) with 12 μm clearance. A postnuclear supernatant was prepared by centrifugation for 10 min at 1000 × g and then additionally centrifuged for 1 hr at 105,000 × g in a TLS 55 rotor (Beckman, Coulter, CA) over 1% Ficoll in HB to obtain a P2 pellet. The β1 subunit of Na+/K+-ATPase was used as a marker for plasma membrane contamination during the subcellular fractionation procedure. P2 was resuspended in 1 ml HB and loaded in an 11 ml linear Ficoll gradient prepared in HB (1–16%), the gradient was centrifuged for 3 hr at 210,000 × g in a SW41 rotor (Beckman), and 1 ml fractions were manually collected from the top. HRP or transferrin-HRP was used to define the early/recycling compartment. The three HRP or transferrin-HRP peak fractions from gradient 1 were pooled and centrifuged over a 9 ml linear Ficoll gradient prepared in HB (3–16%) for 3 hr at 35,000 rpm in an SW41 rotor, and 1 ml fractions were manually collected from the top (gradient 2). Gradient 2 was free of plasma membrane marker. From cells treated with NGF for 2 hr at 37°C, 70 μl of each fraction of gradient 2 were boiled for 10 min in SDS-PAGE sample buffer and loaded in a 12% PAGE gel, blotted to nitrocellulose, and probed for rab5 (1:500), p75 (1:1000), NRAGE (1:1000), and necdin (1:5000) or HA- (1:3000) specific antibodies. For coimmunoprecipitation, 5–10 fractions of gradient 2 were pooled and diluted eight times with HB and then centrifuged for 10–12 hr at 35,000 rpm in an SW41 rotor. The sedimented endosomes were additionally centrifuged for 1 hr at 55,000 rpm in a TLS 55 rotor and lysed with 10 mm Tris, pH 8.0, 150 mm NaCl, 10% glycerol, and proteinase inhibitors containing 0.1% Igepal. Lysates were spun at 10,000 × g for 5 min and precleared with 30 μl of a 50% suspension of protein-G Sepharose beads (Amersham Biosciences, Arlington Heights, IL) for 30 min at 4°C. The beads were removed, and the supernatant (1 ml) was incubated with 5 μg of MC192 for 2 hr at 4°C, followed by 30 μl of protein-G Sepharose for 1 hr at 4°C. Beads were precipitated and washed three times in lysis buffer, and proteins were eluted by 10 min of boiling with SDS-PAGE sample buffer. Eluted proteins were loaded in a 12% SDS-PAGE gel, blotted to nitrocellulose, and developed with rabbit anti-NRAGE (1:1000) or anti-HA (1:3000) antibodies.
HRP activity assay. Each gradient fraction (15–40 μl) was brought to 75 ml with lysis buffer and assayed for HRP activity in a 96-well tissue-culture plate by the addition of 115 μl of citrate buffer (50 mm citrate/100 mm PO4, pH 5.0),O-phenylenediamine (Sigma), and 0.03% H2O2. The assay was stopped with the addition of 60 μl of 2N H2SO4 to each well. Absorbance was followed at 492 nm (Lichtenstein et al., 1998).
Results
Biotinylated and fluorescent probes for p75
Biotinylation of NGF provides a convenient tag for monitoring NGF trafficking with a wide range of different probes. Most biotinylation protocols are targeted to amino groups in proteins, but unfortunately the amino side chains in NGF are crucial for binding to the p75 receptor (Ibanez, 1995). We therefore developed a protocol to biotinylate carboxyl side groups in NGF, using amino-biotin and EDC to activate and derivatize carboxyl groups. The modified NGF was purified by reverse-phase HPLC, and biotinylation was confirmed by Western blot analysis with avidin–peroxidase (Fig.1A).
NGFb was able to compete with the binding of125I-NGF to PC12 cells in the same dose range as native NGF (Fig. 1B), and native NGF competed with binding of NGFb to nnr5 cells that express p75 but not TrkA (Fig. 1C). NGFb bound TrkA transiently expressed in COS cells (Fig. 1D) and activated TrkA in the same effective dose range as native NGF (Fig. 1E). Finally, NGFb induced differentiation of PC12 cells in a similar manner as native NGF (Fig. 1F). Thus, the biotinylated protein was shown to faithfully mimic native NGF with respect to receptor binding and cellular responses, confirming its use for our purposes.
