Abstract
Hippocampal neurons release nerve growth factor (NGF) through the constitutive secretory pathway, thus allowing the protein to be continuously available for promoting nerve cell survival. In contrast, hippocampal neurons use the regulated secretory pathway to process brain-derived neurotrophic factor (BDNF), which alters synaptic activity when released acutely from dense-core vesicles. Thus, understanding how neurons sort and deliver neurotrophins may provide clues to their functions in brain. In this study, we monitored the processing and delivery of neurotrophin-3 (NT-3). Pulse–chase studies, immunocytochemistry, and secretagogue-induced release experiments were performed on cultured hippocampal neurons and AtT-20 cells infected with vaccinia viruses encoding the NT-3 precursor (pro-NT-3). Results show that most newly synthesized NT-3 is released through the constitutive secretory pathway as a result of furin-mediated endoproteolytic cleavage of pro-NT-3 in the trans-Golgi network. Pro-NT-3 can also be diverted into the regulated secretory pathway when cells are treated with α1-PDX, a selective inhibitor of furin-like enzymes, or when pro-NT-3 expression is increased by transient transfection methods. In cells coinfected with viruses coding for pro-NT-3 and pro-BDNF, NT-3 is sorted into the regulated pathway, stored in secretory granules, and released in response to extracellular cues together with BDNF, apparently as a result of heterodimerization, as suggested by coimmunoprecipitation data. Taken together, these data show that sorting of the NT-3 precursor can occur in both the constitutive and regulated secretory pathways, which is consistent with NT-3 having both survival-promoting and synapse-altering functions.
Neurotrophins are synthesized as high molecular weight precursors containing a prodomain linked to the amino terminus of the mature protein. The two components are separated by endoproteolytic cleavage within either the constitutive or regulated secretory pathways. Understanding how neurotrophins are processed in these pathways may help explain their physiological functions.
Hippocampal neurons and AtT-20 cells in culture process nerve growth factor (NGF) within the constitutive secretory pathway (Mowla et al., 1999). The NGF precursor is cleaved within the trans-Golgi network (TGN) by the endoprotease furin, a member of the subtilisin/kexin-like family of proteases (for review see Seidah et al., 1998; Zhou et al., 1999). Constitutive release of NGF occurs soon after the molecule is synthesized. Thus, as a result of being processed in the constitutive pathway, NGF is continuously available to cells that require it, which is consistent with hippocampal neurons producing NGF as an apoptosis-inhibiting survival factor for basal forebrain cholinergic neurons (for review, see Yuen et al., 1996).
In contrast, hippocampal neurons process brain-derived neurotrophic factor (BDNF) within the regulated secretory pathway (Goodman et al., 1996; Mowla et al., 1999). Intact pro-BDNF is shunted from the TGN into immature secretory granules where it is likely cleaved by prohormone convertase 1 (PC1), another member of the subtilisin/kexin-like endoprotease family (Seidah et al., 1996b; Mowla et al., 1999). BDNF is stored within dense-core vesicles (Fawcett et al., 1997; Michael et al., 1997) (for review, see Altar and DiStefano, 1998), and once released, presumably in response to extracellular cues, it can induce changes in neuronal structure (Ventimiglia et al., 1995; Fawcett et al., 2000), membrane depolarization (Kafitz et al., 1999), and changes in synaptic function (for review, see McAllister et al., 1999). Likewise, neurotrophin-3 (NT-3) may regulate neuronal depolarization (Kafitz et al., 1999) and synaptic plasticity (Kang and Schuman, 1995), but as yet little is known about its intracellular sorting in vivo.
Neurotrophins are normally synthesized as noncovalently linked homodimers consisting of two identical chains. When different neurotrophins are coexpressed within the same cell, however, they also form heterodimers. Heterodimers of BDNF and NT-3 are stable, whereas heterodimers involving NGF are not (Radziejewski and Robinson, 1993;Arakawa et al., 1994; Jungbluth et al., 1994; Heymach and Shooter, 1995; Robinson et al., 1995). BDNF/NT-3 heterodimers can induce autophosphorylation of Trk receptors, promote the survival of sympathetic neurons in vitro, and induce dopamine uptake in cultures of substantia nigra neurons (Arakawa et al., 1994; Philo et al., 1994). However, the physiological functions of heterodimers remain unknown.
In this study, we monitored the sorting of NT-3 by infecting hippocampal neurons and AtT-20 cells with vaccinia viruses (VVs) encoding pro-NT-3. Pulse–chase studies and immunocytochemistry show that processed NT-3 is primarily released through the constitutive secretory pathway. Inhibition of furin-mediated cleavage or overexpression of pro-NT-3 shifts pro-NT-3 sorting into the regulated secretory pathway. NT-3 is also sorted to the regulated secretory pathway when it is coexpressed with BDNF. Immunoprecipitation data suggest that the transfer of NT-3 to the regulated pathway occurs as a result of NT-3 and BDNF heterodimerizing. Thus, either secretory pathway can sort NT-3.
