Abstract
Mature dentate granule cells in the hippocampus receive input from the entorhinal cortex via the perforant path in precisely arranged lamina, with medial entorhinal axons innervating the middle molecular layer and lateral entorhinal cortex axons innervating the outer molecular layer. Although vastly outnumbered by mature granule cells, adult-generated newborn granule cells play a unique role in hippocampal function, which has largely been attributed to their enhanced excitability and plasticity (Schmidt-Hieber et al., 2004; Ge et al., 2007). Inputs from the medial and lateral entorhinal cortex carry different informational content. Thus, the distribution of inputs onto newly integrated granule cells will affect their function in the circuit. Using retroviral labeling in combination with selective optogenetic activation of medial or lateral entorhinal inputs, we examined the functional innervation and synaptic maturation of newly generated dentate granule cells in the mouse hippocampus. Our results indicate that lateral entorhinal inputs provide the majority of functional innervation of newly integrated granule cells at 21 d postmitosis. Despite preferential functional targeting, the dendritic spine density of immature granule cells was similar in the outer and middle molecular layers, which we speculate could reflect an unequal distribution of shaft synapses. However, chronic blockade of neurotransmitter release of medial entorhinal axons with tetanus toxin disrupted normal synapse development of both medial and lateral entorhinal inputs. Our results support a role for preferential lateral perforant path input onto newly generated neurons in mediating pattern separation, but also indicate that medial perforant path input is necessary for normal synaptic development.
SIGNIFICANCE STATEMENT The formation of episodic memories involves the integration of contextual and spatial information. Newly integrated neurons in the dentate gyrus of the hippocampus play a critical role in this process, despite constituting only a minor fraction of the total number of granule cells. Here we demonstrate that these neurons preferentially receive information thought to convey the context of an experience. Each newly integrated granule cell plays this unique role for ∼1 month before reaching maturity.
Introduction
As the entry point to the trisynaptic hippocampal circuit, the dentate gyrus has several interesting features, including a “sparse” network design (Boss et al., 1985; Rolls et al., 1998), laminated inputs carrying distinct informational content (Witter, 2007; Knierim et al., 2014), and the participation of mature granule cells alongside the continuous integration of newly generated neurons (Overstreet-Wadiche and Westbrook, 2006; Ming and Song, 2011). Hippocampal granule cells receive highly laminar inputs from the entorhinal cortex within the molecular layer of the dentate gyrus. Input from the medial entorhinal cortex, conveying spatial cues, is restricted to the middle molecular layer (MML; Ferbinteanu et al., 1999; Hafting et al., 2005; Hargreaves et al., 2005; Yasuda and Mayford, 2006; Witter, 2007; Van Cauter et al., 2013), whereas input from the lateral entorhinal cortex conveying contextual information is restricted to the outer molecular layer (OML; Hargreaves et al., 2005; Hunsaker et al., 2007; Witter, 2007; Deshmukh and Knierim, 2011; Yoganarasimha et al., 2011; Tsao et al., 2013). Despite being substantially outnumbered by mature granule cells, newly integrated granule cells are thought to uniquely contribute to pattern separation (Clelland et al., 2009; Sahay et al., 2011; Nakashiba et al., 2012; Tronel et al., 2012). That is, they foster the ability to distinguish between subtly different contexts, one of the primary functions of the dentate gyrus (Deng et al., 2010; Aimone et al., 2011). This unique function must occur during a narrow time window between initial integration into the perforant path circuit (∼3 weeks postmitosis) and the complete maturation of synapses (>8 weeks postmitosis; van Praag et al., 2002; Ambrogini et al., 2004; Overstreet et al., 2004; Laplagne et al., 2006; Overstreet-Wadiche et al., 2006; Zhao et al., 2006; Kumamoto et al., 2012; Brunner et al., 2014).
The search for unique functions of newly integrated neurons has largely focused on intrinsic properties, such as enhanced excitability and plasticity (Schmidt-Hieber et al., 2004; Abrous et al., 2005; Ge et al., 2007; Marín-Burgin et al., 2012; Dieni et al., 2013). However, newborn neurons also undergo rapid changes in connectivity in the first few weeks after mitosis. This process likely differs from synapse remodeling in early development (Goodman and Shatz, 1993; Katz and Shatz, 1996; Walsh and Lichtman, 2003), as newborn neurons integrate into an already established circuit (Toni et al., 2007, 2008) and compete for synaptic innervation with pre-existing axons of the perforant path. Rabies-based circuit mapping also suggests that inputs to newly integrated neurons may differ from mature granule cells (Vivar et al., 2012).
Here, using retroviral labeling of newborn neurons and laminar-specific optogenetic stimulation of entorhinal inputs, we directly assayed functional synaptic integration of newborn granule cells over the course of excitatory synapse development. Our results indicate that newly integrated granule cells preferentially receive functional synaptic input from the lateral entorhinal cortex, whereas mature granule cells receive balanced input from the medial and lateral entorhinal cortex. Although medial perforant path (MPP) input was weak in newly integrated granule cells, chronic silencing of this pathway using tetanus toxin impaired the functional and morphological development of lateral perforant path (LPP) inputs.
Materials and Methods
Animals.
We used male and female C57BL/6 mice. Animal procedures were performed in accordance with the Oregon Health and Science University Institutional Animal Care and Use Committee, Biosafety Committee protocols, and National Institutes of Health guidelines for the safe handling of animals.
Viral constructs.
