Abstract
The Neuregulin (NRG) family of ErbB ligands is comprised of numerous variants originating from the use of different genes, alternative promoters, and splice variants. NRGs have generally been thought to be transported to axons and presynaptic terminals where they signal via ErbB3/4 receptors in paracrine or juxtacrine mode. However, we recently demonstrated that unprocessed pro-NRG2 accumulates on cell bodies and proximal dendrites, and that NMDAR activity is required for shedding of its ectodomain by metalloproteinases. Here we systematically investigated the subcellular distribution and processing of major NRG isoforms in rat hippocampal neurons. We show that NRG1 isotypes I and II, which like NRG2 are single-pass transmembrane proteins with an Ig-like domain, share the same subcellular distribution and ectodomain shedding properties. We furthermore show that NRG3, like CRD-NRG1, is a dual-pass transmembrane protein that harbors a second transmembrane domain near its amino terminus. Both NRG3 and CRD-NRG1 cluster on axons through juxtacrine interactions with ErbB4 present on GABAergic interneurons. Interestingly, although single-pass NRGs accumulate as unprocessed proforms, axonal puncta of CRD-NRG1 and NRG3 are comprised of processed protein. Mutations of CRD-NRG1 and NRG3 that render them resistant to BACE cleavage, as well as BACE inhibition, result in the loss of axonal puncta and in the accumulation of unprocessed proforms in neuronal soma. Together, these results define two groups of NRGs with distinct membrane topologies and fundamentally different targeting and processing properties in central neurons. The implications of this functional diversity for the regulation of neuronal processes by the NRG/ErbB pathway are discussed.
SIGNIFICANCE STATEMENT Numerous Neuregulins (NRGs) are generated through the use of different genes, promoters, and alternative splicing, but the functional significance of this evolutionary conserved diversity remains poorly understood. Here we show that NRGs can be categorized by their membrane topologies. Single-pass NRGs, such as NRG1 Types I/II and NRG2, accumulate as unprocessed proforms on cell bodies, and their ectodomains are shed by metalloproteinases in response to NMDA receptor activation. By contrast, dual-pass CRD-NRG1 and NRG3 are constitutively processed by BACE and accumulate on axons where they interact with ErbB4 in juxtacrine mode. These findings reveal a previously unknown functional relationship between membrane topology, protein processing, and subcellular distribution, and suggest that single- and dual-pass NRGs regulate neuronal functions in fundamentally different ways.
Introduction
Neuregulins (NRGs) signal via ErbB3/4 receptor tyrosine kinases to regulate numerous neurodevelopmental and activity-dependent processes (Buonanno, 2010; Mei and Nave, 2014). For example, NRG/ErbB4 signaling in parvalbumin-positive GABAergic interneurons regulates glutamatergic synaptic plasticity in the hippocampus (Chen et al., 2010; Shamir et al., 2012) and critical period plasticity in the visual cortex (Gu et al., 2016; Sun et al., 2016). NRGs are encoded by four genes, of which nrg1–3 are expressed in the nervous system. All NRGs share an EGF-like domain that mediates receptor binding and initiation of downstream signaling. NRG1 isoform diversity results from the use of multiple promoters that give rise to unique amino-terminal sequences of NRG Types I–VI, and by alternative splicing of sequences encoding both the extracellular and intracellular domains (Falls, 2003; Steinthorsdottir et al., 2004). Proforms of canonical NRGs, such as NRG1 Types I/II and NRG2, harbor a single transmembrane pass (TMC) downstream of the EGF-like motif that separates the amino-terminal extracellular domain (ECD) from the carboxyl-terminal intracellular domain (ICD). They additionally contain an immunoglobulin-like (Ig) motif that mediates interactions with heparan sulfate proteoglycans in the extracellular matrix (Loeb and Fischbach, 1995). Ig-NRGs shed their ectodomains upon proteolytic processing near the TMC, which then interact with ErbB receptors in paracrine manner. By contrast, NRG1 isoforms transcribed from the Type III promoter lack the Ig-like motif and instead contain a cysteine-rich domain (CRD) near their amino terminus that serves as a second transmembrane domain (TMN). As a result, CRD-NRG1 remains cell-attached after cleavage and signals in juxtacrine fashion (Wang et al., 2001). NRG3, whose mode of signaling has not been reported, lacks both Ig-like and CRD motifs but includes a stretch of hydrophobic residues near its amino terminus (Zhang et al., 1997).
Historically, the relationship between domain organization, signaling mode, and biological function has been most extensively explored for CRD-NRG1. In particular, juxtacrine interactions between CRD-NRG1 on sensory neuron or motorneuron axons and ErbB2/3 receptors on glial cells are essential for Schwann cell development and functional maturation (Garratt et al., 2000; Nave and Salzer, 2006), and mice lacking this isoform exhibit deficient myelination of peripheral nerves resulting in neonatal lethality (Wolpowitz et al., 2000). Axonal accumulation of CRD-NRG1 has therefore served as a general paradigm for subcellular NRG targeting. Less is known about the in vivo functions of single-pass Ig-NRG1s in neuronal development because mice lacking the Ig-like motif die at E10.5 due to deficient myocardial trabeculation (Kramer et al., 1996; Meyer et al., 1997), although an essential role for glial-derived Type 1 NRG1 has been demonstrated during Schwann cell regeneration following peripheral nerve denervation (Carroll et al., 1997; Hayworth et al., 2006; Stassart et al., 2013).
We recently reported that unprocessed NRG2, a major Ig-NRG in the adult rodent brain, clusters on the soma and proximal dendrites of NRG2-expressing cells, such as ErbB4-positive GABAergic interneurons and cerebellar Purkinje neurons, rather than accumulating on axons (Vullhorst et al., 2015). Pro-NRG2 targets to a distinct type of ER-PM contact site characterized by endoplasmic reticulum specializations known as subsurface cisterns (SSCs) (Berridge, 1998), and colocalizes with Kv2.1 potassium channels (Du et al., 1998; Misonou et al., 2004). Ectodomain shedding is mediated by metalloproteinases and requires NMDA receptor (NMDAR) activity (Vullhorst et al., 2015). Interestingly, NRG1 has recently been reported to accumulate postsynaptically at C-boutons, cholinergic synapses between local interneurons and α-motorneuron cell bodies (Gallart-Palau et al., 2014), which form atop SSCs and contain Kv2.1 channel clusters (Deardorff et al., 2014). However, the type of NRG1 expressed at C-boutons is not known.
In this study, we delineated general principles underlying the relationship between domain structure, subcellular distribution, and ectodomain shedding of major NRG isoforms in central neurons, including NRG1 Types I/II, NRG2, and NRG3. Our data show that single-pass NRGs share the same subcellular targeting and NMDAR-dependent ectodomain shedding properties, whereas the dual-pass proteins CRD-NRG1 and NRG3 accumulate as processed proteins on axons through juxtracrine interactions with ErbB4. Furthermore, processing of single-pass NRGs is mediated by metalloproteinases, whereas dual-pass NRGs are processed by BACE. Together, these findings establish a rational basis to understand NRG isoform diversity and function in cell biological terms.
