Abstract
Expression of neuregulin-2 (NRG2) is intense in a few regions of the adult brain where neurogenesis persists; however, little is understood about its role in developments of newborn neurons. To study the role of NRG2 in synaptogenesis at different developmental stages, newborn granule cells in rat hippocampal slice cultures were labeled with retrovirus encoding tetracycline-inducible microRNA targeting NRG2 and treated with doxycycline (Dox) at the fourth or seventh postinfection day (dpi). The developmental increase of GABAergic postsynaptic currents (GPSCs) was suppressed by the early Dox treatment (4 dpi), but not by late treatment (7 dpi). The late Dox treatment was used to study the effect of NRG2 depletion specific to excitatory synaptogenesis. The Dox effect on EPSCs emerged 4 d after the impairment in dendritic outgrowth became evident (10 dpi). Notably, Dox treatment abolished the developmental increases of AMPA-receptor mediated EPSCs and the AMPA/NMDA ratio, indicating impaired maturation of glutamatergic synapses. In contrast to GPSCs, Dox effects on EPSCs and dendritic growth were independent of ErbB4 and rescued by concurrent overexpression of NRG2 intracellular domain. These results suggest that forward signaling of NRG2 mediates GABAergic synaptogenesis and its reverse signaling contributes to dendritic outgrowth and maturation of glutamatergic synapses.
SIGNIFICANCE STATEMENT The hippocampal dentate gyrus is one of special brain regions where neurogenesis persists throughout adulthood. Synaptogenesis is a critical step for newborn neurons to be integrated into preexisting neural network. Because neuregulin-2 (NRG2), a growth factor, is intensely expressed in these regions, we investigated whether it plays a role in synaptogenesis and dendritic growth. We found that NRG2 has dual roles in the development of newborn neurons. For GABAergic synaptogenesis, the extracellular domain of NRG2 acts as a ligand for a receptor on GABAergic neurons. In contrast, its intracellular domain was essential for dendritic outgrowth and glutamatergic synapse maturation. These results imply that NRG2 may play a critical role in network integration of newborn neurons.
- dentate gyrus
- ErbB4
- neuregulin
- neurogenesis
- synaptogenesis
Introduction
Neuregulins belong to a family of peptide hormones that contains epidermal growth factor (EGF)-like domain. Neuregulin-2 (NRG2) has been identified as a second member of the neuregulins with a domain structure similar to neuregulin-1 (NRG1) (Busfield et al., 1997; Carraway et al., 1997; Chang et al., 1997). Although NRG1 and NRG2 are strongly expressed early in the developing brain, especially in germinal layers (Corfas et al., 1995; Longart et al., 2004), they are expressed in distinct cell populations in the brain and display distinct subcellular distribution. In the adult brain, the expression of NRG1 becomes low and sporadic but widespread over the brain (Longart et al., 2004; Liu et al., 2011). In contrast, intense expression of NRG2 persists in three regions of an adult brain: the cerebellum, olfactory bulb, and the hippocampal dentate gyrus (Carraway et al., 1997; Longart et al., 2004). NRG2 is preferentially expressed in dendrites, whereas NRG1 is targeted to the axon as well as dendrites (Longart et al., 2004). Such distinct temporal and spatial expression patterns of NRG2 imply that it may have nonredundant biological functions.
Developmental consequences induced by depletion or knock-out of the NRG1 gene or exogenous NRG1 injection have been extensively studied over the last decades. Neuregulins can function as a ligand for ErbB4, an EGF receptor. NRG1/ErbB signaling has been implicated in GABAergic circuit formation, axon myelination, and synaptic plasticity (Ghashghaei et al., 2006; Li et al., 2007; Woo et al., 2007; Fazzari et al., 2010; Abe et al., 2011; Ting et al., 2011; Yin et al., 2013). Furthermore, type III NRG1 plays a role in morphological development of cortical neurons independently of ErbB kinase activity (Chen et al., 2008; Chen et al., 2010). Although NRG2/ErbB4 signaling has been implicated in the proliferation of neural stem cells and neuroblasts in the subventricular zone (Ghashghaei et al., 2006), little is understood about whether it plays a role in synaptogenesis of newborn neurons.
In general, GABAergic synaptogenesis precedes glutamatergic synaptogenesis in the early developmental stage of newborn neurons. It has been demonstrated that depolarization induced by GABAergic synaptic inputs in immature neurons is important for AMPA receptor insertion to nascent glutamatergic synapses that express only NMDA receptors (Akerman and Cline, 2006; Wang and Kriegstein, 2008), suggesting that GABAergic synaptogenesis is a prerequisite for maturation of glutamatergic synapses in immature neurons. Given that NRG1/ErbB4 signaling plays a critical role in GABAergic synapse formation (Fazzari et al., 2010), it should be differentiated whether the effects of neuregulin signaling on glutamatergic synapse maturation are direct or secondary to its effect on GABAergic synaptogenesis. Whereas CNS-specific knock-out of ErbB2/4 impaired dendritic spine maturation (Barros et al., 2009), a recent study has shown that conditional knock-out of ErbB4 in neocortical pyramidal neurons caused no effect on excitatory synapses (Fazzari et al., 2010). Therefore, cell- and developmental-stage-specific gene manipulation is essential to elucidate biological functions exerted directly by neuregulins.
NRG2 is the major type of neuregulin expressed in hippocampal dentate granule cells (GCs). We set out to address the question of whether NRG2 plays any cell-autonomous role in the development of newborn GCs, especially during two critical developmental periods when GABAergic and glutamatergic synapses are established. To this end, we depleted NRG2 at different developmental stages of newborn GCs using a tetracycline-inducible (Tet-On) expression system (Gossen and Bujard, 1992). Here, we show that NRG2 plays a central role in GABAergic synaptogenesis and glutamatergic synapse maturation in newborn GCs via forward and reverse signaling pathways, respectively.
Materials and Methods
Organotypic slice culture.
All experiments were performed with the approval of the animal experiment ethics committee at the Seoul National University College of Medicine. The entorhino-hippocampi of postnatal day 6–9 (P6–P9) Sprague Dawley rat pups (Charles River) of either sex were cultured by using previously described membrane interface techniques (Lee et al., 2012b). Briefly, the transverse hippocampal slices (thickness, 300 μm) were obtained with vibratome (DTK-1000 ZERO 1; Dosaka) and carefully placed on the surface of 30 mm porous (0.4 μm) membrane insert (Millicell-CM; Millipore) set in a 6-well plate on 1 ml of culture medium. Because deprivation of major synaptic inputs of GCs may alter the responsiveness to NRG2, we took great care to preserve the perforant pathway and entorhinal cortex in the organotypic culture. The culture medium was a mixture of 50% minimum essential medium, 25% horse serum, 24% Eagle's buffered salt solution, and 1% penicillin–streptomycin (PS). Glucose was added to reach a final concentration of 36 mm. To examine the role of NRG2 in synaptogenesis, we infected the slices with retrovirus immediately after transferring slices on membrane. After 4 d in culture, the medium was changed to serum-free Neurobasal medium with 2% B-27 supplement, 1% GlutaMAX-I, 1% PS, and 5 mm glucose added. Culture medium was changed every other day. Slice cultures were maintained at 36°C in a 5% CO2 humidified incubator. All media and reagents for organotypic culture were purchased from Invitrogen.