To selectively transfect and visualize adult-born hippocampal granule cells, we used a replication-deficient Moloney murine leukemia virus-based retroviral vector that requires cell mitosis for transduction (Luikart et al., 2011). The retrovirus contained an internal ubiquitin 6 promoter that drives expression of GFP (viral titer 105) as described previously (pRubi-GFP; Luikart et al., 2011). To express the light-activated ion channel channelrhodopsin-2 (ChR2) selectively in entorhinal cortex axons projecting to the MML or OML, we stereotaxically injected an AAV9-CAG-ChR2-eGFP viral construct (University of North Carolina Viral Core) into the medial or lateral entorhinal cortex. Laminar-specific labeling was confirmed by examination of GFP fluorescence in the entorhinal cortex and in the dentate molecular layer. Injections affecting both the lateral and medial entorhinal cortex were excluded from the analysis. To selectively silence axons, we made a custom tetanus neurotoxin (TeNT) virus (AAV9-CAG-TeNT-mCherry, viral titer 1013) by cloning a 2kb fragment encoding the light chain of tetanus toxin fused with mCherry into an AAV backbone using InFusion cloning. AAV vectors were serotyped with AAV9 coat proteins and packaged at the University of North Carolina Vector Core.
Stereotaxic injections.
Stereotaxic viral injections into 6–8-week-old male and female C57BL/6 mice were performed using a Model 1900 Stereotaxic Alignment System (David Kopf Instruments). Mice were anesthetized with 2% isoflurane, and a small incision was created over the skull following application of artificial tears to the eyes and antibiotic/iodine around the incision site. A Model 1911 Stereotaxic Drill (David Kopf Instruments) was used to create burr holes over the injection site. pRubi-GFP retrovirus to label mitotically active granule cells was injected into the dentate gyrus (coordinates, from bregma: anteroposterior, −1.9 mm; lateromedial: ±1.1 mm; dorsoventral, −2.5 mm, −2.3 mm). One microliter of nondiluted virus was injected at 250 nl/min with a 10 μl Hamilton syringe fitted with a 30 gauge needle using a Quintessential stereotaxic injector (Stoetling). After each injection, the needle was left in place for 1 min to allow for diffusion of the virus and prevent backflow. Injections of AAV9-CAG-CHR2-GFP into the lateral entorhinal cortex were made at the following coordinates: anteroposterior (from bregma), −3.4 mm; lateromedial (from bregma), ±4.0 mm; dorsoventral (from brain surface), −2.4 mm. Injections of AAV9-CAG-ChR2-GFP or AAV9-CAG-TeNT-mCherry into the medial entorhinal cortex were made at the following coordinates: anteroposterior (from bregma), −4.5 mm; lateromedial (from bregma), ±3.0 mm; dorsoventral (from brain surface), −3.2 mm. To control for differences in the degree of innervation from the medial and lateral entorhinal cortex (Dolorfo and Amaral, 1998; Ohara et al., 2013), injections in the dentate gyrus were targeted to the intermediate region across the septotemporal axis (van Groen et al., 2003; Strange et al., 2014), which receives approximately equal innervation from the medial and lateral entorhinal cortex. Where appropriate, pRubi and ChR2 were injected during the same surgery. Following injection, mice received topical lidocaine and drinking water with cherry-flavored Tylenol, and were monitored every 24 h for 3 d.
Immunohistochemistry and spine counts.
Transcardiac perfusion of deeply anesthetized mice [2% 2,2,2-tribromoethanol (0.7–0.8 ml)] was performed with ice-cold 4% sucrose in 0.1 m PBS followed by fixative containing 4% sucrose and 4% paraformaldehyde (PFA) in PBS. Brains were removed and postfixed (4% PFA, 1× PBS) overnight at 4°C. The hippocampus was sectioned (coronal, 100 μm) using a Leica VT 1000S vibratome. Sections were permeabilized with 0.4% Triton X-100 in PBS (PBS-T), blocked with filtered 10% horse serum in PBS-T and incubated in primary antibody overnight in 1.5% horse serum in PBS-T. Primary antibodies included the following: 1:300 Alexa Fluor 488-conjugated rabbit anti-GFP (catalog #A21311, Invitrogen), 1:500 anti-VGlut2 (catalog #135 404, Synaptic Systems), and 1:500 anti-glial-associated fibrillary protein (GFAP; catalog #Z-0334, DAKO). Sections were then rinsed with PBS-T and incubated for 2–3 h at room temperature in PBS-T with the following secondary antibodies: 1:300 Alexa Fluor 488-conjugated anti-GFP (A21311, Invitrogen), 1:200 goat anti-guinea pig Alexa Fluor 568 (A11075, Invitrogen), and 1:200 goat anti-rabbit Alexa Fluor 488 (A11034, Invitrogen). The mCherry-TeNT signal was extremely bright and was visualized without use of secondary enhancement with antibodies. The tissue was counterstained with DAPI using Fluoromount G with DAPI (SouthernBiotech). All antibodies have been well characterized in prior studies in our laboratory, and staining was not observed when the primary antibody was omitted.
Images were acquired using either a Zeiss LSM 770 or LSM 780 laser-scanning confocal microscope on a motorized AxioObserver Z1 inverted scope (Carl Zeiss MicroImaging). Dendrites for spine analysis were imaged using a 63× objective (1.4 numerical aperture, oil, 2× zoom). For each imaged cell, dendritic segments in the MML and the OML were imaged. The MML and OML were distinguished based on VGluT2 immunofluorescence pattern, which begins at the border between the inner molecular layer and the MML. MML dendritic segments were therefore imaged at the beginning of the VGluT2 staining nearest the granule cell body layer, whereas OML dendritic segments were imaged at the distal tip of the molecular layer. Spine density analysis was performed blinded to experimental condition. The Cell Counter plugin in FIJI (National Institutes of Health) was used to count and categorize spines (Harris et al., 1992), and Simple Neurite Tracer (FIJI) was used to measure dendritic segment length. Spine density and spine type between the MML and OML was compared across conditions (control and TeNT overexpression) and developmental time points (3–12 weeks after viral injection). Spine morphology was classified into two groups: mushroom spines, containing a spine head (2× shaft diameter) or filopodia-like for protrusions lacking a spine head.
Electrophysiology.