Some of these results have been published previously in abstract form (Farhadi et al., 1998).
MATERIALS AND METHODS
Cell cultures. Hippocampal neurons were prepared according to the method of Banker and Cowan (1977) as modified byBrewer et al. (1993). Briefly, the hippocampus was dissected from embryonic day 18 (E18) mice (Charles River, Montreal, Quebec, Canada), exposed to trypsin, dissociated mechanically, and grown in 60 mm collagen/poly-l-lysine-coated dishes. Cells from two litters of mice were plated into six dishes. Cultures were maintained in serum-free Neurobasal medium (Life Technologies, Gaithersburg, MD) containing 0.5 mm glutamine and 1× B27 supplement (Life Technologies). AtT-20 cells and COS-1 cells were cultured as reported previously (Seidah et al., 1996a). AtT-20 cells are a neuroendocrine cell line that has been used extensively for studying the regulated secretory pathway (Moore et al., 1983). We also used an AtT-20 cell line stably transfected with α1-PDX cDNA that has been described previously (Benjannet et al., 1997). Special care was taken to ensure that cells were distributed in equal numbers in dishes that were to be used for group comparisons.
VV recombinants and infections. Purified recombinant VVs containing the full-length coding regions of mouse pro-NGF, human pro-BDNF, and human pro-NT-3 (generously provided by Regeneron Pharmaceuticals) were constructed as described previously (Seidah et al., 1996a,b). VVs coding for α1-PDX were kindly provided by Dr. Gary Thomas (Vollum Institute, Portland, OR). Separate plates of cells were infected as described previously (Seidah et al., 1996a) with VV encoding pro-NGF, pro-BDNF, or pro-NT-3, generally at a multiplicity of infection (MOI) of 1. We incubated the cells for 8–10 hr in virus-free medium before metabolic labeling. In some experiments, plates were coinfected with pro-BDNF and either pro-NT-3 or pro-NGF, using an MOI of 0.5 for each. Under our experimental conditions, there was no evidence of cell death after exposure to VVs for the times indicated.
Construction of expression vectors and transfections. In some experiments, we transfected cells with DNA using the lipofectamine reagent (Life Technologies). cDNAs corresponding to the full-length coding regions of human pro-BDNF and human pro-NT-3 were subcloned into the pcDNA3 expression vector (Invitrogen, San Diego, CA). AtT-20 cells growing on poly-l-lysine-coated coverslips were transfected using lipofectamine with a constant amount of DNA (2 μg DNA/2 ml medium) that was composed of expression vector alone (with no insert) together with 0.1, 0.5, 1, or 2 μg of pro-BDNF or pro-NT-3 plasmid DNA. After 5 hr of incubation, the transfection medium was diluted 1:1 with DMEM/20% fetal calf serum, and after 2 d, coverslips were processed for immunostaining (see below).
Metabolic labeling and immunoprecipitation. For pulse–chase experiments, we incubated infected cells with 1.5 ml of Cys-Met-free DMEM containing 10% FCS and 0.5 mCi/ml [35S] Translabel (ICN Biochemicals, Costa Mesa, CA) (70% methionine, 30% cysteine) for 30 min. Pro-BDNF contains eight methionines as compared with three in pro-NT-3, and mature BDNF contains three methionines as compared with none in mature NT-3. These differences, together with higher concentrations of methionine than cysteine in the Translabel, explain why, in Figures showing the results of metabolic labeling experiments, pro-BDNF and mature BDNF label more heavily than pro-NT-3 and NT-3. For the chase periods, cells were washed, and the medium was replaced with an equal volume of DMEM containing 10% FCS plus twofold excess concentrations of nonradioactive cysteine and methionine for the times indicated. In all experiments, conditioned media and cell lysates were brought to final volumes of 1.5 ml, 750 μl of which was subjected to immunoprecipitation. Samples immunoprecipitated with nonimmune rabbit IgG showed no bands corresponding to standards of neurotrophin precursors or products.