A complementary tool to NGFb was provided by a fluorescein-labeled preparation of the MC192 monoclonal antibody (Chandler et al., 1984). MC192 binds to an extracellular epitope on rat p75, which is distinct from the binding site for NGF. Moreover, MC192 binding does not deleteriously affect NGF signaling in PC12 cells (Chandler et al., 1984; Heckers et al., 1994; Maliartchouk and Saragovi, 1997) or neurons (Brann et al., 1999).
P75 internalizes to a transferrin-positive endosome
Although internalization of the p75 receptor has been demonstrated in glial cells (Kahle and Hertel, 1992), to date there is no convincing evidence for ligand-induced p75 internalization in neurons or neuronal cell lines. We addressed this question by incubating PC12 cells with MC192-FITC (3 μg/ml) in the presence of NGF (20 nm) and transferrin-Alexa-647 (60 μg/ml. The high NGF concentration was chosen to ensure maximal internalization of neurotrophin receptors. After 15 min at 37°C, MC192-FITC was associated primarily with the cell surface (Fig. 2A, top panel), similar to the distribution observed in cells treated for 90 min at 4°C (data not shown). Tranferrin-Alexa-647 internalized within 15 min at 37°C. After 60–90 min at 37°C, internalization of MC192-FITC was evident (Fig. 2A, middle panel), and the label colocalized with transferrin-Alexa-647. At steady state (120–180 min at 37°C), MC192-FITC and transferrin-Alexa-647 extensively colocalized (Fig. 2A, bottom panel), and this was also confirmed by a confocal three-dimensional reconstruction of serial z-planes (Fig. 2D). Quantification revealed up to 80% colocalization at the 90–180 min time points (Fig. 2C). We calculated the initial rate of internalization by regression analysis from the internalization curves shown in Figure 2E (Shogomori and Futerman, 2001). The internalization rate thus calculated for the p75 receptor (t1/2 ∼46 min) proved to be approximately three times that of transferrin (t1/2 ∼17 min). The kinetics of internalization of MC192-FITC in the presence of 6 nm NGF in differentiated versus cycling PC12 was similar (t1/2 ∼46 min in cycling PC12 vs t1/2 ∼50 min in differentiated PC12) (Fig.2E,F).
p75 internalization is ligand dependent and TrkA independent
MC192-FITC internalization in PC12 cells in the absence of ligand was very slow and equally potentiated by NGF or BDNF (Fig.2F). NGF-induced internalization of MC192-FITC was also observed in nnr5 cells, in which the label accumulated in transferrin-positive vesicles after 2 hr at 37°C (Fig.3A). These data indicate that ligand-induced p75 internalization does not require trk activation.
To obtain an independent measurement of p75 internalization kinetics, we used NGFb to monitor internalization in PC12 and nnr5 cells. Consistent with the MC192-FITC data in PC12, NGFb was internalized less rapidly by nnr5 cells (that express p75 only) than by PC12 cells that express both trk and p75 (t1/2 ∼18 min for PC12 vs t1/2 ∼48 min for nnr5) (Fig. 3C). The total cellular levels of p75 after NGF treatment remained constant after up to 3 hr of incubation (Fig.3B), suggesting that p75 does not undergo degradation.
The p75 colocalization with transferrin at incubation times above 30 min suggests that p75 is a recycling receptor. We therefore investigated whether NGFb recycles back to the cell surface in both PC12 and nnr5 cells by allowing NGFb to internalize for 2 hr at 37°C, followed by acid wash and incubation of the cells in fresh medium in the presence of 100-fold excess of NGF. Relatively little NGFb (∼15%) was recovered in the incubation media, and a substantial amount was retained intracellularly. This contrasted with transferrin recycling, in which 90% was recovered in the cell media (Fig.3D). These results suggest that the recycling kinetics of NGF is inherently slow. Slow recycling kinetics has been described previously for other receptors that also accumulate in transferrin-positive endosomes (Innamorati et al., 1998; Chatterjee et al., 2001; Innamorati et al., 2001).
Internalization kinetics and vesicle accumulation of TrkA versus p75
The kinetics of NGFb internalization in PC12 versus nnr5 suggested that TrkA receptors internalize faster than p75 receptors. We assessed this possibility by performing a cointernalization experiment of TrkA and p75 in differentiated PC12. TrkA internalization was induced and visualized with an NGF-mimicking anti-TrkA antibody (Clary et al., 1994), whereas p75 internalization was induced by BDNF and visualized with MC192-FITC. After 15 min at 37°C, >80% of the labeled vesicles were TrkA positive and did not contain p75 (Fig.4A,C). At longer incubation times (60 min), three vesicle populations were observed: TrkA only, p75 only, or mixed (Fig. 4). Interestingly, all three populations could also be discerned in PC12 growth cones (Fig. 4B).