Electrophysiological recordings were made 21 d after viral injection into the entorhinal cortex to allow for construct expression. Acute brain slices were prepared as described previously (Perederiy et al., 2013). Briefly, animals were anesthetized with an intraperitoneal injection of 2% 2,2,2-tribromoethanol (0.7–0.8 ml), and perfused with an ice-cold, oxygenated modified ACSF, which contained the following (in mm): 110 choline-Cl, 7 MgCl2, 2.5 KCl, 1.25 NaH2PO4, 0.5 CaCl, 1.3 Na-ascorbate, and 25 NaHCO3. Hippocampi were resected and cut at 300 μm transverse to the longitudinal axis of the hippocampus on a Leica 1200S vibratome. Slices from the intermediate region (Strange et al., 2014) were used for these studies. Slices were allowed to incubate for 1 h in 37°C normal ACSF, which contained the following (in mm): 125 NaCl, 2.5 KCl, 2.0 CaCl, 1.0 MgCl2, 1.25 NaH2PO4, 25 NaHCO3, and 25 glucose.
For extracellular field recording, we used glass pipettes (2–3 MΩ) filled with normal ACSF placed into the lamina of interest. Presynaptic fibers were stimulated using either a bipolar electrode (3–7 V, 0.5 V steps) or optogenetic stimulation (1 ms pulses of 470 nm blue light). Whole-cell voltage-clamp recordings were made using glass pipettes (5–8 MΩ). Mature granule cells were selected based on input resistance <750 MΩ (495 ± 37 MΩ) and soma position in the outer one-third of the granule cell layer (Ambrogini et al., 2004; Overstreet-Wadiche and Westbrook, 2006). The whole-cell recording solution contained the following (in mm): 100 gluconic acid, 0.2 EGTA, 5 HEPES, 2 Mg-ATP, 0.3 Li-GTP, pH 7.2, 295 mOsm, adjusted with 50% CsOH such that final concentration of Cs-gluconate was 100–120 mm. The liquid junction potential (−7 mV) was not corrected. Series resistance of the cell was continually monitored with a 10 mV hyperpolarizing step, and cells with input resistance >25 MΩ at any point were excluded from analysis. Data were acquired at 10 kHz and Bessel filtered at 4 kHz on a Multiclamp 700B (Molecular Devices) and recorded using AxoGraphX acquisition software (www.axograph.com).
Optogenetic stimulation was provided by a 470 nm LED (ThorLabs). Light pulses (1 ms) were delivered through the microscope objective, which was centered over the appropriate lamina. Optical stimulation was delivered over a range of intensities until a maximal response was elicited, which was then used for the remainder of the experiment. Optically evoked EPSCs were collected from mature and newly integrated cells in the same cohort of animals. Peak EPSC amplitudes were measured using a built-in routine in AxographX. Miniature EPSCs (mEPSCs) were recorded in the presence of SR95531 (10 μm) and TTX (1 μm) to isolate miniature excitatory events. Quantal events were detected using a sliding window template consisting of a single exponential (−10 pA, 1 ms rise time, 6 ms decay time constant). Individual events were then manually inspected. mEPSC analysis was performed with the experimenter blinded to condition.
Cell culture.
Mouse hippocampal neurons were cultured on glial microislands as described previously (Tovar et al., 2009). Briefly, neonatal (postnatal day 0–1) male mice were decapitated, and the hippocampi were dissected. Microislands were generated by plating at 125,000 cells/35 mm dish. After 7 d in vitro, cultures were treated with 200 μm glutamate for 30 min to kill any neurons. Neurons were then plated on the remaining glial feeder layer at 25,000 cells/35 mm dish and maintained in a tissue culture incubator (37°C, 5% CO2) until use. The culture medium consisted of minimum essential media with 2 mm glutaMAX (Invitrogen), 5% heat-inactivated fetal calf serum (Lonza), and 1 ml/L MITO+ Serum Extender (BD Biosciences). The culture medium was supplemented with glucose to a final concentration of 21 mm. For validation of tetanus toxin constructs, cultured neurons were transduced at 1 d in vitro by replacing 50% of the culture medium with virus-containing medium (1 μl of virus in 500 μl of medium). After 24 h, the virus-containing medium was removed and replaced with fresh complete medium.
Whole-cell voltage-clamp recordings were made from cultured neurons 3–16 d in vitro. The extracellular recording solution consisted of the following (in mm): 158 NaCl, 2.4 KCl, 1.3 CaCl2, 1 MgCl2, 10 HEPES, and 10 d-glucose, pH 7.4, 320 mOsmol. Glass pipettes (2–6 MΩ) were filled with a solution which contained the following (in mm): 140 K-gluconate, 4 CaCl2, 8 NaCl, 2 MgCl2, 10 EGTA, 10 HEPES, 4 Na2ATP, and 0.2 Na2GTP, pH 7.4, 319 mOsmol. Autaptic EPSCs were elicited from neurons in isolation on a glial microisland with a brief voltage command (+30 mV, 0.5 ms) to elicit an unclamped action potential. Recordings were made in the presence of 10 μm SR95531 and 10 μm (R)-CPP [(R)-3-(2-carboxypiperazin-4-yl)propyl-1phosphonic acid] to block GABAA and NMDA receptors, respectively. Data were acquired using an Axopatch 1C amplifier and AxographX (www.axograph.com) acquisition software. In all recordings, the series resistance was <10 MΩ and was continuously monitored with a −10 mV step. Data were low-pass Bessel filtered at 4 kHz and sampled at 10 kHz.
Electron microscopy.