Materials and Methods
Animals.
Sprague Dawley rats of either sex were used for tissue culture and RNA analysis. Wild-type C57BL/6J mice of either sex were used for immunohistochemistry and ISH. Animals were treated in accordance with National Institutes of Health Animal Welfare guidelines. All procedures were approved by the National Institute of Child Health and Human Development Animal Care and User Committee.
Antibodies.
Antibodies included the following: rabbit monoclonal mAB11 against NRG2 (Vullhorst et al., 2015); mouse monoclonal against Ankyrin G (clone N106/65; NeuroMab); rabbit polyclonal custom antibody 5721 against Erbb4 (for immunization strategy, see Vullhorst et al., 2009); mouse monoclonal against Kv2.1 (clone K89/34; NeuroMab); rabbit polyclonal against NRG1 (SC-348; Santa Cruz Biotechnology); mouse monoclonal against V5 tag (clone SV-Pk1; Bio-Rad); mouse monoclonal against HA tag (clone 16B12; Abcam); mouse monoclonal against PSD95 (clone 7E3-1B8; Thermo Fisher); rat monoclonal against GFP (clone GF090R; Nacalai Tesque); guinea pig polyclonal against parvalbumin (Synaptic Systems); and guinea pig polyclonal against vesicular acetylcholine transporter (vAChT; Synaptic Systems).
Generation of an attenuated CMV promoter to drive low-level NRG expression in transfected hippocampal neurons.
To attain low to moderate NRG expression levels in transfected cultured neurons, the 586 bp wild-type CMV promoter was “gutted” to lower its transcriptional output, following a previously described strategy (Watanabe and Mitchison, 2002). Briefly, a 434 bp internal fragment was removed from the promoter by sequential treatment with the endonuclease AatII and the exonuclease Bal-31. Residual promoter strength was assessed by transient transfection of HEK 293 cells and 10 days in vitro (DIV) cultured hippocampal neurons with vector pGL3basic (Promega) harboring the attenuated CMV promoter. Relative luciferase activity, measured 1 d after transfection and normalized by cotransfection with pRL Renilla (Promega), was 14.1 ± 1.6% of wild-type CMV in HEK 293 cells (n = 3 independent experiment, each run in triplicate) and 38.9 ± 1.2% in hippocampal neurons (n = 4 independent experiments, each run in duplicate). To generate the corresponding attenuated NRG expression vectors, the luciferase sequence was first replaced by a Gateway conversion cassette (Thermo Fisher); the resulting destination vector was named pDESTDV3. NRG cDNAs were transferred by Gateway recombination from their respective entry vectors (see below).
NRG expression constructs.
Sequences for NRG1 cDNAs were of mouse origin and encoded β1a isoforms. A cDNA for human NRG2 (β isoform; IMAGE:100066341; GenBank accession number BC166615.1) was obtained from Origene Technologies. Mouse NRG3 (transcript variant 1; GenBank accession number NM_008734.3) was cloned by RT-PCR from brain total RNA. All NRG1 constructs and NRG3 were initially cloned into pENTR/D; the NRG2 construct was in pENTR223.1 (both Thermo Fisher). Unless indicated otherwise, all constructs harbored a V5 epitope tag upstream of the EGF-like domain that does not interfere with function, as described previously (Wang et al., 2001). Mutated variants of NRG, such as deletions, replacements, fusions, and point mutations, were generated by replacing the wild-type sequence with synthetic DNA fragments (“gBlocks”) harboring the desired alteration (Integrated DNA Technologies). NRG open reading frames were transferred by Gateway recombination to pDESTDV3 (for attenuated expression following cationic lipid-mediated transfection) or to pAAV_hSynI (for neuron-selective gene expression under the control of the human Synapsin I promoter following adeno-associated virus [AAV]-mediated transduction).
Mouse monoclonal antibody against Type II NRG1.
To generate the immunogen, the nucleotide sequence encoding the 469 residue extracellular domain of mouse Type II NRG1 was subcloned into Bacmid vector pFastBac1 (Thermo Fisher), with a hexahistidine tag motif added to its 3′ end to aid in affinity purification. Bioactive Type II NRG1 ectodomain was purified by metal affinity chromatography from 5 L of insect cell medium conditioned by Sf9 cells infected with Type II NRG1-ECD baculovirus (Genscript). Protein integrity and biological activity were validated by SDS-PAGE, Western blotting, and assaying ErbB receptor-dependent Erk pathway activation in HEK293 cells. Recombinant Type II NRG1-ECD was then used to immunize SJL mice and to develop mouse monoclonal anti-NRG1 antibody 7C11 (hybridomas generated at Precision Antibodies). Clone 7C11 was validated for use in immunocytochemistry and in immunohistology (see Fig. 3) but was found not to work in Western blotting.
Rabbit polyclonal antibody against NRG3.
Polyclonal rabbit antiserum 1352 was raised against a peptide corresponding to amino acid residues 690–709 of mouse NRG3 (accession number: NP_032760.1). The peptide included an amino-terminal cysteine for conjugation to keyhole limpet hemocyanin. The antiserum was validated to selectively recognize NRG3, but not NRG1 or NRG2, by Western blotting and immunocytochemistry of HEK293 cells transfected with corresponding expression constructs.
Preparation of adeno-associated viruses.
AAV-293 cells (Agilent), grown in DMEM with 10% FBS, were used for AAV production. Cells between passage 3–5 were seeded in 10 cm dishes and transfected at 50%–60% confluence with pHelper (Agilent), pAAV-RC1 (Cell Biolabs), and recombinant pAAV vectors under the control of the human Synapsin I promoter (pAAV_hSynI). Medium was changed 2 h before transfection. For each dish, 4 μg of plasmid DNAs (1:1:1 mass ratio) were first mixed 1:4 with polyethyleneimine (1 mg/ml) in 500 μl of OptiMEM medium (Thermo Fisher) and then added to the cells. Following transfection (72 h), cells were scraped into gradient buffer (150 mm NaCl, 10 mm MgCl2, 10 mm Tris-Cl, pH 7.6) and lysed by multiple freeze-thaw cycles. The lysate was cleared by centrifugation, and the supernatant was layered on top of an iodixanol step gradient (15%, 25%, 40%, and 58% (v/v) in gradient buffer); the remaining volume was filled with gradient buffer. Ultracentrifugation was done at 48,000 rpm using a Type 70Ti fixed angle rotor (Beckman) for 2 h, 18°C. Viral particles were collected from the 40% iodixanol layer and stored at 4°C for immediate use or at −80°C for long-term storage. AAV preparations were initially tested on cultured hippocampal neurons and used at dilutions that yielded widespread expression at moderate levels suitable for detection by Western blotting.
Cell culture.