Immunoprecipitations were performed as described previously (Seidah et al., 1996a). For NT-3, we used an affinity-purified rabbit anti-NGF IgG that recognizes NT-3 (Murphy et al., 1993; Seidah et al., 1996a). BDNF immunoprecipitations were performed using an antibody kindly supplied by Amgen and characterized previously (Fawcett et al., 1997; Yan et al., 1997). Cell lysates and conditioned media were analyzed by electrophoresis on a 13–22% SDS-PAGE. Gels were fixed in 40% methanol and 10% acetic acid, treated with ENHANCE (Dupont NEN, Boston, MA), and washed in 10% glycerol, all for 1 hr. Dried gels were analyzed by a phosphorimaging device (Molecular Dynamics, Sunnyvale, CA), and radioactivity in each band was quantitated using the ImageQuant program. Levels of radioactivity were within the linear range of the device. Statistical significance was determined using the Student's t test on a minimum of triplicate experiments.
To monitor the effects of depolarization on neurotrophin release, we infected hippocampal neurons with recombinant viruses, metabolically labeled the cells for 30 min, and washed and incubated the cells in medium containing excess nonradioactive methionine and cysteine for 4 hr. The cells were exposed to tissue culture medium supplemented with or without KCl (56 mm) and CaCl2 (5.8 mm) for 15 min. Conditioned media and cell lysates were collected, immunoprecipitated, and fractionated by SDS-PAGE. Neurotrophin levels were estimated and compared by PhosphorImager analysis. In a previous control experiment (Mowla et al., 1999), we confirmed that KCl induces the release of endogenous secretogranin II in cultures of VV:NGF-infected hippocampal neurons to confirm that the regulated secretory pathway is fully functional in cells infected with VV constructs (Mowla et al., 1999).
Immunocytochemistry and confocal microscopy. We visualized VV-infected AtT-20 cells and primary cultures of hippocampal neurons as well as controls consisting of uninfected cells or cells infected with wild-type VVs. Cells were rinsed with PBS, fixed for 25 min in 4% paraformaldehyde/15% picric acid in 0.1 m phosphate buffer, pH 7.4, and incubated in PBS containing 20% horse serum for 30 min to reduce nonspecific binding. The cells were incubated with 1 μg/ml of affinity-purified anti-NT-3 (Chemicon, Temecula, CA) in PBS/0.2% Triton X-100 overnight at 4°C, washed three times with PBS/0.05% Tween-20 (5 min each), and incubated for 1 hr with CY3-conjugated goat anti-rabbit antibody (Jackson Laboratory, Bar Harbor, ME) diluted 1:2000 in PBS/0.05% Tween-20 containing 10% goat serum. Cells were washed three times in PBS and mounted in a Tris-buffered glycerol mounting medium (Sigma, St. Louis, MO). In control experiments, the anti-NT-3 antibody showed no detectable cross-reactivity by immunocytochemistry with either NGF or BDNF (data not shown).
Double-label immunocytochemistry was also performed on VV-infected AtT-20 cells to compare the distribution of NT-3 and NT-3/BDNF with that of TGN38, a marker of the TGN (Luzio et al., 1990), and ACTH, which is packaged in secretory vesicles. Antibody to TGN38 raised in guinea pig (kindly provided by Drs. G. Banting and W. Garten) was used at a 1:50 dilution and visualized using an FITC-conjugated secondary antibody raised in goat (Jackson Laboratory) diluted 1:50 in PBS containing 10% goat serum. ACTH was localized with a monoclonal antibody (Cortex Biochem) at a dilution of 1:1000, visualized with a CY2-conjugated goat anti-mouse secondary antibody (Jackson Laboratory) diluted 1:1000 in PBS containing 10% goat serum.
Cells were analyzed by confocal laser scanning microscopy using a ZeissLSM 410 inverted confocal microscope and a 63×, 1.4 NA objective. Cells were excited at 543 nm and imaged on a photomultiplier after passage through FT 590 and LP 590 filter sets. The confocal images represent one confocal level (a depth of ∼1 μm) that includes the cell nucleus along with as many cell processes as were possible to capture, the goal being to evaluate the distribution of secretory vesicles. No differences were evident in the distribution of NT-3 or NT-3/BDNF immunoreactivity when we scanned at various levels below or above the nucleus.
RESULTS
NT-3 is released constitutively from hippocampal neurons and AtT-20 cells
To determine the pathway by which NT-3 is processed and released, we did the following: (1) measured the retention or release of processed NT-3 from virally infected cells after pulse–chase labeling; (2) determined whether agents that promote vesicle exocytosis promote the release of NT-3; and (3) used immunocytochemistry to visualize the intracellular localization of NT-3 in virally infected cells.
