Abstract
A subset of preBötzinger Complex (preBötC) neurokinin 1 receptor (NK1R) and somatostatin peptide (SST)-expressing neurons are necessary for breathing in adult rats, in vivo. Their developmental origins and relationship to other preBötC glutamatergic neurons are unknown. Here we show, in mice, that the “core” of preBötC SST+/NK1R+/SST 2a receptor+ (SST2aR) neurons, are derived from Dbx1-expressing progenitors. We also show that Dbx1-derived neurons heterogeneously coexpress NK1R and SST2aR within and beyond the borders of preBötC. More striking, we find that nearly all non-catecholaminergic glutamatergic neurons of the ventrolateral medulla (VLM) are also Dbx1 derived. PreBötC SST+ neurons are born between E9.5 and E11.5 in the same proportion as non-SST-expressing neurons. Additionally, preBötC Dbx1 neurons are respiratory modulated and show an early inspiratory phase of firing in rhythmically active slice preparations. Loss of Dbx1 eliminates all glutamatergic neurons from the respiratory VLM including preBötC NK1R+/SST+ neurons. Dbx1 mutant mice do not express any spontaneous respiratory behaviors in vivo. Moreover, they do not generate rhythmic inspiratory activity in isolated en bloc preparations even after acidic or serotonergic stimulation. These data indicate that preBötC core neurons represent a subset of a larger, more heterogeneous population of VLM Dbx1-derived neurons. These data indicate that Dbx1-derived neurons are essential for the expression and, we hypothesize, are responsible for the generation of respiratory behavior both in vitro and in vivo.
Introduction
The necessity for the brainstem in the generation of breathing has been known for over a millennium, and the search for the regions most important for this behavior has been ongoing for nearly 200 years (Legallois, 1813; Feldman and Del Negro, 2006). A small region of the ventrolateral medulla (VLM), the preBötC, is hypothesized to be the site for respiratory rhythm generation (Smith et al., 1991). In the adult rat, a subset of glutamatergic neurons within this region coexpress the neurokinin 1 receptor (NK1R) and somatostatin (SST) peptide (Gray et al., 1999; Stornetta et al., 2003; Llona and Eugenín, 2005). The near-complete, targeted ablation of preBötC NK1R neurons over several days produces ataxic breathing during wakefulness, while the partial elimination of this population produces sleep-disordered breathing (Gray et al., 2001; McKay et al., 2005). The genetic silencing of preBötC neurons by expression of a Drosophila peptide receptor under the control of a fragment of the SST promoter induces persistent apnea (Tan et al., 2008). Together these data indicate an important role for a subset of preBötC neurons in breathing. What role glutamatergic neurons lacking SST or NK1R expression within the preBötC, as well as within the adjacent Bötzinger Complex (BötC) and rostral ventral respiratory group (rVRG), have in the generation of respiratory behavior is unknown (Feldman and Del Negro, 2006).
Transcription factor mutations that affect rhombomeric patterning and interneuron specification lead to respiratory instability and death, suggesting a strong genetic component to the formation of the respiratory central pattern generator (Blanchi et al., 2003; Rhee et al., 2004; Gray, 2008; Pagliardini et al., 2008; Rose et al., 2009; Thoby-Brisson et al., 2009; Caubit et al., 2010). No direct relationship, however, has been identified for any specific transcription factor and the formation of preBötC glutamatergic neurons. In contrast, within the VLM, discrete transcription factors give rise to respiratory glycinergic neurons (Lbx1), as well as retrotrapezoid nucleus and parafacial respiratory group (RTN/pFRG) glutamatergic neurons (Atoh1, Lbx1, Phox2b) (Pagliardini et al., 2008; Rose et al., 2009; Thoby-Brisson et al., 2009). Here we examined the role of the transcription factor Dbx1 in the genetic organization of the mammalian respiratory oscillator including preBötC neurons. Understanding the developmental and genetic organization of the neurons necessary for breathing may provide insight into the general principles of neural circuit formation as well as human breathing disorders.
Materials and Methods
Transgenic mice.
We used Dbx1LacZ (Pierani et al., 2001), Dbx1CreERT2 (Hirata et al., 2009), Gad1GFP transgenic (Chattopadhyaya et al., 2004), Lmx1bLacZ (Pressman et al., 2000), Rosa26-EYFP (Srinivas et al., 2001), Slc6a5 BAC transgenic (Gong et al., 2003), or wild-type mice. All mice were bred onto a mixed CD1/C56B6 or CF1 background. Experiments were done in accordance with the Institute for Laboratory Animal Research Guide for the Care and Use of Laboratory Animals. All experiments were approved by the Animal Studies Committee at Washington University School of Medicine, the Institutional Animal Care and Use Committee at the College of William and Mary, or the Bioethics Committee of the Universidad de Santiago de Chile.
Immunohistochemistry.
Tissue sections were washed in PBS with 0.2% Triton X-100, blocked in 10% heat-inactivated normal horse sera, incubated in antibody overnight at 4°C, incubated in secondary antibody, and coverslipped in Vectashield.
Antibodies.
Rat anti-bHLHb5 (1:1000, M. E. Greenberg, Harvard Medical School, Boston, MA), chicken anti-β-galactosidase (β-gal) (1:4000, Abcam), rabbit anti-β-gal (1:1000, Covance), goat anti-FoxP2 (1:2000, Abcam), chicken anti-green fluorescent protein (GFP) (1:1000, Aves Labs), rabbit anti-GFP (1:2000, Invitrogen), goat anti-Lhx9 [1:1000, Santa Cruz Biotechnology (SCBT)], guinea pig anti-Lmx1b (1:500, T. Jessell, Howard Hughes Medical Institute, Columbia University, New York, NY), rabbit anti-NK1R (1:2000, Advanced Targeting Systems and Millipore), rabbit anti-Pax2 (1:250, Invitrogen), goat anti-Pax2/5/8 (1:100, SCBT), goat anti-Phox2b (1:500, SCBT), rabbit anti-Phox2b (1:20,000, C. Gordis, École Normale Supérieure, Paris, France), goat anti-SST (1:600, SCBT), rabbit anti-SST (1:500, SCBT), guinea pig anti-somatostatin 2a receptor (SST2aR) (1:8000, Gramsch Labs), sheep anti-tyrosine hydroxylase/tryptophan hydroxylase (1:1000, Millipore). Secondary antibodies were species specific and conjugated to AMCA, FITC, Alexa 488, DyLight 488, Cy3, C5, or DyLight 649 (Invitrogen or Jackson ImmunoResearch).