Dissociated hippocampal neurons were prepared from E19 Sprague Dawley rat pups and propagated in defined medium, as described previously (Brewer et al., 1993). Neurons were plated on poly-D-lysine-coated plastic for Western blotting, or on poly-D-lysine-coated coverslips for immunofluorescence cytochemistry. Neurons were maintained in defined Neurobasal/B27 medium (Thermo Fisher), and half of the medium was changed once every week. To achieve sparse expression for immunofluorescence cytochemistry of dual-pass NRGs, neurons were transfected between DIV 8–10 with 1.5 μg of plasmid DNA per well of a 24-well plate using Lipofectamine 2000 (Thermo Fisher). pDESTDV3-based plasmids expressing NRG under the control of the attenuated CMV promoter (see above) and GFP under the control of the human Synapsin I promoter were mixed 1:1 (mass ratio) for double transfections or 1:1:1 for triple transfections. For other ICC experiments and Western blotting, neurons were transduced with AAV at least 1 week before analysis. HEK293 cells were propagated at 37°C and 5% CO2 in DMEM supplemented with 10% FBS (Thermo Fisher), and transfected with 1.5 μg plasmid DNA per well of a 24-well plate using Xtreme HP transfection reagent (Roche). For competition experiments, neurons were transfected at DIV 8 and treated daily for 48 h with 60 nm NRG1 EGF-like domain (Shenandoah Biotechnology).
Semiquantitative RT-PCR.
Total RNA was extracted from whole brains of E19, P7, and adult Sprague Dawley rats using Tri Reagent solution (Thermo Fisher). Aliquots of RNA (1 μg) were reverse transcribed at 55°C for 20 min using random hexamer primers and Superscript IV reverse transcriptase (Thermo Fisher). For semiquantitative PCR, reverse transcription reactions were diluted 10-fold in water, and 1 μl aliquots of the diluted samples were amplified in 20 μl total volume using FastStart DNA Master SYBR Green reagent mix (Roche) and 0.5 μm of the following NRG1 type-specific forward primers: Type I, 5′-GGA AGG GCA AGA AGA AGG AC-3′; Type II, 5′-TTG TGC AAG CGG TGC GCA CTG-3′; and Type III (CRD-NRG1), 5′-CAT TCT GGC TTG CCT AGT CAG C-3′. The sequence of the common reverse primer was 5′-CCA GTC GTG GAT GTT GAT GTG-3′. For normalization, β-actin transcripts were amplified using the following primers: β-actin forward, 5′-ACC AAC TGG GAC GAT ATG GAG AAG A-3′, β-actin reverse, 5′-CGC ACG ATT TCC CTC TCA GC-3′ (Peirson et al., 2003). Annealing temperatures were 60°C for NRG1 targets and 55°C for β-actin. Amplification was done in a LightCycler 1.5 (Roche), and the results were analyzed using LightCycler software version 4.05. Values for NRG1 Types I-II, CRD-NRG1 targets, and the β-actin reference were internally calibrated using plasmid DNA standards.
Double ISH.
We used RNAscope, a fluorescence-based multiplexing ISH technique (Wang et al., 2012), to analyze expression of Type II NRG1 mRNA in the mouse brain. Briefly, 12 μm fresh-frozen sagittal sections from 4-week old wild-type mice were hybridized at 40°C for 2 h with specific probe sets for mouse Type II NRG1 and Gad1. Probes were as follows: NRG1, accession number XM_006509059.2, target region 6625–7529; Gad1: accession number NM_008077.4, target region: 62–3113. Specific hybridization signals were amplified following the manufacturer's instructions, and detected with Atto 550 (for Type II NRG1) and Atto 647 (for Gad1) fluorophores. Sections were additionally labeled with DAPI to visualize nuclei.
Type II NRG1 ectodomain purification from conditioned medium.
Cultured hippocampal neurons in 6-well plates were transduced at DIV 15 with AAV-expressing Type II NRG1/V5 and assayed at DIV 23. To reduce baseline Type II ectodomain levels in the conditioned medium, cells were first washed into conditioned medium from untransduced hippocampal neurons. Following treatments, the Type II ectodomain was captured from 1 ml supernatant using heparin-agarose beads (Sigma). Beads were first equilibrated with cold Neurobasal/B27 and then incubated for several hours at 4°C with conditioned medium. Following three washes with cold PBS, heparin-bound protein was eluted with 40 μl SDS-PAGE sample buffer (Pierce); 15 μl aliquots were analyzed by Western blotting using anti-V5.
Western blotting.
Protein samples from cultured cells were size-fractionated on 4%–15% Mini-Protean TGX precast gels (Bio-Rad) and electroblotted onto nitrocellulose. Membranes were blocked with 3% BSA in Tris-buffered saline (TBS) containing 0.1% Tween 20 (TBS/T), and incubated with primary antibodies in blocking solution for several hours at room temperature or overnight at 4°C. After several washes with TBS/T, membranes were incubated with HRP-conjugated secondary antibodies (Jackson ImmunoResearch Laboratories) for 1 h at room temperature. Signals were detected by chemiluminescence using a ChemiDoc MP imager (Bio-Rad) and quantified using Image Laboratory software (Bio-Rad).
Immunofluorescence cytochemistry.
Neurons or HEK 293 cells grown on round 12 mm glass coverslips were fixed for 15 min at room temperature in 4% PFA in PBS supplemented with 4% sucrose. After extensive washing with PBS, cells were blocked and permeabilized with 10% normal goat serum/0.1% TX-100 in PBS. For surface labeling, blocking solution without detergent was used. Cells were incubated with primary antibody for several hours at room temperature or overnight at 4°C with gentle rocking, and for 1 h with donkey or goat secondary antibodies conjugated to AlexaFluor-488, DL-549 and Alexa-647 fluorophores (Thermo Fisher or Jackson ImmunoResearch Laboratories). DAPI stain was included to label nuclei (Thermo Fisher). Coverslips were washed with PBS, dipped in water, and mounted on slides using Mowiol/DABCO (1,4-diazabicyclo-[2,2,2]-octane) mounting medium.
Preembedding immunogold electron microscopy.
DIV 21 cultured hippocampal neurons transduced with AAV expressing Type II NRG1/V5 were fixed for 15 min with 4% PFA in PBS with 4% sucrose, then washed and blocked with 5% normal goat serum for 40 min. Cells were incubated with mouse monoclonal anti-Type II NRG1 clone 7C11 and secondary antibodies (Nanogold, Nanoprobes) for 1 h, fixed with 2% glutaraldehyde in PBS overnight, silver enhanced (HQ kit, Nanoprobes), treated with 0.2% osmium tetroxide in 0.1 m phosphate buffer (PB) at pH 7.4 for 30 min, en bloc stained with 0.25% uranyl acetate in acetate buffer at pH 5.0 for 1 h, dehydrated in graded ethanols, and embedded in epoxy resin. Thin sections were examined on a JEOL 1200 EX transmission electron microscope and images collected with a digital CCD camera (AMT XR-100, Advanced Microscopy Techniques).
Immunofluorescence histochemistry.
Rats (∼P30) were transcardially perfused with 4% PFA in 0.1 m PBS, pH 7.4. Brains were postfixed overnight in the same fixative, and 50 μm sections were cut on a vibratome. Sections were blocked in 10% normal donkey serum, 0.25% Triton X-100 in 0.1 m PB for 1 h at room temperature and incubated with primary antibodies in 0.1 m PB with 5% normal donkey serum and 0.25% Triton X-100 (dilution buffer) for 24 h at 4°C with gentle rocking. Slices were washed in 0.1 m PB with 0.25% Triton X-100 for at least 30 min before incubation with fluorophore-conjugated donkey secondary antibodies for 90 min at room temperature in dilution buffer. DAPI stain was included to label nuclei. After extensive washes in PBS with 0.25% Triton X-100, sections were mounted on gelatin-coated slides, dried, and mounted in Mowiol-DABCO.