Retroviruses, conditional knock-down, and conditional transgene expression.
Newborn GCs were labeled using vesicular stomatitis virus glycoprotein pseudotyped recombinant retrovirus encoding EGFP and microRNA. These two genes were cloned downstream of long terminal repeat (LTR) promoter and a Tet-On promoter, respectively, in the same Moloney murine leukemia virus (MMLV)-derived retroviral vector (see Fig. 1C). Therefore, the expression of miR30-based short-hairpin RNA (shRNAmir) was under the control of the tetracycline-inducible expression system (Gossen and Bujard, 1992). We targeted the shRNAmir by inserting the partial sequence of NRG2 (5′-GGTGTGTCACTCGCCTGCTACT-3′) into the backbone of miR30, an endogenous microRNA (Dickins et al., 2005). This will be referred to as “shNRG2mir.” The fluorescent protein mCherry-targeting sequence (5′-GAACATCAAGTTGGACATCACC-3′) was used for nontargeting control of shRNAmir (shNTmir). Figure 1C shows the schematic diagram for the expression cassette of EGFP, reverse tetracycline transactivator 3 (rtTA3), and shRNAmir. We engineered retroviral construct by inserting this cassette (2.6 kb) between the LTRs of EGFP-CL retroviral vector (Lee et al., 2012a). For rescue experiments, C-terminal myc-tagged intracellular domain of NRG2 (NRG2-ICD) was cloned downstream of the Tet-On promoter in the TagRFP-CL retroviral vector, where TagRFP was substituted instead of the EGFP in EGFP-CL (see Fig. 7A1). To package retroviruses, each of these plasmid DNAs were transfected into 293GPG packaging cells using Lipofectamine 2000 (Invitrogen). Supernatant containing viral particles was harvested at 3–10 d after transfection and centrifuged at 6000 × g for 16 h at 4°C. The viral pellet was then resuspended in 1/500 of the original volume of DPBS (Invitrogen). The dentate gyrus of a hippocampal slice culture was infected with the virus solution (0.3 μl) within 5 min after placement of hippocampal slices on the membrane insert as described previously (Namba et al., 2007; Lee et al., 2012a). For conditional knock-down or conditional expression, supplement of doxycycline (Dox, 2 μg/ml) in culture medium was started 2 d before the time that knock-down or overexpression was desired.
Single-cell RT-PCR.
Hippocampal newborn GCs were labeled by retrovirus encoding EGFP. To obtain total mRNA of newborn GC, whole-cell patch-clamp was attained on the EGFP-expressing soma of a dentate GC at 5–6 days postinfection (dpi). Pipette solution was composed of the following (in mm): 140 K-gluconate, 5 di-Tris-phosphocreatin, 5 NaCl, 4 MgATP, 0.4 Na2GTP, 15 HEPES, 2.5 Na-pyruvate, pH 7.3 adjusted with KOH, together with 10% RNaseOUT (v/v), a recombinant ribonuclease (RNase) inhibitor (Invitrogen). After rupturing the giga-ohm-sealed cell membrane patch, cytosolic contents were sucked into the glass pipette by applying negative pressure. To prevent the pipette solution from being contaminated by RNase, the whole-cell patch mode was converted to outside-out configuration by gently pulling up the pipette away from the cell. The pipette tip containing the cytosolic contents was broken into a 0.2 ml PCR tube with 7 μl of premixture containing 1 μl of dNTP (25 mm each), 1 μl of 0.1 m DTT, 1 μl of random hexamer oligonucleotides as primers, and 4 μl of 5× first-strand buffer (Invitrogen). Then, 1 μl of SuperScript III reverse transcriptase (200 U/μl; Invitrogen) and RNase-free water were added to make a total volume of 20 μl of solution. All subsequent steps for synthesizing cDNA followed the user manual of SuperScript III reverse transcriptase. Random primers were annealed to mRNA template by incubating at 65°C for 5 min. cDNA was synthesized under the following conditions: 25°C for 5 min and 50°C for 60 min. The reaction was terminated by heating at 70°C for 15 min. Synthesized single-strand cDNA was amplified by PCR with GoTaq Green Master Mix (Promega) and the following primers: NRG2β forward 5′-CAGCAGTTCGCAATGGTCAACT-3′, reverse 5′-GTAATCTGCCATCTGGATCTCC-3′; β-actin forward 5′-GCCGCATCCTCTTCCTCCCTG-3′, reverse 5′-GGGGCCGGACTCATCGTACTC-3′. The PCR products were examined by standard agarose gel electrophoresis.
In situ hybridization and immunohistochemistry.
For in situ hybridization, a postnatal week 4 (PW4) rat was perfused by PBS and subsequently fixed with 4% paraformaldehyde (PFA). Brain was postfixed with 4% PFA and then dipped with 30% sucrose in PBS. After sinking, the brain was embedded in optimum cutting temperature compound and sectioned serially into 16 μm sections. The sequence of the ErbB4 mRNA target probe was manufactured by Advanced Cell Diagnostics. A probe targeting the bacterial gene dapB was used as a negative control. In situ hybridization of ErbB4 mRNA was performed on sectioned samples according to the RNAscope multiplex fluorescence kit. Briefly, tissue sections were dried at 50°C for 30 min and then fixed with 4% PFA for 15 min; dehydrated by 50%, 70%, and 100% ethanol gradually for 5 min; and pretreated with the probe kit before hybridization. After hybridization with ErbB4 mRNA at 40°C for 2 h, the RNAscope multiplex fluorescence kit was used for signal amplification. Fluorescence detection was performed using Atto 550 (red fluorescence). Immunohistochemistry was performed using a primary antibody against the doublecortin (DCX, 1:500; Santa Cruz Biotechnology) for 1 h at 37°C. Alexa Fluor 488-conjugated donkey anti-rabbit IgG was applied for 30 min (1:500) with Hoechst 33343 for staining nuclei. The sections were washed three times and mounted.
Western blotting.
HEK293 cells were seeded in 100 mm culture dishes at ∼70% confluence and transfected with C-terminally myc-tagged NRG2 (NRG2-myc) plus shNRG2mir or plus shNTmir (as control) using the calcium phosphate protocol. Mouse cDNA of NRG2 was purchased from Origene (catalog #MR217926). After culture for 48 h, the cells were washed twice with PBS (pH 7.4) solubilized in ice-cold lysis buffer containing 20 mm Tris (pH 7.4 adjusted with HCl) 140 mm NaCl, 10% sucrose, 1 mm EDTA, 1 mm Na3VO4, 1% NP-40 (v/v), and 0.2% protease inhibitor mixture. Cell lysates were mixed with equal volume of the 2× SDS sample buffer and boiled for 5 min. Proteins were separated by SDS-PAGE and transferred to PVDF membranes (Millipore). The resulting blots were blocked for 1 h in PBS plus 0.1% Triton X-100 (0.1% PBST) containing 5% skim milk (blocking solution) and incubated overnight at 4°C with specific primary antibodies: mouse monoclonal anti-c-myc (1:1000; Cell Signaling Technology) or mouse monoclonal anti-β-actin (1:5000; Santa Cruz Biotechnology) as loading controls. Immunoblots were washed with washing buffer containing 1% NP-40 and 0.1% SDS in PBS for 1 h, then with PBS twice each for 30 min at room temperature. Blots were blocked in blocking solution for 30 min and incubated with horseradish peroxidase-conjugated goat anti-mouse IgG (1:5000; Jackson ImmunoResearch). After washing with washing buffer and PBS, detection was performed using enhanced chemiluminescence reagent (GE Healthcare Bioscience). The membranes were then exposed to x-ray films (Agfa Gevaert).