In situ hybridization.
Slides were immersed in 4% PFA, permeabilized with proteinase K, washed in 0.1 m triethanolamine-HCl with 0.25% acetic anhydride, blocked in hybridization buffer at 65°C, then placed into slide mailers containing hybridization buffer with DIG-labeled antisense RNA at 1 μg/ml overnight at 65°C. Slides were washed in SSC buffers at 62°C, then washed and incubated in alkaline phosphatase-conjugated anti-DIG antibody in 10% NHS and incubated in NBT-BCIP until cellular labeling is clear. For combined immunohistochemistry and in situ hybridization (ISH), slides are stained for mRNA expression before immunohistochemical labeling.
Genotyping.
Mice were genotyped by PCR using primers specific for β-gal, GFP/YFP, Neomycin phosphotransferase, Cre recombinase, Atoh1, Dbx1, and Lmx1b as described previously (Pressman et al., 2000; Pierani et al., 2001; Rose et al., 2009), or by direct visualization of fluorescent reporter, β-gal reaction product, or anatomical defect.
Tissue acquisition.
Neonatal pups (P0–P4) or embryos from timed pregnant females (morning of plug = E0.5, E10.5–E18.5) were anesthetized and either perfused (≥E16.5) or immersion fixed in 4% paraformaldehyde in 0.1 m PBS, pH 7.4. Embryos or isolated brainstems were postfixed in PFA overnight at 4°C, cryoprotected in 25% sucrose in PBS, blocked, frozen in OCT, and stored at −75°C. Brainstems were sectioned in sets of six on a Hacker cryostat at 20 μm, and sections were thaw mounted onto Superfrost Plus slides and stored at −20°C until use.
Immunohistochemical and in situ hybridization image acquisition.
Fluorescent and bright-field images were acquired using a Nikon 90i microscope (Nikon Instruments), Roper H2 cooled CCD camera (Photometrics), and Optigrid Structured Illumination Confocal with a Prior (Rockland) motorized translation stage. Pseudocolored images were acquired in Velocity (PerkinElmer), modified in Photoshop (Adobe) or ImageJ (National Institutes of Health), and exported as 8 bit JPEG images. Images were filtered and levels were modified for clarity.
Video recording.
Video images were acquired using a Nikon D90 camera with 105 mm Nikkor Macro lens (Nikon Instruments). Video was processed in IMovie HD (Apple Computer) and individual frames were exported to Photoshop for analysis.
BrdU and tamoxifen labeling.
5-Bromo-2-deoxyuridine (BrdU) (50 mg/kg, Roche) was injected intraperitoneally into timed pregnant mice with sterile saline (20 mg/ml) as previously described (Pagliardini et al., 2003). Tamoxifen (1–2 mg, 10 mg/ml in vegetable oil) was given by oral gavage in timed pregnant mice as previously described (Hirata et al., 2009).
Cell counting.
Cells or nuclei larger than 5 μm in diameter were counted from the caudal end of the VII motor nucleus (VIIn) to the caudal pole of the lateral reticular nucleus (LRN) by visual inspection of confocal images acquired at 10–20× within either a 500 μm circle encompassing the majority of the VLM, or a 350 μm circle ventral to the nucleus ambiguus. Levels of digital images were enhanced to maximize low-level expression. The first section within a set containing the VIIn was set as 0 μm. Colocalization of β-Gal and mRNA required at least half of the nucleus to be surrounded.
En bloc recordings (quantal slowing).
P0 to P2 CF1 mice were anesthetized by cooling and ether (Merck) and immersed in cooled (4°C) artificial CSF (aCSF) containing the following (in mm): 125 NaCl, 5 KCl, 24–28 NaHCO3, 1.25 KH2PO4, 30 d-glucose, 0.8 CaCl2, and 1.25 MgSO4 (Sigma). The medium was equilibrated with carbogen: 95% O2/5% CO2, pH 7.40. The CNS was removed, decerebrated through a pontomesencephalic transection, and transferred to a 2 ml recording chamber. Newborn animals in each experimental group came from at least 3–4 litters. No pontobulbar transection was performed.
Spontaneous activity from C3–C5 ventral roots was recorded with glass suction electrodes (24–25°C). Electrical signals were amplified by a low-noise differential amplifier (Grass Instruments), processed with a full-wave rectifier and leaky integrator (time constant = 100 ms), displayed on a monitor, and recorded via Digidata 1320 AD acquisition system (Molecular Devices). Analyses were performed in Axoscope software (Molecular Devices).
Somatostatin was added to the aCSF for a final concentration between 10−10 and 10−14 m. In six preparations, SST doses were 10−12 m with slight visualization of quantal slowing. Quantal slowing was observed in four of six preparations using SST doses between 10−13 m and 10−14 m.
En bloc recordings (Dbx1 mutant mice).
E18.5 Dbx1LacZ/+ and Dbx1LacZ/LacZ were removed by cesarean section from anesthetized timed-pregnant animals. Brainstem–spinal cord preparations extending from the pontomedullary junction to sacral region of the spinal cord were isolated by craniotomy and laminectomy from pups, deeply anesthetized by cooling, and immersed in cold (4°C) aCSF, pH 7.4, containing the following (in mm): 124.0 NaCl, 5.0 KCl, 2.4 CaCl2, 1.3 MgSO4, 26.0 NaHCO3, 1.2 KH2PO4, and 30 glucose equilibrated with 95% O2 and 5% CO2 to pH 7.4. These preparations were incubated at 25–26°C for up to 2–3 h under constant aeration and transferred to a 6 ml recording chamber.