Internalized p75 is sorted to early endosomes via clathrin-coated pits
In the well characterized clathrin-mediated endocytic pathway, endocytosed molecules are delivered to sorting or early endosomes and then trafficked to the recycled endosomal compartment or to late endosomes and lysosomes for degradation. The fact that internalized p75 colocalized with transferrin at steady state strongly suggests that p75 avoids the degradation route and accumulates in the recycling compartment (Gruenberg and Maxfield, 1995; Mukherjee et al., 1997). Early endosomes accumulate fluid phase markers such as HRP. To test whether p75 passes through an early endosome compartment before reaching the recycling endosome, we applied HRP (2 mg/ml) together with MC192-FITC in the presence of NGF for 30 min and visualized the HRP with anti-HRP-RRX. As shown in Figure5A, both markers colocalized in a subset of vesicles in the cell body and growth cones of differentiated PC12. In addition, endosomes at the cell periphery that were positive for p75 were also positive for EEA1 (Fig. 5B), a specific marker for early endosomes (Mills et al., 1998). In contrast, at longer incubation times (3 hr), MC192-FITC does not colocalize with HRP in lysosomes (Fig.6A) or with lysosomal or late endosomal markers (Fig.6B,C). Furthermore, MC192-positive vesicles did not accumulate significant amounts of lysotracker dye, which labels acidic organelles such as the lysosome (Fig. 6D).
To investigate whether the internalization of p75 is mediated by clathrin-coated pits, we tested the association of p75 with clathrin matrices by co-patching experiments. p75 was patched on the cell surface by incubating PC12 cells with MC192-FITC, NGF, and anti-mouse secondary antibody. Cells were then fixed and immunostained for Clathrin HC, revealing extensive co-patching of clathrin with the p75 receptor (Fig. 7A). We then repeated the MC192-FITC internalization assay using two protocols that inhibit the formation of clathrin matrices: potassium depletion (Larkin et al., 1983) and cytosol acidification (Sandvig et al., 1987). These treatments inhibit clathrin-mediated endocytosis without preventing endocytosis mediated by other processes such as caveolae-dependent mechanisms (Subtil et al., 1994). We first verified binding of MC192-FITC under both experimental conditions and then proceeded to monitor internalization. Under both conditions, MC192-FITC internalization is inhibited in a similar manner as transferrin, a classical clathrin-mediated internalization marker (Fig.7B,C). HRP internalization via nonclathrin-dependent mechanisms, such as micropinocytosis, was not inhibited by these treatments (Fig. 7C).
Evidence for a p75 signaling endosome
To determine whether internalized p75 is active in PC12 cell endosomes, we investigated whether p75 internalized together with NGFb, visualizing the latter with streptavidin-Alexa-647. At short internalization intervals (10–30 min), we observed primarily NGFb-positive vesicles without p75, suggesting that these represent NGF-TrkA complexes (Fig.8A). At longer time points (e.g., 1 hr), extensive colocalization of NGFb and p75 could be seen. Colocalization of NGFb and p75 was also found in neurites and growth cones of differentiated PC12 (Fig.8B,C). The endocytic compartment labeled with p75 and NGFb in the growth cone is also positive for the B-subunit of cholera toxin (CTX-B) (Fig. 8D). CTX-B binds to GM1 gangliosides in lipid rafts and is used as a retrograde transport tracer in the nervous system. In addition, CTX-B traverses the same endosomal compartment as receptor-bound ligands internalized via clathrin-mediated endocytosis (Tran et al., 1987;Nichols and Lippincott-Schwartz, 2001; Shogomori and Futerman, 2001). Thus, p75 and NGF accumulate together in the recycling endosomes and CTX-B-positive vesicles in the growth cone.