Immunohistochemistry.
Expressions of NRG1 and NRG2 in the hippocampal slice cultures and tetracycline-inducible knock-down of NRG2 or expression of myc-tagged NRG2-ICD were confirmed by immunostaining of endogenous NRG1 and NRG2 or myc in organotypic cultured hippocampal slices. Dox treatment was started 3–5 d before fixation. Slices were fixed overnight at 4°C by submersion in 4% PFA dissolved in PBS. The next day, after 3 washes with PBS containing 0.3% Triton X-100 (0.3% PBST), slices were incubated in blocking solution (5% donkey serum in 0.3% PBST) for 1 h at room temperature and then with rabbit polyclonal anti-NRG2 IgG (1:500; Millipore; see Fig. 1E) or mouse monoclonal anti-NRG1 IgG (1:200; Millipore; see Fig. 1F) or mouse monoclonal anti-myc (1:2000; Cell Signaling Technology; see Fig. 7A2) diluted in blocking solution overnight at 4°C. After 3 washes in 0.3% PBST for 10 min, slices were incubated with Cy3-conjugated goat anti-rabbit (1:400; Invitrogen), Alexa Fluor 647-conjugated donkey anti-mouse (1:200; Jackson ImmunoResearch), or FITC-conjugated donkey anti-mouse (1:200; Jackson ImmunoResearch) diluted in blocking solution for 1 h at room temperature. Finally, the slices were washed 3 times in 0.3% PBST store in PBS until confocal imaging was performed.
Electrophysiology.
Postsynaptic current (PSC) was recorded in EGFP-positive newborn GCs using whole-cell patch-clamp techniques while perfusing a slice with artificial CSF (aCSF). The aCSF contained the following (in mm): 124 NaCl, 26 NaHCO3, 3.2 KCl, 2.5 CaCl2, 1.3 MgCl2, 1.25 NaH2PO4, and 10 glucose, pH 7.4 adjusted by saturating with carbogen (95% O2, 5% CO2). PSC was evoked by stimulation (200 μs duration; 1–10 V intensity) of axons passing through the inner molecular layer (IML) of hippocampal dentate gyrus using a concentric bipolar electrode with 30 s interstimulus interval. The stimulation electrode was placed at least 200 μm apart laterally from the cell under recording to avoid direct stimulation of a recorded cell. To isolate GABAergic PSCs (GPSCs), the membrane potential was held at 0 mV, which is the reversal potential of excitatory PSCs (EPSCs). The internal pipette solution for recording GPSCs contained the following (in mm): 140 K-gluconate, 5 di-Tris-phosphocreatin, 5 NaCl, 4 MgATP, 0.4 Na2GTP, 15 HEPES, 2.5 Na-pyruvate, 1 EGTA, pH 7.3 adjusted with KOH. For isolation of EPSCs, we could not use a GABAA receptor blocker because it induces epileptiform activity. Instead, GPSCs were blocked intracellularly using a CsF-based pipette solution containing the following (in mm): 140 CsF, 2 MgCl2, 10 HEPES, 1 EGTA (Marchionni and Maccaferri, 2009; Schwartz et al., 2011), and a Cl− channel blocker, 4,4′-diisothiocyanatostilbene-2,2′-disulfonic acid (DIDS, 1 mm) (Hollrigel et al., 1998), pH 7.3 adjusted with CsOH. AMPA receptor- and NMDA receptor-mediated EPSCs (AMPA-EPSCs and NMDA-EPSCs) were recorded at holding potentials of −60 and +40 mV, respectively. The amplitudes of GPSCs and AMPA-EPSCs were measured at their peak; the amplitude of NMDA-EPSCs was measured at 50 ms after stimulation to exclude AMPA-EPSC contribution. The paired-pulse ratio (PPR) was calculated from the mean amplitude of the second PSCs divided by the mean amplitude of the first PSCs. The interpulse interval for GPSCs and NMDA-EPSCs was 500 ms and that of AMPA-EPSCs was 30 ms. The AMPA-to-NMDA EPSC ratio (AMPA/NMDA ratio) was calculated by dividing the peak amplitude of AMPA-EPSCs by the amplitude of NMDA-EPSCs measured at 50 ms, similar to the procedure described by Mierau et al. (2004). To measure monosynaptic GPSCs, monopolar stimulation electrode (a glass pipette filled with aCSF) was placed ∼100 μm lateral from the recording position. Monosynaptic responses were evoked by extracellular stimulation (200 μs duration; 1–25 V intensity) with 30 s interstimulus interval in the presence of 20 μm CNQX and 50 μm APV to block glutamatergic transmission. The amplitudes of monosynaptic GPSCs compared in Figures 3C and 6B were obtained from a minimal stimulation protocol. The first criterion for the minimal stimulation is an abrupt appearance of synaptic responses as a gradual increase in the stimulation intensity. There should be a distinct threshold for such all-or-none activation of synaptic responses. Moreover, further increase in the stimulation intensity should not change the synaptic responses by ∼20% increase in stimulus intensity from the threshold (Dvorzhak et al., 2013). Typical voltage intensities required for minimal stimulation ranged between 5 and 12 V.
In vivo experiments.
P16–P22 SD rats were anesthetized by inhalation of ∼1–4% isoflurane, shaved, and then placed in a stereotaxic frame (Neurostar; Stoelting). All surgical procedures were performed under aseptic conditions. Retrovirus encoding EGFP plus Tet-On/shNRG2mir was infused through a glass micropipette which was prepared using a vertical puller (Narishige PC-10) and a pipette beveler (beveling angle, 30°; Narishige EG-4). Virus solution of 0.5 μl was injected at a rate of 0.15 μl/min by a 10 μl Hamilton syringe attached to a digital microinjector (Stoelting). The injection coordinates were −4.8 mm A/P, ± 4.4 mm M/L, −4.6 mm D/V from the bregma. The glass pipette was slowly removed after holding it in the injection site for 3 min to allow for the viral diffusion. After suturing, the rats were returned to the cages and lidocaine/antibiotics ointment was applied over the sutured region. Rats were given drinking water containing 2 mg/ml Dox plus 2% sucrose (Dox-containing water) or 2% sucrose alone (Dox-free water) from 5 dpi or from 9 dpi. The drinking water was changed every other day. Acute hippocampal slices (thickness, 300 μm) were prepared from 12–21 dpi (P28–P40) rats as described in Lee et al. (2007).
Drugs.
All chemicals were purchased from Sigma-Aldrich except CNQX and bicuculline methiodide, which were from Tocris Bioscience; APV, which was from Abcam; and AG-1478, which was from Calbiochem. Stock solutions were stored at −20°C and diluted to the desired concentration in aCSF just before use. Anti-c-erbB4 Ab-3 mouse monoclonal antibody (MS-304) was purchased from Thermo Scientific.
Sholl analysis and measurement of total dendritic length.