Ultrastructural analysis of control and TeNT-expressing MPP axons were conducted 21 d after viral injection, as in Perederiy et al., 2013. Two control (pRubi-expressing) and two pRubi-expressing and TeNT-expressing animals were perfused with PBS followed by a 3.75% acrolein and 2% PFA fixative. The brains were then extracted and stored in 2% PFA for ≥1 h before sectioning at 40 μm in the coronal plane using a Leica VT 1000S vibratome (Leica Microsystems). Sections including the dorsal hippocampus were incubated in 1% sodium borohydride for 30 min to reduce nonspecific binding, followed by incubation in 10% Triton-X for 45 min to increase antibody penetration. Next, sections were blocked with 0.5% bovine serum albumin for 1 h followed by primary antibody incubation directed against pRubi-GFP (rabbit α-GFP, 1:500; Millipore, catalog #AB3080) or TeNT-mCherry (Mouse α-mCherry, 1–500; Living Colors, catalog #632543) overnight at 4°C. Following primary antibody incubation, the tissue was thoroughly washed with 0.4% Triton-X. To visualize GFP, tissue was incubated in biotinylated goat α-rabbit secondary antibody (1:200; Vector Laboratories, catalog #BA-1000) for 2 h at room temperature followed by avidin-binding complex (Vector Laboratories) for 30 min then reacted with DAB-H2O2 solution for 5.5 min. To visualize mCherry, the tissue was incubated in goat α-mouse gold-conjugated IgG (1:50; Aurion, catalog #800.422) for 2 h at room temperature. Tissue was then washed with citrate buffer and silver-enhanced for 6.5 min.
Following DAB and/or immunogold reactions, the tissue was fixed in 1% osmium tetroxide for 15 min in 0.1 m phosphate buffer. Tissue was then washed and dehydrated through an ethanol series before being incubated in propylene oxide (10 min) and propylene oxide:EMBed (1:1 solution) overnight. Finally, the tissue was embedded in Aclar resin and placed in an oven at 60°C for 24 h. Coronal sections measuring 700 nm were made using a Leica EM UC6 vibratome (Leica Microsystems). Some sections were mounted on glass slides and stained with toluidine blue in 0.5% sodium tetraborate to assist in region selection. Tissue from the suprapyramidal blade of the dentate gyrus was sectioned at 70 nm using an ultramicrotome (Leica Microsystems). Sections were placed on 200 square mesh copper/rhodium grids and counterstained with 5% uranyl acetate and Reynold's lead citrate. The MML was imaged at 11,000× on an FEI Technai G2 12 BioTWIN microscope (Thermo Fisher Scientific) at 80 kV. At least 10 representative images were selected in both control and TeNT-expressing conditions.
Experimental design and statistical analysis.
Male and female mice were used for all experiments except developmental spine analysis, in which only males were used to provide more consistent results across animals. All data are reported as mean ± SEM unless otherwise noted. For statistical analysis of electrophysiological datasets, the number of cells is reported in the text and was collected from 3–6 animals for each experiment. Statistical analysis was performed in Prism6 (GraphPad Software). Data were assumed to be normally distributed, in accordance with previous datasets in this circuit. Spine density data were analyzed using a two-way repeated-measures ANOVA (repeated measures: days postmitosis, lamina). Pooled data were analyzed using an ANOVA with Holm–Sidak post hoc analysis. Electrophysiology data were analyzed using two-tailed unpaired Student's t tests. Linear regressions were performed using an extra-sum-of-squares F test. Sample sizes were chosen to detect an effect size of 20%, based on previous experiments, with a power of 0.8. Statistical significance was defined as α < 0.05, and was adjusted for post hoc comparisons (Holm–Sidak), as appropriate.
Results
Adult-born granule cells receive preferential functional input from OML axons
To examine the perforant path input onto newborn granule cells, we first compared electrical and optogenetic laminar-specific stimulation (Fig. 1A). Approximate targeting of the MPP or LPP was possible using a bipolar electrode as demonstrated by changes in the polarity of the field EPSP (fEPSP; Fig. 1B; Andersen et al., 1966). However, to specifically activate laminar-specific inputs to mature and newly integrating granule cells, we optogenetically labeled axons by injecting AAV9-CAG-ChR2-eGFP into either the medial or lateral entorhinal cortex, which provided precise labeling of either the MPP or LPP fibers in the molecular layer (Fig. 1C). To ensure that ChR2 expression was comparable across animals and slices, we used a range of stimulus intensities to determine a maximal evoked EPSC in mature cells from the MPP and LPP. Consistent with effective and laminar-specific ChR2 expression, the maximal EPSC amplitudes were the same for optical and electrical stimulation in the MPP (electrical stimulation: 105.0 ± 17.4 pA, n = 7 cells; optical stimulation: 123.0 ± 24.7 pA, n = 19 cells; unpaired t test: 0.68) and the LPP (electrical stimulation: 97.1 ± 20.6 pA, n = 6 cells; optical stimulation: 105.9 ± 31.3 pA; n = 16 cells; unpaired t test: 0.87) in mature granule cells.
Laminar-specific electrical and optical stimulation. A, Circuit schematic demonstrating laminar-specific input from the medial entorhinal cortex (MEC) and the lateral entorhinal cortex (LEC). Within the molecular layer of the dentate gyrus, MEC axons reside in the MML, whereas lateral entorhinal cortex axons reside in the OML. B, Demonstration of laminar-specific input using fEPSP recordings. When the field recording electrode and bipolar electrode are within the same layer, a current sink is observed as a negative voltage deflection. A current source can be observed when the field electrode and bipolar electrode are in adjacent layers. Bath application of NBQX blocked the field response (green). C, Laminar-specific expression of ChR2 following viral injection into the medial entorhinal cortex (left) or lateral entorhinal cortex (right). Green, ChR2-GFP; blue, DAPI. Scale bar, 100 μm. D, Comparison of lamina-specific optogenetic stimulation in mature (black) and newborn cells (green). E, Comparison of the strength of the maximal light-evoked EPSCs from each lamina in mature and newborn (postnatal day 21) granule cells. F, Comparison of the AMPA/NMDA ratio in newly integrated granule cells following laminar-specific stimulation of the MPP or LPP. ***p < .001, ****p < .0001.