p75 does not posses intrinsic catalytic activities, therefore its biological effects are mediated by forming complexes with intracellular interactors (Barker, 1998; Hempstead, 2002), including members of the MAGE gene family (Salehi et al., 2000, 2002; Tcherpakov et al., 2002). Necdin, a MAGE family member, associates with p75 in a ligand-dependent manner and has a slow kinetics of association compared with other p75 interactors such as TRAF6 (Khursigara et al., 1999; Tcherpakov et al., 2002). To directly assess whether internalized p75 is associated with MAGE proteins on endosomes, we performed subcellular fractionation of PC12 cells to isolate early/recycling endosomes. We followed a modification of a previously described protocol (Blagoveshchenskaya et al., 1999; Blagoveshchenskaya and Cutler, 2000), as detailed in Materials and Methods (Fig.9A,B). The endosome peak from NGF-stimulated PC12-necdin cells was positive for rab5, p75, NRAGE (endogenously expressed in PC12), and necdin (Fig.9C). p75 levels in the endosomes were markedly increased by NGF (Fig. 9D). Coimmunoprecipitation from endosomal fractions showed that both necdin and NRAGE co-precipitated with p75 in an NGF-dependent manner (Fig. 9E). Thus, p75 is internalized together with its ligand to the recycling compartment where it associates with NRAGE and necdin, forming a p75-signaling endosome.
Discussion
In this study, we have demonstrated ligand-induced internalization of p75 and have shown that liganded p75 associates with intracellular MAGE interactors in the endosomal compartment of PC12 cells, thus suggesting that specific components of p75 signaling take place in a signaling endosome. In addition, we have presented evidence that p75 internalizes through the clathrin-mediated internalization pathway to the recycling endosome but at distinct kinetics from TrkA, thus indicating that p75-signaling endosomes may be distinct from trk-signaling endosomes.
Monitoring the internalization and trafficking of p75-ligand complexes requires the use of selectively tagged ligands or probes for the complex. Most of the previous studies of neurotrophin-receptor internalization have relied primarily on preparations of neurotrophins labeled with radioactive iodine (Eveleth and Bradshaw, 1992; Kahle et al., 1994; Gargano et al., 1997). Although iodinated neurotrophins provide a highly sensitive probe caused by the high-specific activities obtainable in labeling and the relative ease of detection of125I, there are inherent limitations to this approach (i.e., the short half-life of iodinated proteins and their reduced stability). Nonradioactive labeling of neurotrophins has been attempted previously by a number of groups with varying degrees of success. Neet and colleagues described a detailed protocol for fluorescein labeling of NGF; however, an unexpected quenching limited the use of this preparation (Kasaian et al., 1994). A recent preliminary report described the use of rhodamine-NGF to follow neuronal retrograde transport in vivo (Weible et al., 2001). Unfortunately, the labeling protocol of Weible et al. (2001) was targeted to amine groups that are crucial for NGF binding to p75 (Ibanez, 1995). To obtain a useful and stably labeled NGF that retains the capacity to bind to p75, we devised a biotinylation strategy targeted to carboxyl groups on the protein. Carboxyl groups in NGF have been successfully labeled previously with fluorescent high molecular weight dextrans (Gatzinsky et al., 2001). Our protocol leads to incorporation of an average of approximately nine biotins on carboxyl groups in each NGF dimer, whereas it retains both TrkA- and p75-binding properties of the modified NGF. The labeled NGF was stable and could be visualized or pulled down with various avidin- or streptavidin-based reagents, thus providing a highly versatile tool for studies of internalization and trafficking. This was complemented by the use of MC192-FITC as a selective fluorescent probe for p75, thus providing an additional and independent possibility for monitoring p75 internalization.
p75 internalization proceeds via clathrin-coated pits to early endosomes, with subsequent transfer to the recycling compartment. Internalization occurs in both cycling and postmitotic differentiated cells, and in the latter can also be observed in the processes and terminals. p75 and NGF colocalize in endosomes in the cell body and terminals, suggesting that internalized p75 may be activated. Intriguingly, the kinetics of internalization of ligand-bound p75 is slower than that for classical rates of clathrin-mediated endocytosis, such as those measured for the transferrin receptor. Moreover, p75-NGF internalization proceeds at a rate approximately one-third (t1/2 ∼42–50 min) than that of NGF-TrkA. The different rates of internalization of p75 and TrkA define different populations of endocytic vesicles in the cell body and growth cone of differentiated PC12 cells, which contain TrkA only, p75 only, or a mixed population of both receptors.