EGFP fluorescence expressed in newborn GCs were imaged using a confocal laser scanning microscope (FV300; Olympus) and a 40× water-immersion objective. For analysis of dendritic morphology, 3D reconstructions were made using the Simple Neurite Tracer plugin in the ImageJ-based image processing package Fiji (Longair et al., 2011). The dendritic complexity and length were quantified by Sholl analysis plugin and tracing algorithms in NeuronJ plugin, respectively. For Sholl analysis, the concentric circles were drawn every 10 μm from the first concentric circle, which had a diameter 5 μm encircling the soma, and the numbers of branch intersections were counted in each circle.
Data analysis.
Data were analyzed using Igor-Pro (version 6.1; WaveMetrics) or IBM SPSS statistics version 21.0 software. Statistical data are expressed as mean ± SEM and n indicates the number of cells studied. If not mentioned otherwise, the statistical significance of differences between two experimental conditions was evaluated using Student's t test. Comparisons between input–output curves of synaptic currents and between results of Sholl analysis were analyzed using repeated-measures (RM) one-way ANOVA (see Figs. 3A1, 4A, 5B, 7D2). To compare between cumulative lengths of neurites, the Kolmogorov–Smirnov (K-S) test was used (see Figs. 5C, 7D3). Differences were considered as significant when p < 0.05 (n.s. indicates no statistical significance; *p < 0.05; **p < 0.01; ***p < 0.001).
Results
Confirmation of NRG2 expression in newborn GCs and conditional knock-down strategy of NRG2
Although NRG2 is highly expressed in the GC layer of dentate gyrus of adult hippocampus (Anton et al., 2004; Longart et al., 2004), it is not clear whether newborn GCs express NRG2. To address this question, newborn GCs from cultured rat hippocampal slice were labeled with EGFP-expressing retrovirus and then their mRNA was analyzed by single-cell RT-PCR (see Materials and Methods for details). There are two alternative splicing isoforms of NRG2, α and β, and only the β isoform is capable of stimulating ErbB4 (Hobbs et al., 2002). The cytoplasm of EGFP-positive single newborn GC was aspirated using a whole-cell patch pipette (Fig. 1A1) and mRNA therein was amplified using a primer pair specific for an ErbB4-stimulating isoform, NRG2β. NRG2β transcript was detected in 7 of 8 newborn GCs and β-actin, used as positive control, was detected in all samples (Fig. 1A2).
We further examined the expressions of NRG1 and NRG2 in hippocampal slice cultures at 7 and 14 dpi (equivalent to PW2 and PW3 in vivo, respectively) using immunohistochemistry. Consistent with Longart et al. (2004), the NRG1 immunosignal was weaker in the dentate gyrus compared with the CA1 and CA3 regions (Fig. 1B1), suggesting that NRG2 may be a major ligand for ErbB4 in the dentate gyrus. Next, we investigated whether newborn GCs express the NRG2 receptor ErbB4. It has been noted that ErbB4 is expressed exclusively in GABAergic interneurons, at least in the neocortex and hippocampus (Vullhorst et al., 2009; Fazzari et al., 2010). Nevertheless, the expression of ErbB4 in newborn GCs remains unknown. To determine whether immature GCs express ErbB4, we doubly stained the hippocampus for ErbB4 transcripts and DCX. The former was stained by in situ hybridization and the latter, which is a marker of immature GCs (Rao and Shetty, 2004), was stained by immunohistochemistry. This double staining revealed that the signal of ErbB4 transcripts is noise level in most DCX-immunoreactive cells of the dentate gyrus (0.59 ± 0.14, n = 180, 3 rats, Fig. 1B2). In contrast, some cells scattered in the dentate gyrus showed significantly many ErbB4 fluorescent spots (44.49 ± 3.17, n = 45) that were presumably inhibitory interneurons. Therefore, it is unlikely that NRG2 on newborn GCs act as an autocrine ligand.
To study the role of NRG2 in GABAergic and glutamatergic synaptogenensis on newborn GCs, we tried to knock down the NRG2 transcripts specifically in newborn GC using retrovirus. Because NRG2/ErbB4 signaling regulates the proliferation of neuroblasts in the subventricular zone (Ghashghaei et al., 2006), constitutive knock-down of NRG2 may suppress the proliferation of neural progenitor cells in the dentate gyrus. Therefore, we designed a cassette encoding shNRG2mir under the control of the Tet-On promoter (Fig. 1C; see Materials and Methods for details; Gossen and Bujard, 1992) and inserted it into the MMLV retroviral vector. This retroviral construct enabled us to control the period of NRG2 knock-down by treatment with Dox (2 μg/ml). In addition, the cassette encodes the EGFP gene downstream of the constitutively active LTR promoter, so we could label newborn GCs infected by the retrovirus regardless of Dox treatment (Fig. 1C).
The knock-down efficiency of shNRG2mir was tested in HEK293 cells heterologously expressing NRG2-myc together with shNRG2mir or shNTmir. When the HEK293 cells were treated with Dox (2 μg/ml) for 48 h, shNRG2mir, but not shNTmir, almost depleted NRG2-myc. In untreated cells, neither shNTmir nor shNRG2mir depleted NRG2-myc (Fig. 1D). Next, to test whether shNRG2mir efficiently depletes endogenous NRG2 in newborn GCs, we compared immunofluorescence of NRG2 in EGFP-positive newborn GCs at 7 dpi grown in the rat hippocampal slice cultures under control conditions and those treated with Dox from 4 dpi. The immunoreactivity of NRG2 was significantly lower in the Dox-treated newborn GCs compared with the untreated GCs (Fig. 1E, untreated, 940.97 ± 79.87, n = 9 vs Dox-treated, 558.60 ± 21.22, n = 27, p < 0.001), whereas NRG1 immunoreactivity was not affected by shNRG2mir (Fig. 1F). Repeating the same experiments for newborn GCs at 14 dpi that were untreated or treated with Dox from 10 dpi, we obtained similar results (Fig. 1E2, untreated, 822.69 ± 53.33, n = 11 vs Dox-treated, 466.55 ± 35.32, n = 22, p < 0.001), indicating that shNRG2mir efficiently depletes endogenous NRG2 in newborn GCs and that knock-down can be induced by Dox treatment.
Developmental changes of postsynaptic currents in newborn GCs under control conditions
Before studying the effect of NRG2 depletion, we examined the normal developmental increase in the PSC of newborn GCs. Newborn GCs grown in rat hippocampal slice cultures were identified by expression of EGFP (Fig. 2A). At different dpi's, the IML of the hippocampal dentate gyrus was stimulated to evoke GPSCs, AMPA-EPSCs, and NMDA-EPSCs (Fig. 2B). The K-gluconate-based pipette solution containing 5 mm Cl− was used for recordings of GPSCs. In hippocampal dentate gyrus, glutamatergic afferent fibers, such as perforant pathways and hilar mossy cell axons, are mostly confined to the molecular layer and run in parallel with the GC layer (Buckmaster et al., 1992; Witter, 2007; Chancey et al., 2014), whereas GABAergic axon fibers are highly branched and convoluted over all three layers of dentate gyrus (Soriano and Frotscher, 1989; Bartos et al., 2001; Markwardt et al., 2011). Because a bipolar stimulation electrode was placed at least 200 μm laterally apart from the recorded newborn GC, the electrode is more likely to stimulate glutamatergic afferent fibers rather than GABAergic ones. Consistently, putative GPSCs, which were recorded as an outward PSC at the reversal potential of EPSCs (0 mV), were inhibited not only by bicuculline (20 μm), a GABAA receptor blocker, but also by CNQX (20 μm), an AMPA receptor blocker (Fig. 2C), implying that the GPSCs evoked by IML stimulation are caused by bisynaptic feedforward GABAergic inputs (Fig. 2B).