As expected for mature cells, including mature granule cells generated from adult-born granule cells (Laplagne et al., 2006), the similar maximal amplitude of light-evoked EPSCs from the MPP or LPP indicates that mature cells receive robust and balanced excitatory input from both layers. In newly generated granule cells, inputs from both the medial and lateral entorhinal cortex can be detected at >14 d postretroviral labeling (Kumamoto et al., 2012). However, surprisingly, in newly integrated neurons (identified by retroviral labeling at 21 d postmitosis), we found that the strength of LPP inputs was nearly 10-fold larger than inputs from the MPP (MPP: 7.8 ± 3.1 pA, n = 14 cells; LPP: 72.2 ± 15.2 pA, n = 18 cells; Student's unpaired t test: t(30) = 3.68, p = 0.0009; Fig. 1D,E). Despite the larger optically evoked EPSCs resulting from optical stimulation of the LPP, the band of fluorescent intensity of labeled axons was similar across the MML and the OML (Fig. 1C). Furthermore, because optically evoked responses in mature neurons were similar across laminae, it is unlikely that differences in innervation contribute to these results. Additionally, our slices were taken from the intermediate region of the longitudinal axis of the hippocampus, which has similar innervation patterns as the most dorsal regions (for review, see Strange et al., 2014). Recordings from mature and newly integrated neurons were obtained from the same animals, supporting the preferential functional innervation by LPP to newly integrated neurons (Fig. 1D,E).
The relatively reduced strength of MPP inputs in newly integrated granule cells could not be attributed to NMDA-only or “silent” synapses, as NMDA-evoked responses showed similar amplitude differences (MPP: 3.27 ± 1.55 pA, n = 13 cells; LPP: 37.68 ± 10.38 pA, n = 13 cells; Student's unpaired t test: t(24) = 3.28; p = 0.0032). There also was no difference in the AMPA/NMDA ratio between lamina (MPP: 5.2 ± 1.3, n = 13 cells; LPP: 3.66 ± 0.58, n = 13 cells; Student's unpaired t test: t(24) = 1.04; p = 0.31; Fig. 1F). These results indicate that newly integrated neurons receive preferential, but not exclusive, functional input from the LPP.
Synapse formation in newborn granule cells does not involve competitive elimination
Given the differences in synaptic strength between LPP and MPP axons in newly integrated granule cells, we examined whether exuberant synapse formation occurs in the LPP, followed by competitive elimination and synaptic rebalancing, as is observed during early development (Goodman and Shatz, 1993; Katz and Shatz, 1996; Walsh and Lichtman, 2003). We labeled mitotically active neurons in 6-week-old male mice with a retroviral pRUBI-GFP vector (Luikart et al., 2011), then examined spine density in granule cells in weekly intervals from 3 to 12 weeks postinjection in the MML and OML. Despite the functional difference in synapse strength in newly integrated granule cells, there was no difference in spine density between laminae at any time point (two-way repeated measure ANOVA: F(1,2) = 0.195, p = 0.7). In grouped data from both laminae, the spine density increased from 3 to 4 weeks after injection (3 weeks: 0.94 ± 0.07 spines/μm, n = 35 cells from 3 animals; 4 weeks: 1.52 ± 0.03 spines/μm, n = 35 cells from 3 animals; Holm–Sidak post hoc comparison: t(47) = 4.5, p < 0.001; Fig. 2A,B), but remained constant from 4 to 12 weeks after injection (Holm–Sidak post hoc comparison: p > 0.05). The spine density at 12 weeks was within the range of reported values for mature granule cells (Parent et al., 2016). There was a lamina-independent increase in the proportion of dendritic spines with filopodial-like morphology (compared with mushroom) in the MML (3 weeks: 13.3 ± 1.3% of total spines, n = 14 cells; 6 weeks: 23.21 ± 2.6% of total spines, n = 16 cells; Student's unpaired t test: t(28) = 3.29, p = 0.0027; Fig. 2A,C) and OML (3 weeks: 12.53 ± 2.3% of total spines, n = 10 cells; 6 weeks: 25.42 ± 2.6% of total spines, n = 13 cells; Student's unpaired t test: t(21) = 3.54, p = 0.002; Fig. 2A,C).
Synaptic maturation and development. A, Spine density measurements in MML (top) and OML (bottom) of 3-week-old and 6-week-old dentate granule cells. Scale bar, 5 μm. B, Developmental increase in spine density across cell development in MML (black) and OML (red). Inset, Average spine density across layers increases between 3 and 4 weeks after mitosis, then remains constant between 4 and 12 weeks. C, Developmental increase in the percentage of spines with filopodial morphology in both MML (black) and OML (red). D, mEPSC recordings in the presence of 10 μm SR95531 and 1 μm TTX to isolate excitatory events. mEPSCs were recorded at 3 and 6 weeks after mitosis. E, There was no difference in the mEPSC frequency at 3 and 6 weeks after mitosis. F, There was a significant decrease in mEPSC amplitude, suggesting weaker synaptic inputs at 6 weeks after mitosis. *p < .05, **p < .01, ***p < .001.
In contrast to spine density and morphology, we did not detect a change in mEPSC frequency between 3 and 6 weeks after mitosis (3 weeks: 0.08 ± 0.02 Hz, n = 15 cells; 6 weeks: 0.05 ± 0.01 Hz, n = 10 cells; Student's unpaired t test: t(23) = 1.32, p = 0.20; Fig. 2D,E). At 6 weeks after mitosis, there was a small and marginally significant decrease in the mESPC amplitude (3 weeks: 16.2 ± 0.8 pA, n = 15 cells; 6 weeks: 13.5 ± 1.0 pA, n = 10 cells, Student's unpaired t test: t(23) = 2.1, p = 0.045; Fig. 2D,F), perhaps consistent with the observed increase in filopodial spines (Holtmaat and Svoboda, 2009). Our data suggest that during the period of functional synaptic rebalancing in the perforant path, synapse formation by newly integrating granule cells does not follow a trajectory of a net overabundant spiny synapse formation followed by synaptic pruning.