Simultaneous spontaneous activity from cervical C2–C5 ventral roots was recorded with glass suction electrodes. Electrical signals were amplified by a low-noise differential amplifier (Grass Instruments). The signals were digitally acquired using an analog-to-digital converter (ADInstruments). LabChart 7 Pro (v7.1.2, ADInstruments) software was used for signal processing.
Serotonin (5 μm) and SST (10−13 m) were added to aCSF and bath applied to the entire preparation. Low pH (7.0) aCSF contained the following (in mm): 140.0 NaCl, 5.0 KCl, 2.4 CaCl2, 1.3 MgSO4, 10.0 NaHCO3, 1.2 KH2PO4, and 30 glucose equilibrated with 95% O2 and 5% CO2.
Slice recordings.
Transverse slices (550 μm thick) from neonatal (P0–P6) Dbx1LacZ and Dbx1CreERT2;R26REYFP mice were dissected and prepared for recordings as described previously (Hayes and Del Negro, 2007). On-cell and whole-cell patch recordings were obtained using infrared-enhanced differential interference contrast (IR-DIC) videomicroscopy after fluorescent identification of Dbx1+ neurons in both mouse models. Slices from Dbx1LacZ/+ mice were incubated with fluorescein-di-β-d-galactopyranoside (FDG). Cleavage of this nonfluorescent sugar moiety in β-gal-expressing cells releases fluorescein. Slices from Dbx1CreERT2;R26REYFP showed robust reporter expression in the preBötC when tamoxifen was administered on E10.5. aCSF contained the following (in mm): 124 NaCl, 9 KCl, 0.5 NaH2PO4, 25 NaHCO3, 30 d-glucose, 1.5 CaCl2·2H2O, and 1 MgSO4. Slices were placed into a 0.5 ml chamber within an upright fixed-stage microscope (Zeiss Microimaging), and aCSF was perfused at ∼5 ml/min at 27–28°C.
Patch recordings used a HEKA EPC-10 patch-clamp amplifier and Patchmaster software. Respiratory-related motor output was monitored from XII nerves with extracellular suction electrodes and a high-gain differential amplifier with bandpass filtering (0.3–1 kHz) (Dagan Instruments), full-wave rectified, and smoothed for display. Data were acquired using Chart 5 software and a Powerlab 4/30 (ADInstruments). An 8 mV liquid junction potential was corrected online in both current and voltage clamp.
We used a patch solution containing the following (in mm): 140 K-gluconate, 5 NaCl, 0.1 EGTA, 10 HEPES, 2 Mg-ATP, and 0.3 Na3-GTP (pH = 7.2 using KOH). We added 2–4 μl/ml of Alexa Fluor 568 hydrazide (Na+ salt, Invitrogen) to the patch solution for fluorescent visualization of morphology.
Neurons were visually identified using both IR-DIC videomicroscopy and epifluorescence illumination (X-Cite 120, EXFO) and a GFP filter to identify fluorescein- and EYFP-labeled cells. Images were acquired of recorded Dbx1 neurons. In most cases, a MaiTai Ti:sapphire ultra-fast pulsed laser (Spectra Physics) tuned to 800 nm was used for two-photon FDG imaging and transmitted light images (i.e., Fig. 5), and a 543 nm HeNe laser was used for confocal imaging of Alexa 568. Images were contrast enhanced and pseudocolored, and a 0.5-μm-radius Gaussian blur was applied using ImageJ software.
Statistics.
All the Dbx1-derived neuron recordings were used to compute mean and SEM for burst amplitude, burst area, half-width (i.e., duration at 50% burst amplitude), and the preinspiratory burst latency. The latency was determined from the point of first depolarization and/or summating EPSPs above baseline to the maximum slope onset of the drive output from XII, which marks the inspiratory burst per se. Data from Dbx1LacZ/+ and Dbx1CreERT2;R26REYFP animals were similar, so the samples (n = 8 and n = 5, respectively) were pooled. Cell counts were compared using a two-tailed, unequal-samples Student's t test in Numbers (Apple Computer).
Results
To identify transcription factors that might define subpopulations of preBötC neurons, we analyzed the expression, by ISH, of >75% (∼1000) of all transcription factors (TFs) in E13.5 and P0 mouse brain (Gray et al., 2004). While no single TF was specific to the preBötC, we identified three candidate TFs that were expressed by subsets of VLM neurons: Lhx9, Pax2, and Phox2b. Using immunohistochemistry (IHC), we analyzed Lhx9, Pax2, and Phox2b coexpression with NK1R or SST throughout the VLM. In the neonate mouse, NK1R expression is continuous from the caudal pole of the LRN extending beyond the VIIn, including the neurons of the pFRG and the RTN (Gray et al., 1999; Stornetta et al., 2006; Rose et al., 2009; Thoby-Brisson et al., 2009). Thus NK1R expression alone does not identify the boundaries of the preBötC in neonatal mice. SST protein or preprosomatostatin mRNA (data not shown) were limited to the preBötC, similar to rat (Stornetta et al., 2003). SST largely colocalizes with NK1R (87.3%, 144/165, n = 4), which suggests that it can serve as an anatomical marker of the “core” of the preBötC in mice (Fig. 1B,C–E) (Stornetta et al., 2003; Tan et al., 2008). We found that a subset of Pax2-expressing neurons coexpress SST within the preBötC (Fig. 1A). Lhx9 and Phox2b were both expressed throughout the VLM (Gray, 2008); however, they were coexpressed with NK1R only outside the preBötC (supplemental Fig. 1, available at www.jneurosci.org as supplemental material), and neither was coexpressed with SST. Pax2 did not overlap with Phox2b or Lhx9 anywhere in the medulla.