Microscopy and image analyses.
Fluorescence signals were analyzed by confocal microscopy using LSM780 or LSM710 microscopes (Carl Zeiss). For cultured cells, images were acquired at 63× magnification. Image stacks were projected in the Z dimension using the maximum intensity method. For tissue, including RNAscope and immunocytochemistry, images were acquired at 20× or 40× magnification and tiled at 10% overlap. Images were adjusted for overall brightness and contrast using ImageJ. For all quantitative analyses, images were acquired under nonsaturating conditions. To evaluate axonal accumulation of NRG3 puncta in neurons transfected with NRG3/V5, GFP-SNPHΔ-MTB, and mCherry, regions of interest (ROIs) were selected based on the presence of NRG3/V5 puncta. Images were then acquired for NRG3, GFP-SNPHΔ-MTB, and mCherry, and the fraction of NRG3 puncta on neurites that were positive for both GFP-SNPHΔ-MTB and mCherry was calculated using the “colocalization” function included in the ZEN software (Carl Zeiss). The same function was also used to analyze the extent of colocalization of NRG3/CRD-NRG1 puncta with the presynaptic marker bassoon and the postsynaptic glutamatergic marker PSD-95. Time course of NRG3/CRD-NRG1 puncta formation and colocalization with endogenous ErbB4 in transfected neurons was analyzed with Volocity software (PerkinElmer). All quantitative data are based on analyses of at least 10 ROIs from three separate experiments.
Statistics.
One-way ANOVA for independent measurements was used to analyze the effects of protease inhibition on Type II NRG1 ectodomain shedding (see Fig. 6) and to assess the extent of colocalization of CRD-NRG1 and NRG3 with synaptic markers. p values for multiple comparisons were calculated using Dunnett's (see Fig. 6) or Tukey's (see Fig. 8) post hoc test. All other experiments that were not statistically analyzed were independently repeated a minimum of 3 times to ensure consistency and reproducibility.
Results
Single-pass NRG1 proforms accumulate on neuron cell bodies in vitro and in vivo
Earlier observations with NRG2 indicated that the use of strong viral promoters causes ectopic accumulation in axons and distal dendrites (Vullhorst et al., 2015). Because ISH studies indicate that NRG mRNAs are generally expressed at low to moderate levels in the postnatal brain (Corfas et al., 1995; Longart et al., 2004), we developed an attenuated CMV promoter to better reproduce the subcellular distribution of endogenous NRGs under these conditions (Fig. 1; see Materials and Methods). The corresponding expression vector (referred to as pDESTDV3) was used for all NRG transfections. We then generated constructs for mouse Ig-NRG1 Types I and II that included a V5 epitope tag immediately upstream of the EGF-like domain (Fig. 2A), a location that does not interfere with NRG function (Wang et al., 2001). Of note, the sequences of all NRG1 constructs used in this study, including CRD-NRG1, harbored the β1a sequence downstream of the EGF-like domain. Reminiscent of the subcellular distribution of NRG2 (Vullhorst et al., 2015), hippocampal neurons cotransfected with GFP and Ig-NRG1s harbored numerous puncta confined to cell bodies and proximal MAP2-positive dendrites, but absent from distal dendrites or Ankyrin G-positive axons, as illustrated for Type I NRG1 in Figure 2B. To confirm that Ig-NRG1s and NRG2 share the same subcellular localization, hippocampal neurons were transduced with Type I or Type II NRG1/V5-harboring AAVs that were titrated to drive low-level gene expression (Fig. 1C). Neurons were labeled with antibodies against V5 and NRG2 to reveal somatic clusters of endogenous pro-NRG2 present on ErbB4-positive GABAergic interneurons (Vullhorst et al., 2015). Indeed, signals for both Type I and Type II NRG1 overlapped extensively with endogenous pro-NRG2 (Fig. 2C), and colocalized with Kv2.1 clusters (Fig. 2D). Furthermore, colabeling of the extracellular and intracellular domains indicated that somatic Ig-NRG1 puncta are comprised of their respective unprocessed proforms (Fig. 2E). Last, immunogold EM analysis of AAV-transduced neurons confirmed that Type II NRG1/V5 clusters were located on cell somata atop SSCs, as previously shown for NRG2 (Vullhorst et al., 2015), but absent from presynaptic terminals (Fig. 2F).
The Ig-like domain enables NRGs to bind heparan sulfate proteoglycans, and this interaction is thought to promote local retention of the ectodomain in the extracellular matrix upon shedding (Loeb and Fischbach, 1995). To determine whether the Ig-like domain is also involved in trafficking, we generated AAVs harboring a mutant NRG2 lacking the Ig-like domain (NRG2ΔIg/V5). As shown in Figure 2G, V5 immunoreactivity in transduced hippocampal neurons was punctate, concentrated on cell bodies, and reproduced the spatial relationship of endogenous NRG2 with Kv2.1 channel clusters, indicating that the Ig-like domain is not required to target NRGs to SSC-type membrane contacts.
We sought to corroborate these findings in vivo by analyzing the subcellular distribution of endogenous Ig-NRG1s in the adult rodent brain. However, because in our hands commercially available isoform-specific antibodies against Ig-NRG1s were not useful for immunohistochemistry, we set out to generate a custom antibody. Toward this goal, we first used semiquantitative RT-PCR to determine which Ig-NRG1 isoform is most abundantly expressed in the rodent brain by measuring Type I and Type II NRG1 mRNA levels in whole-brain RNA preparations from E19, P7, and adult rats by semiquantitative real-time RT-PCR. As shown in Figure 3A, at all three time points, β actin-normalized Type II NRG1 transcript levels were higher than Type I NRG1 (E19: 4.7-fold; P7: 15.4-fold; adult: 11.2-fold), indicating that Type II NRG1 is a major Ig-NRG1 in the perinatal and adult brain, consistent with previous studies (Meyer and Birchmeier, 1994; Liu et al., 2011). Unlike Type II-NRG1 mRNA levels that remain relatively constant across the tested time points, CRD-NRG1 expression increases postnatally to become the predominant isoform (Fig. 3A). Hence, Type II and Type III NRG1 are the most abundant NRG1 isoforms in the adult rat brain.