Chronic silencing of the MPP with TeNT
To chronically silence axonal input in a laminar-specific manner, we virally expressed tetanus toxin light chain (TeNT), which cleaves the SNARE complex protein synaptobrevin-2, thereby preventing neurotransmitter release (Schiavo et al., 1992). We chose to use tetanus toxin because it has the advantage of completely silencing axons, with the disadvantage that the effects are irreversible. As the degree of silencing may influence effects on excitatory synapse formation (Bagley and Westbrook, 2012), we carefully validated our tetanus toxin vector in vitro and in vivo. First, we examined AMPA receptor currents in neurons in autaptic cultures (Tovar et al., 2009). In control cells, an unclamped action potential at the soma elicited a large-amplitude, NBQX-sensitive EPSC in all cells (n = 7 cells; Fig. 3A,B). However, expression of TeNT by viral transfection completely abolished EPSCs (EPSC success rate: 0.22 ± 0.2%, n = 10 cells, Student's unpaired t test: t(14) = 392.9 p < 0.0001; Fig. 3A,B).
Silencing synaptic input with tetanus toxin expression. A, Comparison of synaptic responses in autaptically cultured neurons in control (left) and following tetanus toxin infection (TeNT). The shaded area indicates the AMPA-receptor EPSC. B, Expression of TeNT abolishes synaptic responses in autaptically cultured neurons. C, Schematic of TeNT viral injection into the medial entorhinal cortex, which will functionally silence axons in the MML of the dentate gyrus. D, Expression of TeNT in the MML dramatically reduces the intensity of VGluT1 expression in the MML, indicating a disruption of presynaptic function. Scale bar, 100 μm. E, TeNT expression did not elicit astrogliosis. F, G, Electron micrographs from control (F) and TeNT-overexpressing (G) axons. TeNT expression results in axonal swelling and vesicle accumulation (b, axonal bouton; s, dendritic spine; arrowheads, synapses). Scale bar, 500 nm. H, fEPSP recordings from the MML while electrically stimulating the MPP fibers. I, fEPSP responses were significantly attenuated when TeNT was expressed in the MML, without changing fiber volley amplitudes.
To selectively silence MPP inputs in vivo, we injected an AAV9-TeNT-mCherry virus into the medial entorhinal cortex (Fig. 3C), resulting in robust laminar-specific expression of TeNT in MPP axons (Fig. 3C,D). TeNT expression was accompanied by a lamina-specific decrease in VGluT1 immunostaining (n = 3 animals), a marker of functional presynaptic terminals (Fig. 3D). Importantly, TeNT expression followed ≤6 weeks in vivo did not elicit an inflammatory response (n = 3 animals; Fig. 3E), unlike the glial scarring that occurs following axotomy of MPP axons with subsequent degeneration of terminal axons (Perederiy et al., 2013). Immunogold electron micrographs of TeNT-expressing axon terminals showed pronounced swelling as well as increased accumulation of small clear vesicles in presynaptic boutons, consistent with complete block of vesicular release (Fig. 3F,G). TeNT-expressing axon terminals were directly apposed to dendritic spines, further suggesting that TeNT expression did not elicit axon degeneration.
To examine the efficiency of silencing of the MML, we recorded fEPSP responses to laminar-specific MPP electrical stimulation in control and TeNT-expressing slices. Consistent with our in vitro results, TeNT markedly reduced the maximal fEPSP slope (control: 0.67 ± 0.07 μV/ms, n = 6 slices; TeNT: 0.26 ± 0.02 μV/ms, n = 5 slices; Student's unpaired t test: t(9) = 5.4, p = 0.0004; Fig. 3H), as well as the input–output relationship between fiber volley amplitude and fEPSP slope (control: 0.52 ± 0.003; TeNT: 0.24 ± 0.01; extra-sum-of-squares F test: F(1,105) = 30.4, p < 0.0001; Fig. 3I). Importantly, there was no difference in the fiber volley amplitude with maximal stimulation (control: −231.7 ± 36.5 μV, n = 5 slices; TeNT: −197 ± 29.8 μV, n = 5 slices; Student's unpaired t test: t(8) = 0.74, p = 0.48), indicating that equal numbers of axons were stimulated in both conditions. The small residual fEPSP response observed in slices likely indicates that a few medial entorhinal cortex neurons had not been infected with TeNT.
Silencing the MML impairs synapse formation with perforant path inputs
Although our results demonstrate that the MPP provides only weak functional input onto newly integrated granule cells, dendritic spines as well as weak synaptic responses (Kumamoto et al., 2012) are present, and thus these inputs could have an activity-dependent effect on circuit formation. To examine this possibility, we expressed ChR2-eGFP in LPP axons in conjunction with TeNT-mCherry expression in the MPP (MPP:TeNT; Fig. 4A). Interestingly, expression of TeNT in the MPP markedly reduced the amplitude of LPP responses in newly integrated granule cells (control: 72.2 ± 15.2 pA, n = 18 cells; MPP:TeNT: 8.7 ± 3.7 pA, n = 8 cells; Student's unpaired t test: t(24) = 2.7, p = 0.011; Fig. 4B,C), but not in mature granule cells (control: 105.9 ± 31.3 pA, n = 16 cells; MPP:TeNT: 125.7 ± 23.24 pA, n = 23 cells; Student's unpaired t test: t(37): 0.52, p = 0.6; Fig. 4B,C). There was an associated increase in the paired pulse ratio (PPR) of LPP axons targeting newly integrated granule cells (control PPR: 0.9 ± 0.08, n = 18 cells, MPP:TeNT PPR: 1.8 ± 0.3, n = 8 cells; Student's unpaired t test: t(24) = 4.3, p = 0.0003; Fig. 4B,D), which was not observed in mature granule cells (control PPR: 1.1 ± 0.07, n = 16 cells; MPP:TeNT PPR: 1.4 ± 0.2, n = 23 cells, Student's unpaired t test: t(37) = 1.38, p = 0.17; Fig. 4B,D). The increased PPR following MPP:TeNT suggests that presynaptic mechanisms may contribute to the reduced amplitude.