PreBötC neurons are derived from Dbx1-expressing progenitors
Adult rat preBötC SST+ neurons are glutamatergic and commissural (Guyenet and Wang, 2001; Stornetta et al., 2003). In the spinal cord, only Dbx1-derived neurons express Pax2, are glutamatergic, and project across the midline (Lanuza et al., 2004). This suggested that preBötC SST neurons might be derived from Dbx1-expressing progenitors (Lanuza et al., 2004). Dbx1 is only expressed in progenitor cells, whereas NK1R and SST expression in preBötC does not commence until E14.5–E15.5, so we could not directly analyze Dbx1 coexpression with these markers (Pagliardini et al., 2003; Thoby-Brisson et al., 2005).
In heterozygous Dbx1-β-gal knock-in mice (Dbx1LacZ/+) (Pierani et al., 2001), in which the persistence of the β-Gal protein can be used to fate map neurons, we found that the preBötC core population of NK1R+/SST+ neurons are derived from a subset of Dbx1-expressing progenitors (Fig. 1B–H). β-Gal was absent, however, from VLM NK1R+ motoneurons, below the central ventrolateral medulla, and putative RTN/pFRG neurons (supplemental Fig. 2, available at www.jneurosci.org as supplemental material) (Nattie and Li, 2002, 2006; Wang et al., 2003; Takakura et al., 2008; Rose et al., 2009).
As NK1R expression is present on neurons from multiple developmental origins, we determined the extent to which VLM SST neurons are Dbx1 derived. We counted β-Gal, SST, and colocalized immunoreactive neurons in a 500-μm-diameter circle encompassing the VLM from the caudal pole of the VIIn to the caudal pole of the LRN. While SST immunoreactivity likely underestimates the number of neurons expressing SST mRNA (Stornetta et al., 2003), it can serve as simple and reproducible marker of neurons. Interestingly, the number of β-Gal+ cells was approximately constant throughout the VLM. SST expression, in contrast, was limited rostrocaudally to an ∼250-μm-long region (Fig. 1I,J). Of VLM SST neurons, 92.7% coexpressed β-Gal (433/467, n = 16). Further, SST+ neurons are concentrated in the center of the Dbx1+ population dorsoventrally, as 82.4% (385/467, n = 16) of them are located within a 350-μm-diameter circle centered on SST expression. This 250 μm by 350 μm column represents the anatomical extent of the preBötC core in the perinatal mouse (Ruangkittisakul et al., 2006).
Differential peptide receptor expression has been proposed to distinguish between subsets of respiratory neurons (Gray et al., 1999; Doi and Ramirez, 2008, 2010; Ruangkittisakul et al., 2008; Ballanyi et al., 2009). In rats, injection of somatostatin at high doses into the preBötC inhibits respiration (Burke et al., 2010). Because of the inhibitory effects of SST in vivo and in vitro, SST coexpression in preBötC neurons, and previously published expression patterns, we also analyzed SST2aR expression within the preBötC and ventral medulla (Schindler et al., 1998; Schulz et al., 2000; Llona and Eugenín, 2005; Burke et al., 2010). SST2aR is expressed throughout the VLM (Schindler et al., 1998). Within the preBötC, SST2aR is coexpressed with SST peptide and NK1R in Dbx1-derived neurons (Fig. 1B). Unlike NK1R, however, SST2aR is also expressed on catecholaminergic neurons (data not shown) but is not expressed on RTN/pFRG neurons (supplemental Fig. 1C,D, available at www.jneurosci.org as supplemental material). These data suggest that SST2aR, similar to μ-opioid receptor, may serve to functionally and anatomically differentiate preBötC from RTN/pFRG neurons (Takeda et al., 2001; Mellen et al., 2003).
Within the preBötC core of Dbx1LacZ/+ mice, β-Gal, SST peptide, NK1R, and SST2aR partially colocalize (Fig. 1B–H); 86.6% (129/149, n = 4) of β-Gal+SST+ neurons coexpress NK1R (Fig. 1C–E). Unlike SST+ neurons, Dbx1-derived NK1R or SST2aR-expressing neurons are not limited to the preBötC core. Outside this region, there is extensive heterogeneity of receptor expression in the Dbx1-derived population (supplemental Fig. 2, available at www.jneurosci.org as supplemental material). For example, within the BötC, there is little β-Gal/SST2aR coexpression, but clear β-Gal/NK1R coexpression extending up to the VIIn boundary (Fig. 1H; supplemental Fig. 2B,C, available at www.jneurosci.org as supplemental material). Even within the preBötC core, only 17.0% (149/875, n = 4) of β-Gal+ cells coexpressed SST, and 21.6% (474/2191, n = 8) coexpressed NK1R. In the VLM as a whole, SST represented only 4.9% of β-Gal-labeled cells (433/8748, n = 16). Moreover, at least 44.2% (3868/8748, n = 16) of VLM Dbx1-derived cells lie outside the preBötC core. This demonstrates that Dbx1-derived neurons comprise a larger percentage of putative respiratory neurons in the VLM, which includes, but is not limited to, the preBötC.
VLM Dbx1 neurons are glutamatergic
In other regions of the CNS, Dbx1 proliferative zones generate glutamatergic, GABAergic, and cholinergic neurons, as well as a subset of glia (Lanuza et al., 2004; Bielle et al., 2005; Fogarty et al., 2005; Zagoraiou et al., 2009). We used ISH and IHC to determine the cellular and transmitter identity of Dbx1 β-Gal+ cells in the VLM. At least 44.7% (1630/3645, n = 9) of VLM Dbx1 β-Gal+ cells coexpressed mRNA for VGlut2, a marker of glutamatergic neural identity (Fig. 2A), and 20.7% (533/2577, n = 5) of β-Gal+ cells coexpressed S100β protein, a marker of glial lineage (Fig. 2E). In contrast, very few VLM Dbx1 β-Gal cells were inhibitory, with only 2.8% (16/562, n = 3) coexpressing glutamic acid decarboxylase 1 mRNA (GAD1), a marker of GABAergic neurons (Fig. 2B), 4.8% (54/1118, n = 7) of β-Gal cells coexpressing vesicular glycine transporter (Slc6a5) mRNA, a marker of glycinergic neurons (Fig. 3C), and 2.4% (53/2146, n = 5) of β-Gal cells coexpressing choline acetyltransferase (ChAT) protein, a marker of cholinergic neurons (Fig. 2D). In general, the inhibitory Dbx1 β-Gal neurons were dorsomedial to the VLM (Fig. 2B,C). Adjacent to the XII motor nucleus, there was extensive overlap of β-Gal with GAD1 or VGlut2 mRNA, consistent with spinal cord expression (Lanuza et al., 2004). The remaining ∼25% of β-Gal cells likely include S100β-negative oligodendrocytes (Fogarty et al., 2005) and neurons with levels of transmitter marker mRNA below threshold for detection.