To analyze the expression and subcellular distribution of endogenous Type II NRG1 protein, we developed mouse monoclonal antibody 7C11 against its ECD (Fig. 3B; for further details, see Materials and Methods). In cultured hippocampal neurons transduced with AAVs harboring Type I or Type II NRG1, clone 7C11 detected Type II NRG1 but not Type I NRG1 (Fig. 3C). Furthermore, 7C11 did not cross-react with NRG2 (Fig. 3C, bottom), the closest structural homolog of Type II NRG1, suggesting that the antibody selectively binds to an epitope in the unique amino-terminal region of Type II NRG1 (Fig. 3B). We then used clone 7C11 to investigate the subcellular expression pattern of Type II NRG1 in the reticular nucleus of the thalamus (RTN), where our fluorescence-based ISH (RNAscope) experiments identified robust mRNA expression in Gad1-positive GABAergic neurons but not in adjacent Gad1-negative cells (Fig. 4A–E); this pattern is consistent with an earlier study using a radioactively labeled Ig-like domain ISH probe (Corfas et al., 1995). Coimmunofluorescence histochemistry of Type II NRG1 protein in the RTN with clone 7C11 and anti-ICD antibody SC-348, which recognizes all NRG1 isoforms with a long (a-type) cytoplasmic tail, revealed numerous overlapping puncta on parvalbumin (PV)-positive GABAergic neuron cell bodies that were absent in adjacent PV-negative cells (Fig. 4F–J). This punctate labeling pattern of endogenous Type II NRG1 in RTN neurons is consistent with the distribution of heterologously expressed Type II NRG1 in cultured hippocampal neurons (Figs. 2C, 3C). Using the pan-NRG1 antibody SC-348, Gallart-Palau et al. (2014) recently reported NRG1 puncta atop postsynaptic SSCs at cholinergic C-bouton synapses. We therefore performed triple-immunofluorescence histochemistry of rat spinal cord cross-sections with clone 7C11, SC-348 and anti-vAChT, and confirmed overlapping punctate signals with both NRG1 antibodies that colocalized with vAChT (Fig. 5). This finding demonstrates that Type II NRG1 targets to C-bouton synapses and is consistent with the general notion that Ig-NRGs accumulate at SSC-type ER-PM contacts.
NMDA receptor activity regulates Ig-NRG1 processing and ectodomain release
The colocalization of ECD and ICD signals for Type I NRG1 shown in Figure 2E and for Type II NRG1 shown in Figures 4 and 5 suggested that clustered Ig-NRG1s accumulate as unprocessed proteins. Consistent with this notion, Western blot analysis of lysates from hippocampal neurons transduced with AAVs harboring Type I and Type II NRG1 using anti-ECD (V5) and anti-ICD (SC-348) antibodies revealed that their unprocessed proforms account for the bulk of immunoreactivity (Fig. 6A,B). Furthermore, a 20 min incubation with 20 μm glutamate greatly reduced proform band intensities in an NMDA receptor-dependent manner (i.e., AP5-sensitive; 100 μm) and increased band intensities of their respective processed ECD and ICD fragments. To directly demonstrate glutamate-dependent ectodomain shedding, we exploited the affinity of the Ig-like domain for heparin to concentrate Type II NRG1 from conditioned supernatants of AAV-transduced hippocampal neurons expressing V5-tagged Type II NRG1. To reduce baseline levels resulting from ongoing NMDAR activity, cell culture medium was changed immediately before treatment. After pull-down with heparin-agarose beads, the ∼60 kDa Type II NRG1 ectodomain was detected by Western blot using anti-V5. Compared with untreated controls, Type II NRG1 ectodomain levels increased twofold following a 20 min treatment with 20 μm glutamate (Fig. 6C,D). This increase of ectodomain shedding in response to glutamate was abolished by pretreatment of neurons with AP5. Next, we investigated the role of matrix metalloproteinases and BACE that could function downstream of NMDAR activation. As shown in Figure 6C, D, accumulation of the ECD by glutamate treatment greatly diminished after inhibition of matrix metalloproteinases by the broad-spectrum inhibitor GM6001 (10 μm), but not after BACE inhibition with 1 μm BACE-IV (p = 0.0031; F(3,12) = 8.222; one-way ANOVA). Together with our previous work on NRG2 (Vullhorst et al., 2015), these data demonstrate that single-pass NRGs share important properties that govern their subcellular targeting and matrix metalloproteinase-dependent ectodomain shedding in response to NMDAR activation.
NRG3 is a dual-pass transmembrane domain protein
Unlike single-pass Ig-NRG1s and NRG2, dual-pass CRD-NRG1 accumulates on axons and axon terminals of peripheral and central neurons (Wolpowitz et al., 2000; Birchmeier and Nave, 2008). Whereas the membrane topology of NRG1 isoforms has been extensively studied, little is known about the membrane topology and subcellular targeting of NRG3, arguably the most broadly expressed NRG in the postnatal CNS (Zhang et al., 1997; Longart et al., 2004). NRG3 harbors neither CRD- nor Ig-like domains in its amino-terminal half (NTD); however, it contains a hydrophobic stretch of 23 amino acids between residues 69 and 91. Analysis of the NRG3 protein sequence using a hidden Markov model for the prediction of transmembrane topology (TMHMM2.0 program) (Krogh et al., 2001) suggests that this area forms an α-helical transmembrane stretch (Fig. 7A). We began to experimentally explore the transmembrane topology of NRG3 by transfecting HEK293 cells with a construct harboring the V5 epitope upstream of the EGF-like domain and the HA epitope upstream of this putative TMN (NRG3/HA-V5; Fig. 7B). The pattern and intensity of V5 immunoreactivity were comparable under permeabilizing and nonpermeabilizing conditions, indicating that NRG3/HA-V5 was efficiently targeted to the plasma membrane. By contrast, HA immunoreactivity was only detectable under permeabilizing conditions, consistent with the prediction of a second transmembrane domain near the amino terminus that would render the location of the HA epitope intracellular (Fig. 7B). To test whether the amino-terminal sequence including the putative TMN alone is sufficient to target the protein to the plasma membrane, we generated NRG3/NTD-GFP, a construct in which the entire NRG3 sequence downstream of the TMN was replaced by GFP. Indeed, surface labeling of transfected HEK293 cells with anti-GFP under nonpermeabilizing conditions revealed strong cell-associated immunoreactivity (Fig. 7C). Together, these data support the notion that NRG3 is a dual-pass transmembrane protein, and that NRG3 and CRD-NRG1 share a common membrane topology.
NRG3 accumulates on axonal varicosities
Next, we sought to investigate the subcellular distribution of NRG3 in transfected hippocampal neurons. Similar to the reported distribution of CRD-NRG1, and in striking contrast to single-pass Ig-NRGs, NRG3/V5 formed discrete small puncta on varicosities of long processes (Fig. 8A). To determine whether these processes correspond to axons, hippocampal neurons were cotransfected with NRG3/V5, GFP-SNPH-ΔMTB, a marker that associates with axonal mitochondria (Kang et al., 2008), and with mCherry to uniformly fill all neuronal processes. As shown in Figure 8B, NRG3/V5 puncta were frequently located on GFP-SNPH-ΔMTB-positive axonal processes; a quantitative analysis revealed that 88 ± 1.4% (SEM) of NRG3/V5-immunoreactive puncta were on axons (n = 10 ROIs from three independent experiments). Furthermore, consistent with the selective NRG3 accumulation in axons, neurons cotransfected with NRG3/V5 and HA-tagged CRD-NRG1, previously shown to be in axons using immunological and functional approaches (Wolpowitz et al., 2000; Hancock et al., 2008), showed extensive overlap between anti-V5 and anti-HA signals at varicosities (Fig. 8C).