Silencing the MML impairs normal synaptic innervation in the OML. A, Expression of ChR2 in the OML, with TeNT expression in the MML (MML:TeNT). Scale bar, 100 μm. B, Comparison of synaptic responses in mature neurons (top) and newborn neurons (bottom) in control and MML:TeNT conditions. C, TeNT expression in the MML significantly reduces the amplitude of OML-evoked responses selectively in newborn cells. D, MML:TeNT expression increases the PPR of OML axons selectively in newborn cells. E, Retroviral labeling of newborn dentate granule cells in control (left) and with MML:TeNT (right). Scale bar, 35 μm. F, G, Spine density in newly integrated neurons is significantly reduced in both MML and OML following MML:TeNT expression. Scale bar: F, 2.5 μm. **p < .01.
Silencing of the MPP also greatly reduced the dendritic spine density of newly integrated granule cells in both the MML (control: 0.95 ± 0.04 spines/μm, n = 24 cells from 4 animals; MPP:TeNT: 0.51 ± 0.05 spines/μm, n = 24 cells from 4 animals; Student's unpaired t test: t(6) = 7.12, p = 0.0004; Fig. 4F,G) and OML (control: 0.93 ± 0.03 spines/μm, n = 24 cells from 4 animals; MPP:TeNT: 0.54 ± 0.02 spines/μm, n = 24 cells from 4 animals; Student's unpaired t test: t(6) = 11.01, p < 0.0001; Fig. 4F,G). Together these results suggest that although the axons of the MPP make only a weak contribution to the synaptic activation of adult-born granule cells, intact synaptic release from MPP axons is required for proper synaptic integration and maturation.
Discussion
There is a general consensus that newborn neurons, once integrated into the dentate gyrus network, have a unique role in memory formation (Aimone et al., 2006; Saxe et al., 2006; Kee et al., 2007). Newborn neurons undergo stereotyped maturation, including early GABAergic depolarization without excitatory perforant input for several weeks (Ge et al., 2006) as their dendrites extend through the molecular layer (Zhao et al., 2006). Previous results have suggested that enhanced excitability and synaptic plasticity explain why such a minor population can have a major impact on circuit function (Schmidt-Hieber et al., 2004; Aimone et al., 2011). However, monosynaptic labeling studies using modified rabies virus (Vivar et al., 2012) suggest that newborn neurons in fact receive preferential functional input from the lateral entorhinal cortex, and only weak input from the medial entorhinal cortex.
Preferential functional input onto newly integrated granule cells
We observed striking differences in laminar-specific perforant path input to newly integrated granule cells. However, several studies have suggested that electrical stimulation of the MPP elicits EPSCs in newborn granule cells (Wang et al., 2000; Schmidt-Hieber et al., 2004; Ge et al., 2006, 2007; Mongiat et al., 2009). Although some studies have suggested that adult-born granule cells receive innervation from the MPP and LPP (Kumamoto et al., 2012), these studies used electrical stimulation of the molecular layer, which does not ensure laminar-specific stimulation. Also, the endpoint in these studies was the percentage of adult-born neurons contacted rather than the synaptic strength, which was assessed in our experiments. Furthermore, most of these experiments used indirect methods to determine the age of the granule cell (e.g., input resistance and soma location). Yet, the rapid changes in newly integrated granule cells after mitosis puts a premium on accurate determination of their age. In our experiments, we explicitly defined cell age with retroviral labeling and verified laminar-specific stimulation with channelrhodopsin. This approach provided an unambiguous comparison of the strength of inputs from the medial and lateral entorhinal cortex in newly integrated granule cells. Although Deller et al. (1996) reported that inputs from the medial and lateral entorhinal cortex may not be perfectly anatomically separable, ChR2 labeling in our experiments was precisely laminar-specific.
Of note, episodic memory requires both spatial and nonspatial information, which are differentially encoded in the medial and lateral entorhinal cortex, respectively (Ferbinteanu et al., 1999; Hafting et al., 2005; Hargreaves et al., 2005; Yasuda and Mayford, 2006; Hunsaker et al., 2007; Deshmukh and Knierim, 2011; Yoganarasimha et al., 2011; Tsao et al., 2013; Van Cauter et al., 2013). Thus, the strict laminar organization in the molecular layer provides a framework in which distinct populations of granule cells or different regions of the dendritic tree may differentially affect circuit function (Magee, 2000; Dieni et al., 2013, 2016). The combination of preferential functional targeting of lateral entorhinal cortex inputs onto newly integrated granule cells thus complements their well-documented enhanced plasticity (Schmidt-Hieber et al., 2004; Abrous et al., 2005; Ge et al., 2007) in mediating distinct aspects of memory formation (Clelland et al., 2009; Sahay et al., 2011; Nakashiba et al., 2012; Tronel et al., 2012). This connectivity fits with a role of newly integrated neurons as novelty detectors for incoming contextual information, the essence of pattern separation (Deng et al., 2010; Aimone et al., 2011). Although the specific information carried by the LPP and MPP is likely more complex than a simple segregation of spatial and contextual input (Knierim et al., 2014), the lamination of the molecular layer suggests that the two inputs remain segregated along granule cell dendrites. One limitation of our results is that the data were obtained from the dorsal and intermediate regions of the hippocampus, which have similar connectivity. Thus, we cannot exclude the possibility that these results may be different in the most temporal tip of the hippocampus (“ventral”), which is known to have different connectivity (Strange et al., 2014).