As combined ISH and IHC protocols limit sensitivity, we also analyzed the coexpression of Dbx1 β-gal in double transgenic mice in which GFP was driven with either a Slc6a5 or GAD1 promoter (Gong et al., 2003; Chattopadhyaya et al., 2004; Winter et al., 2007; Morgado-Valle et al., 2010; Winter et al., 2010). The expression patterns of GFP in both lines were consistent with both ISH and TF expression in the developing and perinatal mouse brainstem. Consistent with our ISH analysis, we found little overlap of β-gal with GFP in Dbx1LacZ/+;Slc6a5GFP mice (supplemental Fig. 3B, available at www.jneurosci.org as supplemental material), and overlap of β-gal with Dbx1LacZ/+;Gad1GFP near the midline (supplemental Fig. 3A, available at www.jneurosci.org as supplemental material). In the VLM, however, we found no overlap of β-gal, NK1R, or SST2aR with GFP in either transgenic line (Fig. 2B,C).
Glutamatergic neurotransmission is essential for respiratory rhythm generation both in vivo and in vitro (Wallén-Mackenzie et al., 2006). Many current models of the respiratory network hypothesize the preBötC contains two distinct subpopulations of glutamatergic neurons. A subset of specialized neurons that generate the rhythm, and a second population of “follower” neurons thought to play a role in shaping the pattern of motor output (Feldman and Smith, 1989; Feldman et al., 1990; Butera et al., 1999; Koshiya and Smith, 1999; Del Negro et al., 2001; Ramirez and Garcia, 2007; Smith et al., 2007). Dbx1-derived neurons, however, only account for a subset of VLM glutamatergic neurons (Fig. 2A). This suggests that non-Dbx1-derived neurons might play an important role in breathing. Previous work has shown that nonrespiratory VLM catecholaminergic neurons release glutamate, express VGlut2, and are derived from Lmx1b-expressing progenitors and would account for some of the remaining glutamatergic neurons (Qian et al., 2002; Stornetta et al., 2002; Gray, 2008). Similar to Dbx1 neurons, we analyzed the coexpression of VGlut2 in the VLM of Lmx1bLacZ/+ mutant mice (Pressman et al., 2000). The bulk of Lmx1b-derived catecholaminergic, glutamatergic neurons were concentrated ventral to the Dbx1-derived population, but like Dbx1 were found throughout the VLM (Fig. 2G). To better estimate the extent to which VLM glutamatergic neurons were derived from Dbx1 and Lmx1b precursors, we generated Dbx1LacZ/+;Lmx1bLacZ/+ double heterozygous mutant mice. We found that these two developmentally defined populations account for nearly all VLM glutamatergic neurons within the preBötC and adjacent catecholaminergic population (Fig. 2H) (n = 2). This suggests that the majority of VLM glutamatergic neurons concerned with breathing are derived from the single Dbx1 progenitor domain.
Developmental origin of VLM Dbx1 neurons
As only a spatially clustered subset of Dbx1-derived neurons coexpress SST, we wondered whether they represented a developmentally unique subpopulation. To test whether preBötC SST neurons were born at a different time than surrounding SST− neurons, we injected pregnant Dbx1LacZ/+ mice with a single dose of BrdU on E9.5, E10.5, or E11.5, to label dividing cells, and counted the number of β-Gal-, BrdU-, and SST-labeled cells in P0 animals (Fig. 3A–C,E). With injection at E9.5, 21% (474/2252, n = 4) of VLM β-Gal neurons coexpress BrdU, while 21.4% (40/187, n = 4) of VLM SST neurons coexpressed BrdU. With E10.5 injection, β-Gal/BrdU coexpression was 33% (1213/3678, n = 5) and SST/BrdU coexpression was 28.7% (47/164, n = 6). With E11.5 injection, β-Gal/BrdU coexpression was 17.4% (500/2878, n = 4) and SST/BrdU coexpression was 9% (33/367, n = 6). This latter difference is likely due to the onset of gliogenesis by E11.5 (Fogarty et al., 2005). These data suggest that preBötC SST-expressing neurons are born in the same proportion as non-SST-expressing neurons.
As the Dbx1LacZ mouse is a heterozygous mutation, it is possible that the timing of neural specification might be affected. To test this, we examined the coexpression of SST and NK1R in a Dbx1CreERT2 knock-in mouse with no loss of Dbx1 gene function (Hirata et al., 2009). Crossing this mouse with a Rosa26-EYFP (R26RYFP) (Srinivas et al., 2001) line, we find that application of tamoxifen at E9.5 labels the majority of preBötC NK1R+/SST+ neurons, which is consistent with our previous results (Fig. 3D) (n = 5). Together these data suggest that SST expression with the subset of Dbx1 neurons is not a consequence of time of birth.