Figure 1 shows the results of 30 min pulse–chase studies performed over 8 hr to monitor the processing of pro-NT-3 in primary cultures of hippocampal neurons (Fig.1A) and in AtT-20 cells (Fig. 1B). In both cell types, pro-NT-3 (33.5 kDa) is processed to mature NT-3 (14.5 kDa). The precursor is detectable in cell lysates at the start of the chase period, and levels decrease thereafter; by 8 hr of chase, the precursor is barely detectable. Intact pro-NT-3 is not detectable in conditioned medium at any time point in either cell type. Mature NT-3 is visible in cell lysates at the beginning of the chase period, but over time, levels in cell lysates decrease. Over the same time period, NT-3 levels in conditioned medium increase, and by 2 hr they exceed those in cell lysates. Therefore, most newly processed NT-3 is rapidly released from both hippocampal neurons and AtT-20 cells.
We were surprised that levels of pro-NT-3 were so low in these cells and that processed NT-3 was evident immediately after the 30 min pulse period. In our previous studies, levels of pro-NGF and pro-BDNF were much higher at the beginning of the chase period, attributable in part to increased labeling efficiency (see Materials and Methods). Also, significant processing of pro-NGF and pro-BDNF was not evident until 30 min after the chase began. To test whether these differences were caused by pro-NT-3 being processed more efficiently in the constitutive pathway than either pro-NGF or pro-BDNF, we compared precursor processing in virally infected COS-1 cells, a cell line that contains only the constitutive secretory pathway. Results show that abundant amounts of processed NGF and BDNF are detectable in cell lysates and conditioned medium at the end of the test period (Fig.2). As well, significant levels of unprocessed pro-NGF and pro-BDNF are detectable in cell lysates and in conditioned medium, which suggests that some precursor escapes proteolysis, perhaps by overwhelming the processing capacity of the cell (Mowla et al., 1999). In contrast, pro-NT-3 is detectable in cell lysates but not in conditioned medium, whereas processed NT-3 is evident in both. One explanation for these data is that pro-NT-3 is more efficiently processed within the constitutive secretory pathway than either pro-NGF or pro-BDNF.
We used pulse–chase labeling methods similar to those used in Figure 1to determine whether the endoprotease furin, which is present in the constitutive pathway, is involved in pro-NT-3 processing in AtT-20 cells. For this experiment, we used AtT-20 cells that have been stably transfected with α1-PDX, an α1-anti-trypsin structural variant that selectively inhibits furin-mediated cleavage of precursor proteins in the TGN (Anderson et al., 1993; Watanabe et al., 1995; Vollenweider et al., 1996; Benjannet et al., 1997). In cells expressing α1-PDX (Fig.3), significant levels of pro-NT-3 are released into conditioned medium over the 8 hr chase period, but levels of processed NT-3 are markedly reduced (compare Fig. 3 with Fig.1B). Therefore, inhibition of furin-mediated cleavage prevents the processing of pro-NT3 and the efficient generation of mature product.
The finding that α1-PDX prevents the processing of pro-NT-3 and induces its release into conditioned medium is identical to that obtained previously with pro-NGF (Mowla et al., 1999). In that study, we determined that inhibiting furin cleavage with α1-PDX caused the shunting of pro-NGF from the constitutive to the regulated secretory pathway (Mowla et al., 1999). We also observed that some pro-BDNF is constitutively released in the course of its processing within the regulated secretory pathway (Mowla et al., 1999). Together, these results suggest that inhibiting furin-mediated cleavage of pro-NT-3 may also direct the precursor from the constitutive to the regulated secretory pathway.
To test this idea, we monitored the effects of cAMP on NT-3 release from AtT-20 cells in the presence or absence of α1-PDX. We also used immunocytochemistry to analyze the distribution of NT-3 under both experimental conditions. Results show that cAMP stimulates the release of NT-3 from AtT-20 cells in the presence (Fig.4, right panel) but not in the absence (left panel) of α1-PDX. This result is consistent with immunocytochemical data (Fig.5) showing that in the absence of α1-PDX (Fig. 5A), NT-3 immunoreactivity is distributed in the perinuclear cytoplasm and not in cell processes, an appearance identical to that previously reported for NGF (Mowla et al., 1999). However, in the presence of α1-PDX (Fig. 5B), punctate NT-3 immunoreactivity is evident throughout the cytoplasm and in the tips of cell processes, which is consistent with earlier results monitoring the distribution of BDNF in wild-type cells and NGF in α1-PDX-treated cells (Mowla et al., 1999). Thus NT-3, which is normally processed and released from the constitutive pathway, can be rerouted to the regulated secretory pathway when furin-mediated cleavage within the TGN is inhibited.