AMPA-EPSCs and NMDA-EPSCs were recorded using a CsF-based pipette solution containing 1 mm DIDS to block Cl− current (see Materials and Methods for details). AMPA-EPSCs were evoked at a holding potential of −60 mV and completely attenuated by CNQX (20 μm) (Fig. 2D1). NMDA-EPSCs were evoked at a holding potential of +40 mV and inhibited by 50 μm APV, an NMDA receptor blocker (Fig. 2D2). The input–output curves for the three kinds of PSCs in newborn GCs were obtained by plotting the amplitudes of evoked PSCs as a function of stimulus intensity. Figure 2E shows mean input–output curves of GPSCs, AMAP-EPSCs, and NMDA-EPSCs at different dpi's of newborn GCs. Because most of these curves reached a plateau at the stimulation voltage of 6 or 7 V, the mean values of GSPCs and EPSCs at 10 V were collected and plotted as a function of the age of newborn GCs denoted as dpi (Fig. 2F). This plot represents the normal time courses for the developmental increases of synaptic inputs to newborn GCs grown in slice cultures. The evoked GPSCs distinctly appeared in newborn GCs as early as 6 dpi and their amplitude was steeply increased until 10 dpi. After 10 dpi, the evoked GPSC amplitude did not further increase. Conversely, AMPA-EPSCs were negligible until 11 dpi and then continuously increased at least to the oldest age we studied (∼16 dpi). NMDA-EPSCs were observed earlier than AMPA-EPSCs and increased gradually. Because the increase rate of NMDA-EPSCs was less steep than that of AMPA-EPSCs, the AMPA/NMDA ratio increased developmentally (see Figs. 2F, 4C).
Expression of NRG2 is essential for GABAergic synapse formation but dispensable for maintenance in newborn GCs
We studied whether depletion of NRG2 has any effect on the developmental changes of GPSCs. Figure 1E shows that NRG2 is depleted to ∼50% in the 3 d after starting Dox treatment. Therefore, we started to treat cultured hippocampal slices with Dox from 4 dpi and maintained the Dox treatment until the day of the experiment to deplete NRG2 during the GPSC-increasing phase at 6–9 dpi. We obtained input–output curves for mean amplitudes of GPSCs recorded from control and Dox-treated newborn GCs at different dpi's. Typically, GPSCs started to be evoked by stimulation of IML at 3 V and their amplitude became steady at 6 V and higher stimulation voltages. Amplitudes of GPSCs were significantly lower in Dox-treated newborn GCs than those in control conditions at both ages (Fig. 3A1; control vs Dox, F(1,35) = 12.03, p = 0.001 at 7 dpi; F(1,15) = 24.04, p < 0.001 at 11 dpi, RM one-way ANOVA). The effect of NRG2 depletion on GPSCs is summarized in Figure 3A2, which displays the mean amplitude of GPSCs evoked at 10 V as a function of dpi. This plot demonstrates that the depletion of NRG2 significantly suppresses the developmental increase of GPSCs.
The above results indicate that NRG2 is essential for developmental increase in GABAergic inputs at 6–9 dpi, which may be a critical period for GABAergic synapse formation under our experimental conditions (Fig. 2F). To address the question of whether NRG2 is necessary after this critical period, the hippocampal slice cultures were treated with Dox from 10 dpi and GPSCs in the Dox-treated newborn GCs were examined at 13 or 14 dpi. As shown in Figure 3A3, Dox treatment at this age had no significant effect on GPSC amplitudes, arguing against a role of NRG2 in maintenance of GABAergic synapses (control vs Dox-treated from 10 dpi, p > 0.1). To confirm this notion, we started the Dox treatment earlier. The Dox treatment starting at 7 dpi might be sufficient for depleting NRG2 just after the critical period (9 or 10 dpi) because knock-down of NRG2 occurs, at the latest, 2 or 3 d after starting Dox treatment (Fig. 1E). This earlier start of Dox treatment also had no significant effect on GPSCs measured in newborn GCs between 9 and 14 dpi (Fig. 3A3, control vs Dox-treated from 7 dpi, p > 0.1). Figure 3A4 shows the age dependence of NRG2 knock-down effects on the GPSCs. Mean values of GPSC amplitudes were measured in newborn GCs older than 9 dpi, when GPSC amplitudes reached a plateau. Dox treatment from 4 dpi, but not from 7 or 10 dpi, significantly reduced the GPSC amplitude (Fig. 3A4, control, 0.950 ± 0.054 nA, n = 65; Dox-treated from 4 dpi, 0.306 ± 0.032 nA, n = 27, p < 0.001; Dox-treated from 7 dpi, 0.905 ± 0.054 nA, n = 39, p = 0.577; Dox-treated from 10 dpi, 0.889 ± 0.071 nA, n = 14, p = 0.611). These results demonstrate that NRG2 is necessary for GABAergic synapse formation during the critical period (6–9 dpi), but, after this critical period, it is dispensable for the maintenance of GABAergic synapses in newborn GCs.
Next, we verified the above notions in monosynaptic GPSCs in slice cultures (ex vivo) and in vivo. Monosynaptic GPSCs were evoked by local stimulation of GC layer ∼70 μm apart from the recorded cell in the presence of AMPA and NMDA receptor blockers in the bath solution (Fig. 3B1) and recorded as outward PSCs at the holding potential of 0 mV. This outward PSC was completely abolished by bicuculline, indicative of monosynaptic GPSCs (Fig. 3B2). A minimal stimulation protocol was used to evoke monosynaptic GPSCs (Fig. 3B3, see Materials and Methods for details). Consistent with the results of feedforward GPSCs, the monosynaptic GPSCs recorded at 14 or 15 dpi ex vivo were suppressed by early Dox treatment, but not by late Dox treatment (Fig. 3C1). For in vivo experiments, newborn GCs were labeled by stereotaxic injection of the same retrovirus used in ex vivo experiments into the hippocampal dentate gyrus of rats (16–22 d old). We studied monosynaptic GPSCs in the acute slice of such rats after feeding them with Dox-free or Dox-containing (2 mg/ml) water. Because maturation of newborn GCs is faster at a younger age (Overstreet-Wadiche et al., 2006a), Dox feeding started 1 or 2 d later than ex vivo, that is, at 5 and 9 dpi. The amplitude of GPSCs recorded 10 d later were significantly suppressed by Dox feeding from 5 dpi, but not by Dox feeding from 9 dpi, confirming the results of ex vivo experiments (Fig. 3C2).