While the basic dorsoventral development of the hindbrain resembles that in spinal cord (Gray, 2008), we sought to determine whether hindbrain Dbx1 neurons were derived from the V0 progenitor domain (Pierani et al., 2001; Lanuza et al., 2004). As expected, Dbx1-derived cells of the caudal hindbrain were limited to the V0 progenitor domain, as β-gal cells are bounded by bHLHb5 expression in the DB4 and V1 progenitor domains (Fig. 3F,G) (Liu et al., 2007; Gray, 2008). Consistent with previous reports, NK1R expression in the preBötC was first evident in a small population of cells near the nucleus ambiguus (NA) at E14.5 (Fig. 3H), and SST protein expression is first evident at E15.5 (data not shown) (Pagliardini et al., 2003; Thoby-Brisson et al., 2005). In the spinal cord, Evx1 defines a specific subpopulation of V0 interneurons. After E13.5 in the hindbrain, however, Evx1 mRNA and protein are no longer specific to the V0 lineage (data not shown), preventing our ability to determine V0 subtype-specific origin of preBötC neurons (Lanuza et al., 2004).
Somatostatin induces “quantal slowing” in en bloc preparations
Although the relationship between Dbx1-derived neurons of the VLM and respiratory behavior is unclear, the coexpression of SST and SST2aR within preBötC Dbx1-derived neurons, but not more rostral RTN/pFRG populations, suggests that SST might selectively modulate preBötC neurons in a manner similar to opioids in the rat brain (Gray et al., 1999; Mellen et al., 2003). Although other subclasses of SST receptors besides SST2aR have been identified in the brainstem, we predicted that if Dbx1-derived neurons are an essential part of the respiratory network, their partial inhibition by SST should produce “quantal slowing” of the in vitro respiratory period of isolated mouse en bloc preparations (Mellen et al., 2003; Janczewski and Feldman, 2006a,b).
When extremely low concentrations of SST were used (Buscail et al., 1994), the periods of fictive respiratory output clustered near integer multiples of the period before drug application. These data were similar to the effects of low concentrations of opioids in rat (Mellen et al., 2003). Figure 4 shows the effects of 10−13 m SST on fictive inspiratory motor output en bloc from a P0 mouse displayed as raw traces (A) and plotted on a cycle-to-cycle basis (B). A histogram of normalized periods from four different en bloc preparations (10−13 to 10−14 m SST) demonstrates the quantal nature of the SST modulation in four of six preparations tested (Fig. 4C). These data suggest that mouse RTN/pFRG neurons do not express functional SST receptors. They further suggest that Dbx1 neurons are functional components of the respiratory network and play a role in frequency modulation.
PreBötC Dbx1-derived neurons are respiratory
Dbx1 neurons in the preBötC are strong candidates for the neurons generating the inspiratory rhythm because of their location, expression of peptide receptors, and glutamatergic phenotype. Therefore, we examined the firing patterns of Dbx1-derived neurons in rhythmic brainstem slice preparations that spontaneously generate inspiratory motor output in vitro. Fluorescent Dbx1-derived neurons were selected for patch-clamp recording in Dbx1LacZ/+ (n = 8) and Dbx1CreERT2;R26REYFP (n = 8) mouse slices (Fig. 5A; supplemental Fig. 4A, available at www.jneurosci.org as supplemental material). Eighteen of the twenty neurons sampled showed rhythmic inspiratory burst activity in phase with the XII output (Fig. 5B; supplemental Fig. 4B–D, available at www.jneurosci.org as supplemental material). In addition, Dbx1 neurons were active in the preinspiratory phase 0.3–1 s before the XII burst (Fig. 5C). A preinspiratory active phase of duration 400 ± 100 ms has been proposed as a feature of putative respiratory rhythmogenic neurons (Rekling et al., 1996a; Thoby-Brisson and Ramirez, 2001). All 18 Dbx1+ neurons exhibited low-rate (2–10 Hz) spiking in current clamp (e.g., Fig. 5B; supplemental Fig. 4B,C, available at www.jneurosci.org as supplemental material). This preinspiratory activity was associated with the temporal summation of EPSCs in voltage clamp (supplemental Fig. 4D, available at www.jneurosci.org as supplemental material). The duration of the preinspiratory active phase in Dbx1 neurons measured 377 ± 114 ms (mean ± SEM) with a range of 129–1269 ms (193 total cycles of respiratory activity recorded in 15 cells). Inspiratory bursts were robust in Dbx1 preBötC neurons, with a mean amplitude of 15.2 ± 4.2 mV (range 5–36 mV) and a duration of 358 ± 99 ms (range 29–1050 ms). In addition, 8 of the 15 inspiratory Dbx1+ preBötC neurons exhibited characteristic inspiratory drive potentials with voltage-dependent spike inactivation (i.e., depolarization block) during the bursts (Fig. 5C), consistent with recruitment of the calcium-activated nonspecific cation current hypothesized to generate inspiratory bursts in preBötC neurons (Del Negro et al., 2005; Ramirez and Viemari, 2005; Rubin et al., 2009). These data show that preBötC Dbx1-derived glutamatergic neurons have a behavioral signature of firing before the onset of motor output (early I), which has been proposed as a hallmark signature of rhythmogenic function (Richter, 1982; Smith et al., 1990; Rekling et al., 1996a,b; Hayes and Del Negro, 2007). These data further suggest that Dbx1-derived neurons meet all the criteria for generating the in vitro inspiratory rhythm (Feldman and Del Negro, 2006).
Dbx1 is necessary for the formation of preBötC neurons
Dbx1 loss leads to the loss of a number of neural populations from the basal ganglia to the spinal cord (Pierani et al., 2001; Lanuza et al., 2004; Hirata et al., 2009). To determine the effects of the loss of Dbx1 function on VLM populations, we analyzed the VLM of Dbx1 homozygous null mice (E16.5–E18.5, n = 9). Figure 6 shows the expression of NK1R and SST in the preBötC (panels A and B) and RTN/pFRG (panel D) in an E18.5 Dbx1LacZ/LacZ mouse. β-gal was still present in cells of the VLM. However, NK1R- and SST-expressing neurons were completely absent from the area of the preBötC. NK1R was not coexpressed with β-gal outside of this region. NK1R expression appeared normal in the NA and RTN/pFRG (Fig. 6A,D). Additionally, SST-positive processes and puncta were still present within the VLM, indicating that the preBötC was not the sole source of SST in this region, consistent with SST receptor expression on nonrespiratory populations (Fig. 6B). Together these data suggest that the development and expression of NK1R and other genes within the preBötC and pFRG are independently regulated.