Next, we investigated whether these varicosities correspond to bona fide synaptic contacts by using well-established presynaptic and postsynaptic markers, including PSD-95 for glutamatergic synapses where ErbB4 clusters at postsynaptic densities (Garcia et al., 2000; Huang et al., 2000). To this end, we transduced cultured hippocampal neurons with AAVs expressing CRD-NRG1/V5 or NRG3/V5 under the control of the Synapsin I promoter, and triple-labeled neurons at DIV 14, DIV 21, and DIV 28 with antibodies against V5, the general presynaptic marker bassoon, and PSD-95 (Fig. 8D,E). We found that V5-immunoreactive puncta for NRG3 and CRD-NRG1 accumulate at both synaptic and nonsynaptic sites (Fig. 8D,E, top). The fraction of NRG3 puncta that colocalized with bassoon increased significantly from 0.11 ± 0.014 (SEM) at DIV 14 to 0.37 ± 0.038 at DIV 28 (p < 0.0001; F(2,27) = 32.77; one-way ANOVA). PSD-95 colocalization also significantly increased from 0.17 ± 0.023 at DIV 14 to 0.41 ± 0.038 at DIV 28 (p < 0.0001; F(2,27) = 27.62). In that same time frame, the fraction of CRD-NRG1 puncta that colocalized with bassoon increased from 0.08 ± 0.034 to 0.4 ± 0.03 (p < 0.0001; F(2,27) = 29.81), and from 0.16 ± 0.017 to 0.51 ± 0.054 for colocalization with PSD-95 (p < 0.0001; F(2,27) = 38.85). Furthermore, the total number of V5 puncta also increased for both NRG3 and CRD-NRG1 (2.2-fold for CRD-NRG1 and 1.6-fold for NRG3 at DIV 21, and 4.8-fold for CRD-NRG1 and 2.9-fold for NRG3 at DIV 28, relative to DIV 14). These data indicate that a subset of CRD-NRG1- and NRG3-containing axonal varicosities constitute bona fide excitatory presynaptic sites, as defined by bassoon and PSD95 colocalization, whereas other varicosities might represent sites destined for future synapse formation.
The NRG EGF-like domain is important for axonal clustering at sites of ErbB4 accumulation
ErbB4 protein in GABAergic interneurons is enriched at excitatory postsynaptic densities (Garcia et al., 2000; Huang et al., 2000). We therefore explored the possible colocalization between NRG3 puncta on axons and ErbB4 on GABAergic interneuron dendrites by double immunofluorescence cytochemistry of transfected hippocampal neurons. Indeed, we observed that NRG3/V5 puncta extensively colocalized in trans with ErbB4 (Fig. 9A). Quantitative analyses revealed that a large fraction of NRG3 puncta colocalized with ErbB4 puncta at both DIV 10 (0.85 ± 0.02) and DIV 21 (0.86 ± 0.03); in parallel experiments, a similar overlap was observed between CRD-NRG1/V5 and ErbB4 (DIV 10: 0.86 ± 0.02; DIV 21: 0.92 ± 0.02) (Fig. 9B). This high degree of overlap suggested that dual-pass NRGs accumulate on axons through juxtacrine interactions with ErbB4 receptors. To directly address this possibility, neurons were transfected at DIV 8 with GFP and NRG3/V5 or CRD-NRG1/V5, and incubated for 2 d with soluble recombinant NRG1 EGF-like domain (60 nm). As shown in Figure 9C, GFP-positive neurites of both NRG3 and CRD-NRG1-transfected untreated neurons harbored numerous V5 puncta that colocalized with ErbB4. By contrast, no such puncta were observed in the presence of the EGF-like domain, indicating that the free EGF-like domain disrupted NRG puncta by competing for binding to ErbB4. Next, we cotransfected hippocampal neurons with a chimeric variant of NRG3/V5 in which its EGF-like domain was replaced by the corresponding domain of TGF-α (Fig. 9D), a member of the EGF superfamily previously shown to bind ErbB1 but not ErbB4 (Jones et al., 1999); CRD-NRG1/HA was cotransfected as an internal reference. Despite comparable expression levels in transfected HEK 293 cells and AAV-transduced cultured neurons (Fig. 9D), the chimeric TGF_NRG3/V5 protein failed to form axonal puncta, as demonstrated by the lack of V5 immunoreactivity at sites of CRD-NRG1/HA accumulation (Fig. 9E). Together, we conclude that axonal accumulation of NRG3 and CRD-NRG1 is dependent upon stable juxtacrine interactions with ErbB4 at varicosities, and that some of these sites correspond to glutamatergic synapses.
Axonal clusters of CRD-NRG1 and NRG3 are comprised of BACE-processed proteins
Ig-NRGs cluster as unprocessed proforms at SSC-type neuronal ER-PM contact sites (Vullhorst et al., 2015; this study). To determine whether axonal clusters of CRD-NRG1 and NRG3 are comprised of either processed or unprocessed forms, we transfected hippocampal neurons with NRG3/V5 and CRD-NRG1/V5 constructs and simultaneously detected their ECDs with anti-V5 and their c-terminal ICDs with antibodies specific for NRG1 (SC-348) or NRG3 (1352). In stark contrast to single-pass NRGs (Figs. 2⇑⇑–5), these experiments revealed that V5 puncta lacked accompanying ICD signals, suggesting that both NRGs accumulate as processed proteins (Fig. 10A). To further support this conclusion, we analyzed the apparent molecular masses of V5-immunoreactive bands by Western blotting of whole-cell extracts prepared from AAV-transduced hippocampal neurons. As shown in Figure 10B, the major NRG3 and CRD-NRG1 bands migrated at ∼70 kDa and ∼50 kDa apparent molecular mass, respectively, indicating that these bands correspond to their processed amino-terminal halves extending up to, but excluding, the downstream transmembrane domain (TMC).
Both BACE and the ADAM10/17 members of the family of extracellular metalloproteinases have been implicated in CRD-NRG1 processing in heterologous cell lines (Fleck et al., 2012). Western blot analysis revealed that chronic treatment (4 d) of AAV-transduced hippocampal neuron cultures with the BACE inhibitor BACE-IV (1 μm) virtually eliminated NRG3 processing and greatly reduced processing of CRD-NRG1 (Fig. 10C), consistent with a high degree of homology between NRG3 and CRD-NRG1 over a 10 amino acid stretch encompassing the BACE cleavage site (Fig. 11A). By contrast, blockade of metalloproteinases with GM6001 (10 μm) did not affect processing of either NRG3 or CRD-NRG1, indicating that BACE plays a dominant role in the cleavage of dual-pass NRGs in neurons. We also asked whether NMDARs are involved in the processing of NRG3 and CRD-NRG1, as demonstrated for Type II NRG1 (Fig. 6) and NRG2 (Vullhorst et al., 2015). However, inhibition of NMDARs by AP5 (100 μm) for 24 h did not affect processing of either CRD-NRG1 or NRG3 (Fig. 10D). Together, these findings indicate that, in stark contrast to single-pass Ig-NRGs, both dual-pass NRGs are processed by BACE independently of NMDAR activity.