In earlier studies, Heymach et al. (1996) and Moller et al. (1998)showed that NT-3 is packaged in dense-core vesicles of AtT-20 cells and PC12 cells and released in response to secretagogues or cell depolarization. To explain why their results differ from ours, we investigated whether elevating levels of pro-NT-3 expression could redirect NT-3 from the constitutive to the regulated secretory pathway, as has been shown previously for pro-NGF (Mowla et al., 1999). Initially, we determined that infecting AtT-20 cells with 5, 10, and 25 MOIs of VV encoding pro-NT-3 resulted in only a small amount of pro-NT-3 being redirected into the regulated secretory pathway, as determined by the ability of cAMP to induce NT-3 release (data not shown). Similar infection levels were extremely effective in rerouting NGF from the constitutive to regulated secretory pathway (Mowla et al., 1999). We suspect that the differences are attributable to pro-NT-3 being more efficiently processed than pro-NGF within the constitutive secretory pathway, as shown in Figure 2. To achieve higher intracellular concentrations of pro-NT-3, we opted for a lipofectamine transfection method similar to that used by Heymach et al. (1996) andMoller et al. (1998).
Lipofectamine transfection of pro-NT-3 DNA (0.1 μg with 1.9 μg vector DNA/2 ml of culture medium) resulted in NT-3 immunoreactivity in AtT-20 cells that is diffusely distributed in the perinuclear cytoplasm (Fig. 6A), as seen earlier (compare with Fig. 5A). However, when we transfected 0.5 or 1 μg of pro-NT-3 DNA (with vector DNA to a total of 2 μg/2 ml of culture medium), NT-3 immunoreactivity is evident in punctate structures that extend into cell processes, which is consistent with the appearance of secretory proteins processed in the regulated secretory pathway (Fig. 6B). For comparison, we show in Figure 6C the punctate localization of BDNF immunoreactivity in cells exposed to only 0.1 μg of pro-BDNF with 1.9 μg of vector DNA/2 ml of culture medium. Pro-BDNF is processed within the regulated secretory pathway (Mowla et al., 1999). Thus, cells transfected with high concentrations of pro-NT-3 DNA process the protein in the regulated secretory pathway, which likely explains why our results with VV infection methods differ from those of Heymach et al. (1996) and Moller et al. (1998) using lipofectamine transfection.
NT-3 is sorted to the regulated secretory pathway when coexpressed with pro-BDNF
Because NT-3 is processed in the constitutive pathway and BDNF is processed in the regulated pathway (Mowla et al., 1999), we questioned what would happen if we coexpressed precursors to the two proteins within the same cell. Others have shown that neurotrophins readily heterodimerize (Radziejewski and Robinson, 1993; Arakawa et al., 1994;Jungbluth et al., 1994; Philo et al., 1994; Heymach and Shooter, 1995;Robinson et al., 1995; Treanor et al., 1995), but nothing is known about the mechanisms regulating the processing, sorting, and release of heterodimers within cells.
For these studies, we first analyzed the specificity of our antibodies, because previous studies have shown that antibodies to one neurotrophin can cross-react on Western blots with the other (Murphy et al., 1993). In these studies we infected AtT-20 cells for 1 hr with 1 MOI of VV coding for either pro-NT-3 or pro-BDNF, incubated the cells for 8 hr without virus, metabolically labeled the cells for 3 hr, and immunopreciptated cell lysates and conditioned media with antibodies to NGF (for NT-3) or BDNF. In some experiments, we coinfected cells with 0.5 MOI of VV coding for pro-NT-3 and pro-BDNF to ensure that the total level of viral infection (1 MOI) was held constant.
Figure 7 (left side) shows that antibody to NGF immunoprecipitates NT-3 but not BDNF or pro-BDNF. Similarly, antibody to BDNF (Fig. 7, right side) immunoprecipitates BDNF and pro-BDNF but not NT-3. In contrast, in cells coinfected with VV coding for pro-NT-3 and pro-BDNF, antibody to NGF immunoprecipitates in conditioned medium NT-3 as well as a protein migrating in a position identical to that of pro-BDNF (Fig. 7,left side). We interpret this result to mean that NT-3 and pro-NT3 are associating with the BDNF precursor. In cell lysates as well as conditioned medium, the NGF antibody immunoprecipitates a doublet consisting of a higher molecular weight band (probably arising from precipitation of NT-3 alone and with BDNF) as well as a lower molecular weight band (BDNF) that precipitates because of association with NT-3. The right side of Figure 7 shows that antibodies to BDNF precipitate in cell lysates, and to a lesser extent in conditioned medium, a doublet consisting of a lower band (probably arising from precipitation of the BDNF alone or with NT-3) as well as an upper band (NT-3). Results identical to those shown in Figure 7 were obtained when the same experiments were performed in cultures of hippocampal neurons (data not shown).