The loss of Dbx1 gene function eliminated preBötC NK1R and SST expression, but did not completely eliminate β-gal expression from the VLM. The overall number of remaining β-gal-expressing cells in the VLM decreased by 39% [67.2 ± 2.3 cells per hemisection (Dbx1LacZ/+), n = 14 vs 41.5 ± 1.9 cells per hemisection (Dbx1LacZ/LacZ), n = 5, p < 0.001, Student's t test, SEM]. In contrast, β-Gal/S100 coexpression increased by nearly 50% (283/943, n = 2). Additionally, we found no overlap of β-gal with FoxP2 or bHLHb5, markers of V1- and DB4-derived populations (Gray et al., 2004; Liu et al., 2007), in the VLM of either genotype, and no obvious increase in either population (data not shown). These data suggest that β-Gal expression in Dbx1LacZ/LacZ remains an accurate representation of the Dbx1 promoter activity during development.
Because the majority of VLM Dbx1-derived neurons do not express SST, it was possible that the absence of peptide markers did not indicate a general loss of VLM neurons in null mice. To test this, we analyzed the expression of neurotransmitter markers in Dbx1LacZ/LacZ mice. Consistent with the elimination of Dbx1-derived neurons, we observed a near-complete loss of VGlut2 in the respiratory regions of the VLM as well as adjacent to the XIIn in Dbx1LacZ/LacZ mice (Fig. 6C). VGlut2-expressing cells are still present in Lmx1b-derived catecholaminergic neurons. In these animals, only 3.9% (13/336, n = 3) of the remaining β-gal-expressing cells coexpressed VGlut2, while 17.9% (71/397, n = 3, not shown) expressed GAD1. To address the possibility that Dbx1 elimination decreases β-gal expression, but does not affect other properties of neurons such as Pax2 expression, we also counted the number of VLM VGlut2 neurons that coexpress Pax2 but not β-gal. In Dbx1LacZ/+ animals, 82% (253/307, n = 2) of Pax2-expressing glutamatergic neurons coexpressed β-gal. The remaining Pax2+/VGlut2+/β-gal− neurons were distributed throughout the VLM in small numbers with 1.9 ± 0.4 cells per hemisection. In homozygous mutants, however, the number of Pax2+/VGlut2+/β-gal− neurons per hemisection was statistically unchanged (1.2 ± 0.3 cells per hemisection, n = 2, p = 0.07, Student's t test), indicating that the loss of VGlut2 expression corresponds to the loss of Dbx1-derived neurons. Together, these data suggest a large change in the cellular composition of the VLM in Dbx1 mutant mice, which also includes an increase in the ratio of β-Gal-expressing glia and GABAergic neurons. These data further suggest that Dbx1 gene function is necessary for the specification of the glutamatergic neurons of the respiratory column, including the preBötC.
Dbx1 is necessary for inspiration in vivo and in vitro
E18.5 wild-type (13/13) and Dbx1LacZ/+ (14/16) mice show one or two distinct rhythmic respiratory-like behaviors within 20 min of cesarean delivery. The first is a classic rhythmic inspiratory activity involving activation of jaw and diaphragm muscles, expansion of the rib cage, and compression of the abdominal region, leading to inspiratory airflow (Fig. 7A; supplemental Video 1, available at www.jneurosci.org as supplemental material). The second is a transient rhythmic activity of abdominal muscles without jaw movements, and with a slight compression of ribcage corresponding to active expiration (Fig. 7B; supplemental Video 2, available at www.jneurosci.org as supplemental material). Some animals show only inspiratory activity, while others show both, but there was no difference in either behavior between wild-type or Dbx1LacZ/+ mice. All animals exhibiting respiratory behaviors had inflated lungs upon dissection (Fig. 7C).
Dbx1LacZ/LacZ mice, in sharp contrast, do not make any inspiratory, expiratory, or jaw movements, even with extensive tactile stimulation (11 of 11) (supplemental Video 3, available at www.jneurosci.org as supplemental material). Dbx1 mutant mice do, however, make locomotor movements, respond to stimuli, and show rhythmic heart activity. Furthermore, Dbx1 mutant mice have completely collapsed lungs, indicating the absence of any inspiratory efforts. Dbx1 mutant lung and diaphragm appear otherwise normal (Fig. 7D).
As Dbx1-derived neurons are present throughout the brain, the absence of in vivo behavior may be the consequence of a role for Dbx1 outside the VLM. To address this, we tested whether Dbx1 was necessary for inspiratory rhythm in isolated brainstem–spinal cord preparations under conditions known to enhance respiratory activity. In wild-type or Dbx1LacZ/+ E18.5-P0 mice, large-amplitude inspiratory activity was present in all animals tested (n = 9) (Fig. 7E). In Dbx1LacZ/LacZ mice, however, no inspiratory activity was present from cervical roots (n = 10).
While consistent with the large loss of glutamatergic neurons in the VLM, the absence of rhythmic activity does not necessarily indicate the inability to generate rhythms. We tested whether we could rescue respiratory rhythms in Dbx1LacZ/LacZ mice by stimulating the remaining network with well established respiratory stimulants: 5-HT and acidosis (Perségol and Viala, 1994; Onimaru et al., 1998; Iizuka, 1999; Peña and Ramirez, 2002; Bodineau et al., 2004; Iizuka, 2004; Kawai et al., 2006; Ptak et al., 2009). Mutant hindbrain preparations exhibited no inspiratory-like output in control aCSF at pH 7.4, nor when exposed to 5 μm 5-HT (although tonic cervical nerve discharge increased, as expected (5/5). Decreasing aCSF pH from 7.4 to 7.0 stimulates inspiratory frequency in wild-type animals, but did not induce respiratory-like activity in Dbx1 mutant preparations (Fig. 7E). As one further measure, we tested whether a low concentration of SST (10−13 m) in pH 7.0 aCSF might disinhibit rhythmic cranial root activity as seen with opioids and rhythmic VII nerve activity in rats (Onimaru et al., 2006). However, this combination was without effect in Dbx1LacZ/LacZ mutants (Fig. 7E). These data indicate that Dbx1 loss eliminates the ability to express inspiratory behavior both in vivo and in vitro.