Processing by BACE is required for axonal clustering of CRD-NRG1 and NRG3
We sought to explore a possible causal relationship between BACE-dependent NRG3/CRD-NRG1 processing and axonal clustering. Hippocampal neurons were transfected with GFP and NRG3/V5 or CRD-NRG1/V5, and treated for 4 d with 1 μm BACE-IV as described above. To analyze axonal processes, one set of neurons was colabeled with anti-ECD (V5) and anti-ErbB4 antibodies. To analyze cell bodies, another set was colabeled with anti-ECD (V5) and anti-ICD (NRG1: SC-348; NRG3: 1352) antibodies. Unlike untreated controls, neurons treated with BACE-IV lacked V5 puncta at sites where axons of transfected neurons intersected dendrites of ErbB4-positive neurons (Fig. 10E,G). Furthermore, BACE inhibition caused cell body accumulation of unprocessed NRG3 and CRD-NRG1 proforms (immunoreactive with both ECD and ICD antibodies) in some transfected neurons (Fig. 10F,H). To exclude possible indirect effects of chronic BACE inhibition on NRG trafficking, we used an orthogonal approach by mutating NRG3 and CRD-NRG1 in the area upstream of their respective TMC transmembrane domains to render them resistant to BACE cleavage (Fig. 11A). Functionality of these constructs was verified by Western blotting of whole-cell lysates made from hippocampal neurons transduced with AAVs harboring normal and cleavage-resistant (cr) versions of NRG3 and CRD-NRG1 (Fig. 11B). Next, hippocampal neurons were cotransfected with GFP, wild-type CRD-NRG1/HA, and either crCRD-NRG1/V5 or crNRG3/V5, and immunolabeled with antibodies against HA, V5, and ErbB4. While wild-type CRD-NRG1 colocalized in trans with ErbB4 on dendrites of untransfected neurons, puncta comprised of crCRD-NRG1 and crNRG3 were notably absent from axons (Fig. 11C,D). Instead, crNRG3 and crCRD-NRG1 consistently accumulated in cell bodies. Interestingly, we noticed that, whereas crCRD-NRG1 was broadly distributed throughout the entire cell body, crNRG3 immunoreactivity was mostly confined to the Golgi apparatus, as evidenced by colabeling with an antibody against the Golgi marker protein TGN38 (Fig. 11E). Conversely, a truncated variant of NRG3 with a stop codon inserted immediately upstream of the TMC (NRG3(Q360*)), which mimics its processed form and is structurally similar to the naturally occurring NRG1 SMDF isoform that is transcribed from the Type III promoter (Ho et al., 1995), formed axonal puncta regardless of BACE inhibition (Fig. 11F). Collectively, these findings strongly support the notion that BACE-dependent processing of dual-pass NRGs is a prerequisite for their axonal accumulation through juxtacrine interactions with ErbB4, and reveal a previously unknown functional relationship between proteolytic processing and subcellular targeting of NRGs in neurons.
Discussion
The main findings of this study, based on evidence from cultured hippocampal neurons, are as follows: (1) Like CRD-NRG1, NRG3 is a dual-pass transmembrane protein. (2) Single- and dual-pass NRGs accumulate in distinct subcellular domains. (3) This differential distribution reflects accumulation of unprocessed single-pass NRGs at SSC-type ER-PM contact sites and accumulation of processed dual-pass NRGs on axons as a result of juxtracrine receptor interactions. (4) NMDA receptor activity promotes processing of single-pass but not dual-pass NRGs. (5) In neurons, single-pass NRGs are processed by matrix metalloproteinases, whereas dual-pass NRGs are processed by BACE. Together, these findings (summarized schematically in Fig. 12) establish a new conceptual framework for NRG isoform diversity that is based on their cell biological properties.
Activity-dependent ectodomain shedding of single-pass NRGs from cell body ER-PM contact sites
The prevailing notion until now has been that axonal targeting represents a common feature of most neuronal NRGs. This paradigm is based partly on early immunohistological analyses of NDF/ARIA (synonymous with Type I NRG1) expression at the neuromuscular junction using antibodies directed against the EGF-like domain that is common to all NRG1 isoforms (Chu et al., 1995; Jo et al., 1995; Moscoso et al., 1995). These analyses were performed before the existence of the Type III promoter, which generates CRD-NRG1 and SMDF isoforms, was known and the functional importance of these NRG isoforms for the development and maintenance of sensory neurons and motorneurons recognized (Ho et al., 1995; Wolpowitz et al., 2000). Together with previous studies from our laboratory and by others (Gallart-Palau et al., 2014; Vullhorst et al., 2015), it is now becoming evident that an important aspect of NRG isoform diversity, at least in central neurons, is to target NRGs to distinct subcellular compartments, in addition to providing distinct spatiotemporal gene expression regulation during development and in the adult (Fig. 12A) (Buonanno and Fischbach, 2001; Falls, 2003; Birchmeier and Nave, 2008). This finding has important implications for the ways in which single-pass NRGs are thought to regulate neuronal functions. At the most fundamental level, they can be thought of as providing a local source of signal that acts in paracrine mode on nearby neurons or glia, or in autocrine mode as shown for NRG2 in ErbB4-positive GABAergic interneurons (Vullhorst et al., 2015). Interestingly, Type II NRG1-expressing GABAergic neurons in the RTN (this study) also coexpress ErbB4 (Gerecke et al., 2001) and therefore might also engage in autocrine signaling. The Ig-like domain, although not required for targeting per se, likely serves to retain the processed ectodomain near the source, thereby reinforcing the spatially restricted nature of this signal. Although not directly tested here, we predict that other Ig-NRG1s (Types IV-VI) share the properties of the single-pass NRGs tested in this study (Steinthorsdottir et al., 2004; Tan et al., 2007). It should also be noted that release of Ig-NRG1s from peripheral axons during early postnatal development was reported to support Schwann cell survival and differentiation (Esper and Loeb, 2004; Ma et al., 2011), suggesting that subcellular NRG isoform distribution might be differentially regulated during development and/or in different neuron types.
Previous studies implicated ADAMs (a disintegrin and metalloproteinase), in particular ADAM17/TACE, in NRG1 processing (Horiuchi et al., 2005; La Marca et al., 2011; Fleck et al., 2013). Our findings showing that NMDAR-dependent ectodomain shedding of single-pass NRGs is sensitive to metalloproteinase inhibition are consistent with those reports. How NMDAR activity promotes NRG ectodomain shedding by ADAMs is currently not known, although available evidence suggests that calcium influx via NMDARs could either directly regulate ADAMs (Nagano et al., 2004), possibly via PKC-dependent pathways (Loeb et al., 1998), or indirectly promote shedding by disrupting the integrity of ER-PM contacts (Fox et al., 2015).