In the clathrin-mediated endocytic pathway, endocytosed molecules are delivered to the sorting endosome and then trafficked to the recycling endosome or the late endosome–lysosome pathway (Gruenberg and Maxfield, 1995; Mellman, 1996). If activated p75 transports an NGF-mediated retrograde signal, it must avoid degradation in the axon. Our data support this affirmation. Indeed, p75 and NGF avoid degradation and remain in the recycling endosome for at least up to 3 hr after internalization. Likewise, NGF-TrkA internalized via clathrin (Howe et al., 2001) has been shown to avoid degradation (Zapf-Colby and Olefsky, 1998). In contrast to the neurotrophin receptors, the EGF receptor is not retrogradely transported and is efficiently degraded in the lysosomal pathway after ligand stimulation (Futter et al., 1996;Kao et al., 2001; Waterman et al., 2002). Thus, receptors that are retrogradely transported must first evade rapid degradation in the synaptic terminal. The recycling organelle in PC12 has been reported to contain synaptic vesicle components that recycle or sort to synaptic microvesicles (Lichtenstein et al., 1998). This raises the possibility that p75 normally recycles in the synaptic terminal, sharing a similar endosome as components of the synaptic vesicles. Ligand association with p75 might regulate interaction with specific docking proteins, which might then sort the receptor to the retrograde transport pathway. Indeed, the association of endosomal p75 with MAGE proteins supports this interesting possibility and suggests that internalized p75 might carry a signaling complex from the synaptic terminal to the cell body. Such a concept has been exemplified by the amyloid precursor protein that internalizes to recycling synaptic vesicles in primary cerebellar neurons and subsequently traffics retrogradely to the soma (Marquez-Sterling et al., 1997).
P75 and TrkA may form a high-affinity joint-binding complex for NGF (Esposito et al., 2001), raising the question of how these receptors internalize with different kinetics. Although we cannot rule out a fast-internalizing high-affinity complex in other cell types, the high excess of p75 over TrkA in PC12 cells (Urdiales et al., 1998) suggests that the majority of p75 receptors should be excluded from such a complex. Alternatively, the high-affinity complex may dissociate after ligand binding, allowing each receptor to follow separate kinetics of internalization. Nonetheless, because both p75-NGF and TrkA-NGF enter the cell via clathrin-mediated endocytosis, their differential internalization kinetics is intriguing. Slow internalization kinetics has been observed in the past for GPi-linked receptors associated with lipid rafts (Chatterjee et al., 2001). Both p75 and TrkA have been found in these specialized microdomains (Huang et al., 1999), and internalized p75 colocalizes with the lipid raft marker CTX-B in differentiated PC12. Thus, lipid rafts may regulate differential internalization of p75 versus TrkA (for example, via different affinities of the receptors for rafts). Notably, tetanus toxin-labeled retrograde trafficking vesicles in motor neurons have been reported to contain p75 (Lalli and Schiavo, 2002), and tetanus toxin is also associated with lipid rafts in the cell membrane (Herreros et al., 2001). Together, these studies might suggest that lipid rafts in the synaptic terminal regulate the sorting of retrograde-transported vesicles.
To summarize, our observations support the possibility that internalized neurotrophin-p75 complexes can act as signaling platforms in neuronal cells and may be incorporated to signaling endosomes. The differential kinetics of internalization of p75 complexes versus trk complexes may provide a mechanism for temporal separation between signaling endosomes containing each of these receptors. Such endosomes could thereby be shunted into a retrograde transport pathway of a neuron in a spatially separated manner, thus allowing differential signal transmission to the cell body.
Footnotes
This work was supported by Grant GR-1802 from the German and Israeli Ministries of Science (M.F., T.M.J.), Grant 647/01 from the Israel Science Foundation (M.F.), and an EMBO short-term fellowship and Feinberg postdoctoral fellowship (F.C.B.) M.F. is the incumbent of the Daniel Koshland Sr. Career Development Chair at the Weizmann Institute. We thank Dr. Phil Barker, Dr. Louis Reichardt, and Dr. Kazuaki Yoshikawa for generous provision of antibodies. We are grateful to Dr. Dmitry Charny (Goettingen, Germany) for advice on NGF labeling, Dr. Vladimir Kiss (Rehovot, Israel) for assistance with confocal microscopy, and Zehava Levy for excellent technical assistance.
Correspondence should be addressed to Mike Fainzilber, Department of Biological Chemistry, Weizmann Institute of Science, Herzl Street 1, 76100 Rehovot, Israel. E-mail: mike.fainzilber{at}weizmann.ac.il.