NRG2 is essential for functional maturation of glutamatergic synapses and dendritic growth in newborn GCs
During the early postnatal week, GABAergic inputs exert depolarizing influences on newborn neurons. Perturbation of such GABA-induced depolarization by overexpression of KCC2 or knock-down of NKCC1 blocks normal development of AMPA receptor-mediated neurotransmission (Akerman and Cline, 2006; Ge et al., 2006), suggesting that GABAergic synaptic activity may play a permissive role in the development of glutamatergic synapses. To study the direct roles of NRG2 in the development of glutamatergic synapses, depletion of NRG2 should start after the critical period in order not to interfere with the GABAergic synapse formation. To this end, we started to treat the slice cultures with Dox at 7 dpi (referred to as late Dox treatment), which had no significant effect on GPSCs (Fig. 3A3,A4). Figure 4A shows input–output curves for mean amplitudes of AMPA-EPSCs and NMDA-EPSCs evoked by stimulation of IML at 12 and 15 dpi of newborn GCs grown in control or Dox-treated slices. At 12 dpi, neither AMPA-EPSC nor NMDA-EPSC amplitudes were significantly affected by NRG2 knock-down (Fig. 4A1, AMPA-EPSC, F(1,16) = 2.17, p = 0.160; Fig. 4A2, NMDA-EPSC, F(1,17) = 2.33, p = 0.145, RM one-way ANOVA). However, at 15 dpi, both amplitudes were significantly lower in the Dox-treated newborn GCs (Fig. 4A1, AMPA-EPSC, F(1,16) = 15.2, p < 0.001; Fig. 4A2, NMDA-EPSC, F(1,17) = 6.78, p = 0.019, RM one-way ANOVA). The late Dox treatment completely suppressed the developmental increase in AMPA-EPSCs and partially suppressed the NMDA-EPSCs to ∼40% of the control (Fig. 4A,C1). These findings are summarized in Figure 4B, which displays developmental changes of the mean amplitudes for AMPA-EPSCs and NMDA-EPSCs evoked by 10 V stimulation at control and Dox-treated newborn GCs. The differential effects of NRG2 knock-down on the AMPA-EPSCs and NMDA-EPSCs are more clearly demonstrated by comparing the AMPA/NMDA ratio of control and Dox-treated newborn GCs. AMPA/NMDA ratio was estimated from AMPA-EPSCs and NMDA-EPSCs that were measured in the same cell and evoked by the same stimulation intensity (10 V). Developmental increase of the AMPA/NMDA ratio in newborn GCs was abolished by knock-down of NRG2 (Fig. 4C2). Because nascent glutamatergic synapses express only NMDA receptors and then AMPA receptors are added as they are matured, the AMPA/NMDA ratio is an index for maturity of glutamatergic synapses (Wu et al., 1996; Akerman and Cline, 2006; Haas et al., 2006). These results indicate that NRG2 is essential for the maturation of glutamatergic synapses in newborn GCs.
To test whether NRG2 knock-down has any effect on dendritic growth, we compared the morphology of newborn GCs in hippocampal slices at different dpi's under control or late Dox treatment conditions (Fig. 5A). The complexity of dendritic arbor was quantified using Sholl analysis (see Materials and Methods for details). The complexity and the total length of dendritic arbors in the Dox-treated GCs were significantly lower than the control GCs, not only at 14 dpi, but also at 10 dpi (Fig. 5B, Scholl analysis, p < 0.001 at both dpi's, RM one-way ANOVA; Fig. 5C, cumulative distributions of total dendritic length, p < 0.01, K-S test). The developmental increase of mean values for total dendritic length was significantly retarded in the Dox-treated GCs (Fig. 5D). Considering that NMDA-EPSCs in the Dox-treated GCs were not significantly different from the control GCs until 13 dpi (Fig. 4B2), the effect of Dox on the dendritic growth emerged 4 d earlier than that on EPSCs. Because the Dox-induced impairment was specific to dendritic development between 10 and 13 dpi, NRG2 may have a role in the morphological development rather than glutamatergic synaptogenesis during this period. However, it is not clear whether the lack of developmental increase in the AMPA/NMDA ratio is caused by NRG2 depletion itself or secondary to impaired dendritic arborization (see Discussion).
GABAergic synapse formation of newborn GCs is mediated by ErbB4 tyrosine kinase
Neuregulins are known as ligands of ErbB family of receptor tyrosine kinases (Iwakura and Nawa, 2013). Although NRG2 can bind to both ErbB3 and ErbB4, the NRG2-induced tyrosine kinase activity may be mediated by ErbB4 because ErbB3 lacks kinase activity. To test the involvement of ErbB4 in the downstream signaling of NRG2, we investigated the effect of AG-1478 (10 μm), an ErbB4 tyrosine kinase inhibitor, on postsynaptic currents in newborn GCs. The amplitudes of feedforward GPSCs recorded in newborn GCs at 7 dpi was significantly lower in the slice culture treated with AG-1478 from 4 dpi (Fig. 6A1, control vs AG-1478-treated, p < 0.001). However, treatment with AG-1478 from 10 dpi had little effect on the amplitudes of feedforward GPSCs measured in newborn GCs at 14 dpi (Fig. 6A2, control vs AG-1478-treated, p = 0.878). These results suggest that activation of ErbB4 is required for the developmental increase in GPSCs during the critical period, but not for the later period. Such age dependence of the AG-1478 effect is similar to that of the NRG2 knock-down effects on GPSCs (Fig. 3), suggesting that NRG2 and ErbB4 are on the same signaling pathway required for GABAergic synapse formation.
It is possible that AG-1478 may have an effect on glutamatergic synapses on GABAergic interneurons, which in turn may suppress the feedforward GPSCs in newborn GCs. To rule out this possibility, we recorded the monosynaptic GPSCs in AG-1478-treated or control newborn GCs. Consistent with the results of feedforward GPSCs, the amplitudes of monosynaptic GPSCs were lower in newborn GCs treated with AG-1478 from 4 dpi (Fig. 6B, control vs AG-1478-treated, p < 0.01) and were not affected by AG-1478 treatment from 10 dpi (Fig. 6B, p = 0.182), arguing against the possible effects of AG-1478 on glutamatergic synapses onto interneurons. The inhibition effect of AG-1478 was significantly larger than the knock-down effect of NRG2 on feedforward GPSCs (Fig. 6A1, Dox-treated vs AG-1478-treated, p = 0.034). The reason for this might be either that the efficiency of NRG2 knock-down is <100% or that the drug effect is immediate whereas the knock-down of preexisting NRG2 takes effect later. To confirm the involvement of ErbB4, we tested the effect of monoclonal antibody targeting ectodomain of ErbB4 (C-erbB4 Ab-3 antibody, denoted as “Ab-3”). The ErbB4-blocking effect of Ab-3 antibody has been tested previously (Min et al., 2011). Treatment of the slice culture with Ab-3 antibody (10 μg/ml) from 4 dpi suppressed monosynaptic GPSCs measured at 14 dpi to a similar extent as AG-1478, confirming the involvement of ErbB4 in GABAergic synaptogenesis. The PPR was not altered by any of NRG2 depletion or AG-1478 or Ab-3 treatments from 4 dpi (p > 0.05 for all three conditions), implying that the decrease of monosynaptic GPSC amplitude by NRG2 knock-down or by ErbB4 inhibition is not caused by a change in presynaptic release probability.
Because NRG2 plays an essential role in the development of, not only GABAergic, but also glutamatergic synapses in newborn GCs, we tested whether ErbB4 mediates the downstream signaling of NRG2 involved in the latter. Unlike GPSCs, neither AMPA-EPSCs nor NMDA-EPSCs recorded in newborn GCs at 14 dpi were affected by AG-1478 treatment from 7 dpi (control vs AG-1478-treated; Fig. 6C1, AMPA-EPSCs, p = 0.302; Fig. 6D1, NMDA-EPSCs, p = 0.942). The PPRs of AMPA-EPSCs and NMDA-EPSCs were not altered by either Dox- or AG-1478 treatment from 7 dpi (Fig. 6C2,D2). These results suggest that the role of NRG2 in glutamatergic synapse development in newborn GC is independent of ErbB4 tyrosine kinase.