Functional implications of NMDAR-dependent ectodomain shedding of single-pass NRGs from neuronal cell bodies
One plausible physiological effect of local autocrine signaling via single-pass Ig-NRGs is NMDAR-dependent regulation of intrinsic excitability in ErbB4-expressing GABAergic interneurons, a notion supported by earlier data from our group showing that soluble recombinant NRG1-EGFL acutely increases action potential threshold of cultured ErbB4-positive hippocampal interneurons by downregulating voltage-gated sodium channels (Janssen et al., 2012). Together with other reports showing that activation of (extrasynaptic) NMDARs shifts the voltage dependency of Kv2.1 channel function to more negative membrane potentials (Murakoshi et al., 1997; Misonou et al., 2004; Mulholland et al., 2008), it is conceivable that NMDAR-mediated NRG ectodomain shedding and augmentation of Kv2.1 channel function work in concert to downregulate intrinsic excitability via opposing effects on voltage-gated sodium and potassium channels, and could serve as an adaptive response to potentially harmful increases in ambient glutamate levels. Moreover, bidirectional signaling between NRG2-ErbB4 and NMDARs in GABAergic interneurons modulate NMDAR-mediated currents (Vullhorst et al., 2015) and could therefore regulate excitatory/inhibitory balance in cortical microcircuits. This functional link could also be pertinent to the recently identified role of ErbB4 signaling in PV+ GABAergic interneurons for critical period plasticity in the visual cortex (Gu et al., 2016; Sun et al., 2016), and might constitute a point of convergence for separate findings on the roles of NMDARs, the extracellular matrix (perineuronal nets), and ErbB4 in PV+ GABAergic interneurons (Pizzorusso et al., 2002; Morishita et al., 2015; Kaplan et al., 2016).
Dual-pass NRGs accumulate on axons following processing by BACE
As illustrated in Figure 12B, our results indicate that processing of dual-pass NRGs follows a different route than that of single-pass Ig-NRGs. Intracellular cleavage by BACE, as revealed by the accumulation of unprocessed or cleavage-resistant NRG in the Golgi and other vesicular compartments, is consistent with studies showing that BACE preferentially cycles between the trans-Golgi network and endosomes (Vassar et al., 1999; Yan et al., 2001), and that the pH in these compartments provide conducive conditions for BACE enzymatic activity (Yamashiro and Maxfield, 1984; Demaurex et al., 1998; Fukumoto et al., 2002). Furthermore, it is in agreement with a recent study in HEK 293 cells showing that CRD-NRG1 processing by BACE does not require surface delivery or endocytosis (Ben Halima et al., 2016). However, that and other studies in heterologous cell lines were, by design, not able to capture the requirement of BACE-mediated processing for axonal clustering of CRD-NRG1 and NRG3 in neurons. This striking result suggests that BACE processing enables juxtacrine interactions with ErbB receptor. In further support of the notion that the NTD of dual-pass NRGs alone is sufficient for axonal clustering, we demonstrated that a NRG3 variant with a stop codon immediately upstream of the TMC (NRG3(Q360*)), that is structurally similar to the naturally occurring NRG1 isoform SMDF (Ho et al., 1995), accumulates on axonal varicosities regardless of BACE activity. Whether this transport is directional or whether preferential axonal accumulation is merely the result of selective retention of processed CRD-NRG1/NRG3 by ErbB4, as suggested by the ability of soluble recombinant EGF-like domain to disrupt NRG puncta and by the failure of chimeric TGF_NRG3 (unable to bind ErbB4) to cluster on axonal varicosities that intersect with ErbB4-positive dendrites, remains to be determined. Additional processing of CRD-NRG1 upstream of the EGF-like domain by BACE or ADAM10/17, as reported recently (Fleck et al., 2013), is compatible with this model and would be expected to release the EGF-like domain from either the cell body or the axonal compartment, depending on the subcellular locus of this additional cleavage event. Importantly, while our results indicate that, at low to moderate expression levels, processed dual-pass NRGs preferentially accumulate on axons by virtue of their juxtacrine interactions with ErbB receptors (ErbB4 in neurons and ErbB3 on myelinating glia), their subcellular distribution is likely more widespread in neurons that express higher levels, such as sensory neurons (Canetta et al., 2011). Notwithstanding, a central theme emerging from this work is the notion of isoform-specific short- and long-range signaling by NRGs (Fig. 12A), a concept that is consistent with data from loss-of-function and gain-of-function studies demonstrating that Ig- and Type III NRG1 isoforms are not functionally redundant (Hippenmeyer et al., 2002; Michailov et al., 2004). Our finding showing the requirement of BACE for CRD-NRG1 processing and subsequent interactions with ErbB receptors is also consistent with previous reports of severe hypomyelination in the PNS of BACE-1 KO mice, which essentially phenocopy NRG1 Type III mutant mice (Wolpowitz et al., 2000; Hu et al., 2006; Willem et al., 2006).
NRG3 and CRD-NRG1 share many cell biological properties
This is the first report to demonstrate that NRG3 is a dual-pass transmembrane protein. It also shows that NRG3 traffics as a processed protein to axons where it interacts with ErbB receptors in juxtacrine manner. NRG3 is therefore in a group with CRD-NRG1, both in terms of signaling mode and axonal accumulation, suggesting some functional redundancy. Available data on CRD-NRG1 functions in the CNS point to a role for dual-pass NRGs in the regulation of synaptic transmission, for example, through effects on presynaptic nAChRs (Hancock et al., 2008; Zhong et al., 2008), rather than myelination (Brinkmann et al., 2008). However, ISH analyses in the adult mouse brain indicate that NRG3 expression is higher than CRD-NRG1 in the hippocampus and the neocortex (Longart et al., 2004), where NRG3-positive cells likely correspond to glutamatergic associative, commissural, and cortifugal neurons that project to cortical and subcortical structures (Molyneaux et al., 2007). Based on our findings, future studies should focus on the role of NRG3-ErbB4 signaling in the modulation of synaptic properties at postsynaptic targets in projection areas of cortical NRG3-expressing neurons. This is particularly important given the growing body of literature genetically linking NRG3 in mice and humans with cognition and behavioral traits, such as impulsivity and nicotine dependence, that are relevant to many psychiatric disorders (see, e.g., Hayes et al., 2016; Kao et al., 2010; Loos et al., 2014; Tost et al., 2014; Turner et al., 2014).
In conclusion, this work establishes a new conceptual framework to understand NRG isoform diversity in cell biological terms based on findings in cultured hippocampal neurons. It will be interesting to explore whether, and to what extent, the functional relationship between NRG transmembrane topology and subcellular distribution is observed during development and in different central and peripheral neuron types, and to determine whether other alternatively spliced NRG domains not directly tested here, such as the stalk and carboxyl-terminal tail regions, play any role in differential targeting.
Footnotes
This work was supported by Eunice Kennedy Shriver Institute of Child Health and Human Development Intramural Research Program. We thank Drs. Vincent Schram and Carolyn Smith (Porter Neuroscience Center imaging core) for expert assistance with confocal microscopy; and Dr. Jung-Hwa Tao-Cheng (National Institute of Neurological Disorders and Stroke EM facility) for help with immunogold EM microscopy.
The authors declare no competing financial interests.
- Correspondence should be addressed to Dr. Andres Buonanno, Eunice Kennedy Shriver National Institute of Child Health and Human Development, 35 Lincoln Drive, Room 2C-1000, Bethesda, MD 20892. buonanno{at}mail.nih.gov