At the synaptic level, the preferential functional input could not be attributed to an increase in “silent synapses” (Isaac et al., 1995; Carroll and Malenka, 2000; Ziv and Garner, 2001; Feldman, 2009), as there was no difference in the AMPA/NMDA ratio between MPP and LPP inputs. Newborn granule cells in our experiments had robust AMPA-receptor-mediated EPSCs, despite reports that the first glutamatergic synapses on newborn granule cells are NMDA-only, silent synapses from hilar mossy cells onto the inner molecular layer (Chancey et al., 2013, 2014; Li et al., 2017). As NMDA receptors can detect low concentrations of glutamate, it may be difficult to separate NMDA-only silent synapses from spillover from nearby release sites. Perhaps surprisingly, the presence of the same density of spines in the OML and MML indicates that spine density and morphology are dissociated from functional synaptic strength in newly integrated granule cells. This difference also could not be attributed to differences in dendritic lengths within the MML and OML based on total dendritic length measurements of labeled granule cells (C. Chatzi and G.L. Westbrook, unpublished data). Although presynaptic axon terminals generally colocalize with postsynaptic spines, spine formation can be temporally distinct from functional synapse formation (Yuste and Bonhoeffer, 2004). In fact, following lesions of the perforant path, newly integrated granule cells continue to form dendritic spines despite the loss of presynaptic axon terminals (Perederiy et al., 2013; Sando et al., 2017). Other recent studies also suggest that dendritic spines can form in the absence of presynaptic terminals or glutamate release (Lu et al., 2013; Sando et al., 2017). Perhaps most important to our results, excitatory synapses may initially form on dendritic shafts particularly in relatively immature neurons (Crain et al., 1973; Miller and Peters, 1981; Mates and Lund, 1983; Yuste and Bonhoeffer, 2004; Fortin et al., 2014), which may explain why mEPSC frequency did not increase between 3 and 6 weeks after mitosis in our experiments, although evoked responses can increase over this time period (Ge et al., 2007; Marín-Burgin et al., 2012; Dieni et al., 2013, 2016). Unfortunately, there are as yet no straightforward methods to detect shaft synapses on newly integrated granule cells in intact tissue.
The role of the MPP
Our results indicate MPP inputs are necessary for normal synapse formation of all perforant path inputs on newly integrated granule cells. Adult-born granule cells in the hippocampus share many properties with immature neurons during development (Schmidt-Hieber et al., 2004; Abrous et al., 2005; Ge et al., 2007), but are unique because they integrate into a pre-existing circuit (Ge et al., 2007; Toni et al., 2007; Adlaf et al., 2017). The preferential functional targeting by the lateral entorhinal cortex might seem surprising given that as newborn cells mature, their dendrites first pass through the MML, which is occupied by axons innervating mature granule cells. On the other hand, this is the first perforant path glutamatergic input in these cells. Thus, even quite small events may provide a necessary signal for the subsequent development of spines and functional synapses in the OML. Chronic silencing of MPP inputs did not affect the lamination of incoming axons, but selectively reduced inputs onto newly integrated neurons. Silencing the MPP reduced spine density in both the MML and OML, although the reduction in synaptic strength was greater than the reduction in spine density, contrasting with patterns of homeostatic plasticity in other circuits (Davis, 2013). Furthermore, perforant path stimulation can elicit depolarizing GABAergic responses (Overstreet Wadiche et al., 2005; Ewell and Jones, 2010; Armstrong et al., 2011), which early in cell development can provide important trophic support (Ge et al., 2006; Chancey et al., 2013, 2014). Given the weak nature of this input, it may be that neurotrophic factors other than net neural activity contribute to the developmental role of MPP inputs (Huang and Reichardt, 2001; Cohen-Cory et al., 2010).
Comparison to synapse formation during early development
The existence of activity-dependent and competition-dependent synapse remodeling is well mapped in the immature brain as neural circuits develop (Goodman and Shatz, 1993; Katz and Shatz, 1996; Walsh and Lichtman, 2003). In many developing circuits, an overabundance of weak synapses is later pruned in a competition-dependent manner, resulting in the retention of strong synaptic inputs (Bear, 1995; Knudsen, 2004; Majewska and Sur, 2006; Bhatt et al., 2009; Feldman, 2009), thereby shaping the mature, functional circuit (LeVay et al., 1980; Walsh and Lichtman, 2003; Datwani et al., 2009). Synapse pruning and redistribution occur during critical periods of development, when incoming patterns of activity strongly influence circuit remodeling (Malenka and Bear, 2004; Holtmaat and Svoboda, 2009; Caroni et al., 2014). However, in the adult brain, such circuit plasticity is more limited (Tagawa et al., 2005; Sato and Stryker, 2008), suggesting that the pattern of initial synapse formation and subsequent remodeling/refinement in adult-born cells may be distinct. Indeed, we did not see a distinct period of synaptic overabundance as newly integrated cells reached maturity. Rather synaptic “competition” for newly integrating neurons must reflect a homeostatic rebalancing of functional inputs across the molecular layer, which must occur over a relatively narrow time window, as newborn granule cells are functionally indistinguishable from mature granule cells by 8 weeks after mitosis (van Praag et al., 2002; Ambrogini et al., 2004; Overstreet et al., 2004; Laplagne et al., 2006; Overstreet-Wadiche et al., 2006; Zhao et al., 2006; Brunner et al., 2014). Such competition need not only occur between synapses on the same cell and can occur between mature and newly integrated neurons (Toni et al., 2007; McAvoy et al., 2016; Adlaf et al., 2017). Importantly, remodeling in the adult environment is relevant to both neurogenic niches and repair after neural injury (Lindvall and Kokaia, 2006; Lepousez et al., 2015).
Footnotes
This work was supported by National Institutes of Health Grants R01 NS080979 and P30 NS061800 and by the Ellison Medical Foundation (G.L.W.). We thank Stefanie Kaech Petrie for help with imaging, Eric Schnell for guidance with electrophysiology, and Sue Aicher for assistance with electron microscopy.
The authors declare no competing financial interests.
- Correspondence should be addressed to Gary L. Westbrook, Vollum Institute, L474, Oregon Health and Science University, 3181 SW Sam Jackson Park Road, Portland OR, 97008. westbroo{at}ohsu.edu