NRG2 signaling for glutamatergic synapse maturation and dendritic growth is mediated by its intracellular domain
Given that ErbB4 kinase activity is not relevant to the NRG2-dependent development of glutamatergic synapses in newborn GCs, we hypothesized that a reverse signaling pathway of NRG2 is involved. The role of reverse signaling of NRG1 has been studied at glutamatergic synapses of central neurons for the last decade (Bao et al., 2003; Bao et al., 2004; Chen et al., 2010; Fazzari et al., 2014) and involves activity-dependent cleavage and nuclear translocation of intracellular domain of NRG1 (NRG1-ICD). To investigate the possible involvement of NRG2-ICD in glutamatergic synapse development, we designed a retroviral vector expressing myc-tagged NRG2-ICD and TagRFP under the control of Tet-On and LTR promoters, respectively (Fig. 7A1). Newborn GCs infected by retrovirus encoding NRG2-ICD could be distinguished from those infected by retrovirus encoding shNRG2mir by the red fluorescence of TagRFP. Using immunohistochemical detection of myc, we confirmed that the newborn GCs infected by the retrovirus reliably express myc-tagged NRG2-ICD in the presence of Dox (Fig. 7A2).
Next, we tested whether the NRG2 knock-down effects on glutamatergic synaptic transmission and dendritic arborization could be rescued by the expression of NRG2-ICD. Hippocampal slice cultures were simultaneously infected with two kinds of retroviruses: retroviruses encoding shNRG2mir plus EGFP (shNRG2mir virus) or NRG2-ICD plus TagRFP (NRG2-ICD virus). Because shNRG2mir targets a different domain of NRG2 other than its ICD, it is expected that endogenous NRG2 is depleted by shNRG2mir, whereas shNRG2mir-resistant NRG2-ICD is overexpressed in the newborn GCs labeled with both EGFP and TagRFP (Fig. 7A3). We compared postsynaptic currents in newborn GCs under four different conditions as defined in Figure 7A4. Dox treatment started at 7 and 4 dpi to observe EPSCs and GPSCs, respectively. We found that neither the amplitudes of AMPA-EPSCs and NMDA-EPSCs nor the AMPA/NMDA ratio was significantly different in the doubly labeled newborn GCs (denoted as “rescue” in Fig. 7) compared with the control GCs, indicating that the effects of NRG2 depletion is rescued to the control level by the NRG2-ICD overexpression (Figs. 7B1–B3, control vs rescue, p > 0.1). Conversely, the impaired development of GPSCs caused by NRG2 knock-down was not rescued by NRG2-ICD overexpression (Fig. 7C, NRG2 K/D vs rescue, p = 0.697). These results demonstrate that reverse signaling of NRG2, mediated by NRG2-ICD, is involved in the development of glutamatergic synapses, but not in GABAergic synapse formation. Finally, we observed the dendritic morphology of EGFP-positive and TagRFP-positive newborn GCs treated with Dox from 7 dpi. Overexpression of NRG2-ICD rescued the impairments of dendritic arborization observed in NRG2-depleted newborn GCs at 14 dpi (Fig. 7D1). Both the complexity of dendritic arbor and the total dendritic length were rescued to the control level by NRG2-ICD overexpression (Fig. 7D2, Scholl analysis, F(1,31) = 0.074, p = 0.788, RM one-way ANOVA; Fig. 7D3, cumulative distributions of total dendritic lengths, p = 0.991, K-S test; Fig. 7D4, mean total dendritic length, p < 0.001, t test). These results suggest that reverse signaling of NRG2 is involved in the maturation of glutamatergic synapses and dendritic growth in newborn GCs, whereas forward signaling of NRG2 contributes to GABAergic synaptogenesis.
Discussion
The present study indicates that NRG2 plays a key role in formation of GABAergic synapses and maturation of glutamatergic synapses in newborn GCs via distinct signaling pathways: forward and reverse signaling of NRG2, respectively. NRG2 expression is very low at birth and notably increases during PW1 in neocortex, hippocampus, and cerebellum with development and decreases by PW3 in most brain regions except dentate gyrus, olfactory bulb, and cerebellum (Longart et al., 2004). Given that GABAergic synaptogenesis starts during PW2 in newborn GCs (Fig. 2F), it may coincide with the period when NRG2 expression is fully matured.
Because the expression of NRG2 is confined to somatodendritic compartments (Longart et al., 2004), NRG2 can act as a ligand for presynaptic ErbB4. Recent immunochemical studies revealed that ErbB4 is expressed on parvalbumin (PV) or cholecystokinin-positive basket cells and neuronal nitric oxide synthase (nNOS)-positive interneurons (Neddens and Buonanno, 2010). Neurogliaform interneurons are a major group of nNOS-positive interneurons (Armstrong et al., 2012). Interestingly, it has been shown recently that newborn GCs receive synaptic inputs from PV-positive and neurogliaform interneurons (Markwardt et al., 2011; Song et al., 2013). It has been suggested that presynaptic terminals of GABAergic interneurons innervating perisomatic regions of principal neurons express ErbB4 and that NRG1-dependent activation of ErbB4 promotes GABAergic synaptogenesis in cortical neurons (Woo et al., 2007; Fazzari et al., 2010; but see Vullhorst et al., 2009). Consistent with these notions, we found that GABAergic synaptogenesis in newborn GCs is suppressed, not only by NRG2 depletion, but also by inhibition of ErbB4. These findings raise the possibility that ErbB4 localized at GABAergic presynaptic terminals, probably of basket cells and/or neurogliaform interneurons, may be responsible for the NRG2-dependent GABAergic synaptogenesis in newborn GCs. Because the expression of ErbB4 in newborn GCs is very weak, it is unlikely that postsynaptic NRG2 on newborn GCs act as an autocrine ligand for postsynaptic ErbB4 even if its ectodomain is cleaved.
In contrast to our finding that NRG2 is dispensable for the maintenance of GABAergic synapses in newborn GCs, recent studies showed that the NRG1/ErbB4 interaction enhances GABAergic transmission in neocortex and amygdala (Woo et al., 2007; Lu et al., 2014). This discrepancy may be attributed to the molecular difference between NRG1 and NRG2, to the differences in developmental stages, and/or to the regional difference in the basal interaction level between ErbB4 and neuregulins.
There are controversial studies on the role of ErbB4 in glutamatergic synapse maturation. The lack of AG-1478 effects on the development of glutamatergic synapses suggests that the tyrosine kinase activity of ErbB4 is not involved in glutamatergic synapse maturation (Fig. 6C,D). It has been suggested, however, that presynaptic NRG1-induced activation of postsynaptic ErbB4 enhances AMPA-EPSCs in a kinase-dependent manner (Li et al., 2007) and that ErbB2/4 is involved in the maturation of dendritic spines (Barros et al., 2009). This idea on the role of ErbB4 in glutamatergic synapse maturation was challenged by a more recent study showing little role of ErbB4 expressed on pyramidal neurons in excitatory synaptic transmission (Fazzari et al., 2010). Therefore, the present study is rather consistent with the latter view. Nevertheless, our results do not rule out the involvement of ErbB4 in glutamatergic synapse maturation because interaction of NRG2 with the ectodomain of ErbB4 may trigger the reverse signaling of NRG2 independently of the ErbB4 kinase activity (Bao et al., 2003; Chen et al., 2010).