In short, NT-3-specific antibodies precipitate BDNF, and BDNF-specific antibodies precipitate NT-3 only when the two neurotrophins are coexpressed within cells. We strongly suspect that these two independent but mutually consistent results arise from NT-3 and BDNF forming heterodimers intracellularly. Immunoprecipitation methods similar to ours were used previously by Jungbluth et al. (1994) andHeymach and Shooter (1995) to characterize neurotrophin heterodimers, including NT-3/BDNF. It should be noted that coinfection with wild-type and BDNF-encoding VV and coinfection with VV:pro-NGF and VV:pro-BDNF did not result in coprecipitated neurotrophins (data not shown), probably because of the relative instability of NGF/BDNF heterodimers, as reported previously (Radziejewski and Robinson, 1993; Arakawa et al., 1994).
Evidence in support of the idea that coexpression of NT-3 with BDNF results in some NT-3 being shunted from the constitutive to the regulated secretory pathway is shown in Figure8. The bar graph (Fig.8A) shows the amount of processed NT-3 in cell lysates as a function of the total amount of NT-3 present in cell lysates and conditioned media. Results indicate that more NT-3 is retained within cells when pro-NT-3 is coexpressed with pro-BDNF-encoding virus as compared with wild type. This result suggests that NT-3 and BDNF are noncovalently associated through heterodimerization and that association of the two leads to intracellular retention of NT-3, perhaps within dense-core vesicles. Examination of a typical SDS gel used in this analysis (Fig.8B) shows that NT-3 and BDNF, which are coprecipitated by the NGF (NT-3-reactive) antibody, are evident within the cell lysate and conditioned medium, suggesting that coinfected cells synthesize and release the NT-3 and BDNF together. In companion experiments, coinfection with VV:pro-BDNF and VV:pro-NGF had no effect on NGF retention as compared with the wild-type coinfection control (data not shown).
The idea that NT-3 is diverted into the regulated secretory pathway is further confirmed by secretion data presented in Figure9. When pro-NT-3 is coexpressed with pro-BDNF, processed NT-3 can be released from AtT-20 cells (Fig.9A) in response to cAMP and from hippocampal neurons by KCl depolarization (Fig. 9B). Thus, release of NT-3 that is coexpressed (and presumably dimerized) with BDNF appears to be regulated by the same extracellular signals that regulate the release of homodimeric BDNF (Mowla et al., 1999). Cell lysates and conditioned media immunoprecipitated with NGF antibodies contained both NT-3 and BDNF, further indicating that the two neurotrophins are synthesized and released together in our culture system.
Finally, we used immunocytochemistry and confocal microscopy to compare the intracellular distributions of NT-3 and BDNF when they are singly expressed or coexpressed in hippocampal neurons. Figure10 shows that in hippocampal neurons infected with 1 MOI of VV:pro-NT-3, NT-3 immunoreactivity is distributed in the perinuclear cytoplasm (Fig. 10A), as was seen in AtT-20 cells (Fig. 5). However, in cells coinfected with 0.5 MOI of VV encoding pro-NT-3 and pro-BDNF, NT-3 immunoreactivity (Fig. 10C) is localized in punctate structures distributed throughout the cell cytoplasm and in the tips of cell processes, an appearance similar to that of BDNF immunoreactivity in cells infected with pro-BDNF alone (Fig. 10B). In control studies, coexpression of pro-NT-3 and pro-NGF did not change the distribution of NT-3, as assessed by immunocytochemistry (data not shown). Furthermore, coexpression of pro-BDNF and pro-NGF did not divert NGF from the constitutive to the regulated pathway as assessed by either immunoprecipitation or immunocytochemistry (data not shown).
Figure 11 compares the distribution in virally infected AtT-20 cells of NT-3 alone and NT-3 coexpressed with BDNF with that of endogenous TGN38, a Golgi marker, and endogenous ACTH, which is packaged within secretory granules of AtT-20 cells. In cells infected with VV:pro-NT-3 alone, immunoreactivity for NT-3 (Fig.11A) and TGN38 (Fig. 11B) colocalize in the perinuclear cytoplasm (Fig. 11C). In contrast, in cells coinfected with VV encoding pro-NT-3 and pro-BDNF, NT-3 immunoreactivity (Fig. 11D) is localized in the perinuclear cytoplasm as well as in punctate structures within the cytoplasm and tips of cell processes. In the same cells, ACTH immunoreactivity is distributed in punctate structures within cell processes (Fig. 11E). In a subpopulation of vesicles, NT-3 and ACTH immunoreactivity colocalize (Fig.11F).
DISCUSSION
Data in this study show that NT-3 is processed and released from the constitutive secretory pathway of hippocampal neurons and AtT-20 cells. Pulse–chase experiments reveal that the NT-3 precursor is rapidly cleaved in cells infected with VV encoding the NT-3 precursor (Fig. 1), with processed NT-3 being evident 30 min after cells are exposed to medium containing radiolabeled amino acids. Over the next 8 hr, most processed NT-3 is released into conditioned medium, a result similar to that reported previously for NGF (Mowla et al., 1999). Immunocytochemical analysis shows that NT-3 is diffusely distributed within the perinuclear cytoplasm (Figs. 5, 10, 11), and colocalizes with TGN38, a marker of the trans-Golgi network (Figs.11A–C). Secretagogues (Figs. 4,9A) and KCl-induced depolarization (Fig. 9B) do not induce the release of radiolabeled NT-3 from virus-infected AtT-20 cells or hippocampal neurons, respectively. Thus, NT-3 release is constant and not dependent on extracellular cues, which is similar to the results we obtained for NGF (Mowla et al., 1999).
Pro-NGF, pro-BDNF, and pro-NT-3 were cleaved in COS-1 cells, which is a constitutively secreting cell line that does not have a regulated pathway. Most pro-BDNF and some pro-NGF (but not pro-NT-3) were released into conditioned medium (Fig. 2). This result could be attributable to pro-BDNF and to a lesser degree pro-NGF not being cleaved as effectively as pro-NT-3 by furin or furin-like enzymes within the TGN. The consensus cleavage site of pro-NT-3 (Arg-Arg-Lys-Arg↓Tyr) is ideally suited for furin-mediated processing, probably even more so than that of pro-NGF (Arg-Ser-Lys-Arg↓Ser) (Decroly et al., 1994). Basic residues at positions -4, -2, -1 are conducive to processing in the constitutive secretory pathway (Watanabe et al., 1992). However, the presence of an additional Arg residue at position -3 in pro-NT-3 may enhance even more the ability of furin to cleave the protein at this site.
Although it has yet to be shown directly with neurotrophin precursors, several lines of evidence suggest that sensitivity to furin-mediated cleavage within the TGN is an important factor in determining whether a protein is sorted to the constitutive or regulated secretory pathway (Brechler et al., 1996). In this study, blocking furin activity with α1-PDX inhibited pro-NT-3 processing in the constitutive pathway and resulted in the constitutive release of unprocessed pro-NT-3 (Fig. 3). In addition, α1-PDX treatment caused a shift in the appearance of NT-3 immunoreactivity from diffuse and perinuclear to punctate and distributed throughout the cell cytoplasm, including in the tips of cell processes (Fig. 5). Also, processed NT-3 was released by cAMP treatment (Fig. 4), which is characteristic of proteins within the regulated secretory pathway. Insertion of furin-sensitive cleavage sites into precursors that are normally processed in the regulated secretory pathway favors release through the constitutive secretory pathway (Oda et al., 1991; Yanagita et al., 1992), which is further evidence of the importance of furin sensitivity in the sorting decision (Jung and Scheller, 1991; Brechler et al., 1996; Mowla et al., 1999).
Increasing the MOI of vaccinia virus also shifted pro-NGF from the constitutive to the regulated secretory pathway (Edwards et al., 1988; Mowla et al., 1999), probably by saturating the ability of furin to cleave pro-NGF as a substrate. However, increasing MOI had little effect on the subcellular localization of NT-3 (data not shown), probably because pro-NT-3 is especially well cleaved in the TGN by furin. In contrast, lipofectamine transfection methods (Fig. 6) resulted in NT-3 immunoreactivity becoming localized within punctate structures throughout the cytoplasm and in the tips of cell processes. Lipofectamine transfection may yield higher intracellular concentrations of neurotrophin precursors in the comparatively small number of cells that are transformed (<10%) when compared with vaccinia virus infection (>90% cells infected). These differences in intracellular levels of the protein can be inferred by comparing NT-3 immunoreactivity in lipofectamine-transfected cells (Fig.6B) with that of vaccinia virus-infected cells (Fig.11A). The differences probably explain why Heymach et al. (1996) and Moller et al. (1998) detected NT-3 within the regulated secretory pathway of AtT-20 and PC12 cells. Similarly, increasing expression levels altered the intracellular distribution of β2-microglobulin in pancreatic β cells of transgenic mice (Allison et al., 1991).
Exogenously applied NT-3 is as effective as BDNF in potentiating synaptic efficacy in hippocampal CA1 neurons, which suggests that NT-3, like BDNF, may normally access the synapse through its activity-dependent release from presynaptic neurons (Kang and Schuman, 1995). However, removing endogenous NT-3 has no effect on long-term potentiation (LTP) in mouse hippocampal CA1 neurons (Chen et al., 1999;Ma et al., 1999). In contrast, blocking endogenous BDNF reduces LTP (Korte et al., 1995). Thus, exogenously applied NT-3 may mimic the effects of BDNF through mechanisms that are unrelated to the way NT-3 normally accesses the synapse (Chen et al., 1999).