Reverse signaling of neuregulins
We showed that the NRG2 knock-down effects on the glutamatergic synapse maturation and dendritic arborization are rescued by the expression of NRG2-ICD (Fig. 7). Furthermore, the development of glutamatergic synapses was independent of ErbB4 tyrosine kinase activity (Fig. 6C,D). These results suggest that maturation of glutamatergic synapse is mediated, not by forward signaling, but rather by reverse signaling of NRG2. Although reverse signaling of NRG2 has not been studied previously, there is a line of evidence for the reverse signaling of NRG1 type III (Bao et al., 2003; Bao et al., 2004; Chen et al., 2010; Fazzari et al., 2014). The reverse signaling of NRG1 type III requires sequential cleavage of ectodomain and transmembrane domain of NRG1 by TNF-α converting enzyme (TACE) and γ-secretase containing the subunit Aph1b, respectively (Bao et al., 2003; La Marca et al., 2011; Fazzari et al., 2014). The cleaved NRG1-ICDs are translocated into the nucleus and enhance transcription of PSD-95 by interaction with a zinc-finger transcription factor, Eos (Bao et al., 2004). Therefore, any genetic mutations in γ-secretase-dependent intramembranous cleavage site of NRG1 or Aph1b resulted in impairments of dendritic arborization, dendritic spine formation, and glutamatergic synaptic transmission (Chen et al., 2010; Fazzari et al., 2014).
Examining the amino acid sequences of NRG2, we found that the γ-secretase and TACE-dependent cleavage sites, as well as the nuclear localization signal, are conserved in NRG2. Because the key sequences are not different between the α and β isoforms of NRG2, both isoforms may mediate reverse signaling (Hobbs et al., 2002). In light of knowledge from NRG1 studies, there is a possibility that NRG2-ICD may function as a transcription regulator, but the identity of transcription factors interacting with NRG2-ICD remains to be elucidated.
The expression and cleavage of NRG1 are regulated in an activity-dependent manner (Eilam et al., 1998; Bao et al., 2003; Bao et al., 2004; Ozaki et al., 2004), implying that GABAergic input-induced Ca2+ signaling may be one of factors prerequisite for the reverse signaling of NRG2 in newborn GCs. Previous studies suggested that excitatory GABAergic inputs and subsequent Ca2+ signaling play a key role in coupling the neural activity and the structural plasticity of newborn GCs (Tozuka et al., 2005; Ge et al., 2006; Lee et al., 2012a). Therefore, it is possible that the nurturing effects of network activity on dendritic arborization in newborn GCs may require the reverse signaling of NRG2 as a downstream signaling pathway of the depolarizing GABAergic inputs.
Role of NRG2 in dendritic growth and maturation of glutamatergic synapses
Given that only NMDA receptors are expressed in nascent glutamatergic synapses, the amplitude of NMDA-EPSCs could be a more appropriate parameter for glutamatergic synaptogenesis than AMAP-EPSCs. The suppression of developmental increase in NMDA-EPSCs can be caused by direct inhibition of glutamatergic synaptogenesis or secondary to the inhibition of dendritic arborization. The present study showed that depletion of NRG2 impairs dendritic development, with little effect on NMDA-EPSCs between 10 and 13 dpi (Figs. 4B2, 5). Therefore, it is unlikely that NRG2 contributes to glutamatergic synaptogenesis. In addition, the impoverished dendritic arbor caused by NRG2 depletion may be responsible for the lower developmental increase of EPSCs that became evident at 14 dpi in Dox-treated GCs. It remains to be elucidated, however, whether maturation of glutamatergic synapses, manifested as an increase in the AMPA/NMDA ratio, is mediated directly by NRG2 or if it is secondary to dendritic growth. Because the effects of NRG2 depletion on the NMDA-EPSCs emerged at the dpi, when AMPA-EPSCs started to increase and its effect on AMPA-EPSCs was more substantial, it is likely that NRG2 contributes directly to maturation of glutamatergic synapses. Differential evaluation of dendritic growth and maturation of glutamatergic synapses in immature GCs may not be easy, especially if dendritic arborization in these cells follows the synaptotrophic hypothesis, which argues that addition of AMPA receptors to a nascent glutamatergic synapse is required for stabilization, not only of the synapse, but also of the associated dendritic branch (Haas et al., 2006; Cline and Haas, 2008). Investigation of NRG2 knock-down effects on EPSCs in mature GCs may help to address this question.
Maturation of newborn GCs in hippocampal slice cultures
In the present study, we investigated the role of NRG2 by comparing developmental increases in synaptic currents in newborn GCs labeled in organotypic slice cultures taken from the early postnatal rat hippocampus. Two factors should be considered for evaluating the ex vivo data. First, maturation of newborn GCs is known to be faster at a younger age (Overstreet-Wadiche et al., 2006a). As noted in the present study and our previous study (Lee et al., 2012a), GABAergic synapse formation in newborn GCs in the present study was 3 d earlier than that of newborn GCs in the adult hippocampus (Espósito et al., 2005). Second, the development of newborn GCs is affected by abnormal patterns of neural activity of the slice culture. It has been shown that rewiring subsequent to slicing-induced massive deafferentiation leads to epileptiform discharge in the CA3 region (Dyhrfjeld-Johnsen et al., 2010). Given that seizure accelerates the maturation of newborn GCs (Overstreet-Wadiche et al., 2006b), the time course of developmental increases of synaptic current and morphological maturation may be faster than in vivo. Nevertheless, maturation of newborn GCs in the organotypic slice culture was comparable to that in age-matched in vivo conditions (Namba et al., 2007). Indeed, we found that the amplitude of monosynaptic GPSCs reached a plateau 1 or 2 d earlier in the slice culture than newborn GCs labeled in vivo of P16–P22 rats (data not shown). This small difference may be related to the delayed emergence of epileptiform discharge in the culture. It has been shown that epileptiform discharges were first observed at 21 dpi in 50% of the cultures, indicating that our observation window is earlier than the development of epileptiform discharge.
The present study was done in the neonatal or juvenile dentate gyrus, but adult neurogenesis recapitulates embryonic development (Espósito et al., 2005). Furthermore, the expression of NRG2 persists in the mature GCs. Therefore, it remains to be elucidated whether NRG2 may play a role in synaptogenesis and/or synaptic plasticity in mature GCs and adult-born GCs.
Footnotes
- Received April 24, 2015.
- Revision received November 2, 2015.
- Accepted November 9, 2015.
This work was supported by the National Research Foundation funded by the Korean Ministry of Science, ICT and Future Planning (Grants 2012-0004904 and 2012-0009135 to S.-H.L. and Grant NRF-2015M3C7A1028790 to W.S.). K.-H.L. is a postdoctorate and C.H.Y. is a graduate student supported by BK21plus.
The authors declare no competing financial interests.
- Correspondence should be addressed to Dr. Suk-Ho Lee, Department of Physiology, Seoul National University College of Medicine, 103 Daehak-ro, Jongno-gu, Seoul 03080, Republic of Korea. leesukho{at}snu.ac.kr
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