Neurotrophin heterodimers have not yet been detected in vivo, even with antibodies that recognize them specifically (Kolbeck et al., 1999). However, neurotrophins can form stable heterodimers either when renatured together or coexpressed in cells (Radziejewski and Robinson, 1993; Arakawa et al., 1994; Jungbluth et al., 1994; Philo et al., 1994; Heymach and Shooter, 1995; Robinson et al., 1995; Treanor et al., 1995). Thus, cells that coexpress neurotrophins such as hippocampal neurons (Maisonpierre et al., 1990;Schecterson and Bothwell, 1992) could produce heterodimeric forms of these proteins. The NT-3/BDNF heterodimer is especially stable (Arakawa et al., 1994), which has allowed its crystal structure to be resolved (Robinson et al., 1995).
In our experiments, coexpressing pro-NT-3 and pro-BDNF resulted in the retention of NT-3 within vesicle-like structures that were distributed throughout the cytoplasm and within cellular processes of both AtT-20 cells and hippocampal neurons, a distribution that was identical to that of BDNF (Mowla et al., 1999). NT-3 was also released together with BDNF in response to secretagogues or depolarization. These data together with our coimmunoprecipitation studies strongly suggest that in our experimental system, NT-3 and BDNF heterodimerize, as shown previously by others (Philo et al., 1994; Heymach and Shooter, 1995). However, confirming that idea will require isolating the heterodimers to purity and characterizing them chemically, which we have not done.
As yet, we do not know how NT-3/BDNF heterodimers form. Protein dimerization normally occurs between monomers of unprocessed precursors in the endoplasmic reticulum (Danielsen, 1990; Zhu et al., 1996), which would yield pro-NT-3/pro-BDNF heterodimers. However, heterodimers could also exist between NT-3, which is efficiently processed in the TGN, and pro-BDNF, which is processed in immature secretory granules. Indeed, in our coimmunoprecipitation experiments, we detect within conditioned medium pro-BDNF along with mature NT-3 and BDNF. Further processing of the NT-3/pro-BDNF heterodimer likely occurs in immature secretory granules to yield heterodimers of mature forms of NT-3 and BDNF.
Others have noted previously that heterodimerization can alter the intracellular trafficking of proteins. For example, the common α-subunit of lutropin, follitropin, and chorionic gonadotropin is constitutively secreted when produced alone; however, heterodimerization with the appropriate β-subunit causes the heterodimer to be sorted and released by the regulated secretory pathway (Blomquist and Baenziger, 1992; Bielinska et al., 1994). Apparently, a single chain of a protein destined for the regulated secretory pathway contains sufficient information to reroute the entire heterodimeric complex.
The finding that pro-NT-3 can be released from either the constitutive or regulated secretory pathways suggests that NT-3 could have multiple functions. The release of homodimeric NT-3 from the constitutive secretory pathway would allow NT-3 to be constantly available as a differentiation and survival-promoting factor for neurons, which appears to be its role during development (for review, seeChalazonitis, 1996). In contrast, when NT-3 heterodimerizes with BDNF, as may occur when both are highly expressed in adult hippocampus (Maisonpierre et al., 1990), NT-3 is sorted to the regulated secretory pathway, where the NT-3/BDNF heterodimer is packaged within vesicles that are released in response to activity. Under these conditions, NT-3 acting at TrkC receptors or NT-3/BDNF heterodimers acting in concert at TrkC and TrkB receptors (Philo et al., 1994) could regulate synaptic transmission and plasticity. Thus, understanding how NT-3 is processed in specific populations of neurons at different times of development could reveal much about its physiological functions.
Footnotes
This work was supported by grants from the Medical Research Council of Canada (MRC) to R.A.M. and N.G.S., and by funding from the National Centers of Excellence Program in Neuroscience to R.A.M. and N.G.S. H.F.F. is supported by an MRC Doctoral Research Award, and S.J.M. is supported by a studentship from the Iranian Ministry of Culture and Higher Education. We thank Amgen for providing the antibody to brain-derived neurotrophic factor.
H.F.F. and S.J.M. contributed equally to this work.
Correspondence should be addressed to Dr. Richard A. Murphy, Director, Montreal Neurological Institute, McGill University, 3801 University Street, Montreal, Quebec, Canada H3A 2B4. E-mail:director{at}mni.lan.mcgill.ca.