Discussion
Discovering the origin and identity of the neurons constituting a neural network is key for understanding the neural development and genetic control of behavior (Garcia-Campmany et al., 2010). Here we show that NK1R+/SST+ neurons of the preBötC represent a subset of Dbx1-derived neurons. Moreover, Dbx1 specifics nearly all the glutamatergic neurons of the respiratory VLM. Dbx1-derived preBötC neurons are respiratory and Dbx1 gene function is necessary for the formation of respiratory VLM and for the expression of breathing in vivo as well as in vitro. These data suggest that Dbx1 is an essential component of the genetic cascade necessary for inspiration, which has important implications for understanding the network underlying breathing. While this paper was in review, a conceptually similar paper also found an essential role for Dbx1 in the formation of the preBötC and for breathing both in vivo and in vitro (Bouvier et al., 2010).
Similar to our results, Bouvier et al. (2010) found that the overwhelming majority of Dbx1 β-Gal-expressing neurons were glutamatergic and that they made up approximately half of VLM glutamatergic neurons. They did not, however, identify the origin or role of the remaining glutamatergic neurons. We showed, in contrast, that the non-Dbx1-derived glutamatergic neurons within the preBötC region are Lmx1b-derived catecholaminergic neurons important for modulating blood pressure and cardiovascular function and likely not directly involved in breathing. This indicates that all preBötC glutamatergic neurons are Dbx1 derived. Our results are consistent with the finding that the elimination of Robo3 from Dbx1-derived neurons is sufficient to eliminate bilateral synchronization of respiratory outputs, as few non-Dbx1-derived Robo3-expressing glutamatergic neurons are present (Yuan et al., 2002; Bouvier et al., 2010; Renier et al., 2010).
Within the preBötC, a variety of intracellular criteria, including intrinsic bursting properties and/or ionic conductances, have been used to differentiate putative rhythmogenic from follower neurons. The spectrum of hypotheses regarding the cellular bases for rhythmogenesis has generated vigorous debate (Del Negro et al., 2002; Peña et al., 2004; Ramirez and Garcia, 2007). Our study strongly suggests that all excitatory preBötC respiratory neurons represent variations of a single progenitor population and not distinct developmental populations. This is in sharp contrast to the hypothesized organization of locomotor oscillators where multiple developmentally defined populations play roles in rhythm and pattern generation (Kozlov et al., 2009; Garcia-Campmany et al., 2010).
Phase of firing during the respiratory cycle has also been proposed to identify distinct functional subclasses of preBötC neurons (Smith et al., 1990; Rekling et al., 1996a; Koshiya and Smith, 1999; Thoby-Brisson et al., 2000; Thoby-Brisson and Ramirez, 2001; Peña et al., 2004; Ramirez and Viemari, 2005; Koizumi et al., 2008; Rubin et al., 2009). In E15.5 rhythmically active slices, Bouvier et al. (2010) found that nearly 85% of Dbx1-derived neurons were rhythmically active and in phase with inspiratory output as measured by calcium imaging, and that 70% were rhythmically active and received phasic inspiratory depolarization with whole-cell recordings. We extend these results and find that an early-I firing phenotype in postnatal rhythmic slices is a characteristic property of nearly 95% of postnatal Dbx1-derived glutamatergic neurons. This is in contrast to the firing pattern of genetically identified inspiratory glycinergic neurons within the preBötC, which begin their inspiratory-related firing nearly in sync with motor output (Morgado-Valle et al., 2010). What role intrinsic conductances and/or network synaptic process play in the early-I phenotype is still incompletely understood (Rubin et al., 2009). Nevertheless, these data suggest that in the absence of recordings from genetically labeled preBötC glutamatergic neurons, an early-I firing pattern represents a reasonable approximation for identifying excitatory neurons. Further, they suggest that transmitter identity can be inferred from the rhythmic inspiratory firing patterns of neurons in the literature (Thoby-Brisson and Ramirez, 2001).
The respiratory portion of the VLM contains anatomically and functionally distinct subdivisions that contain both excitatory and inhibitory interneurons in addition to the preBötC (Schreihofer et al., 1999; Alheid and McCrimmon, 2008). Bouvier et al. (2010) focused exclusively on the development of Dbx1-derived neurons of the preBötC. Our finding that Dbx1-derived neurons extend throughout the VLM and represent nearly all VLM non-catecholaminergic, glutamatergic neurons suggests that excitatory neurons outside the preBötC play a role in shaping respiratory output. This is further reinforced by the heterogeneous pattern of NK1R and SST2aR expression within the VLM that may explain the ability of Substance P to promote sigh activity in vitro by acting on rostral brainstem regions (Lieske et al., 2000; Doi and Ramirez, 2008; Ruangkittisakul et al., 2008). The recent finding that the introduction of a fragment of the SST promoter into preBötC neurons in adult rat drives expression of GFP in a larger percentage of preBötC neurons than normally express SST is consistent with a developmentally shared origin of all preBötC excitatory neurons (Tan et al., 2010). We also find that the VLM contains a subset of Dbx1-derived glia, whose specific role in respiratory modulation is still incompletely understood (Gourine et al., 2010).
Whether the specific peptide or peptide receptor expression within individual VLM neurons identifies unique functional populations or merely components of a larger distributed network is unknown. We hypothesize that preBötC core neurons represent a highly connected, and thus specialized, subset for communicating respiratory oscillations to the larger Dbx1-derived respiratory population and that their elimination affects breathing by disrupting the propagation of excitatory neurotransmission in the respiratory network (Del Negro et al., 2002; Rubin et al., 2009). The extent to which Dbx1-derived or other glutamatergic neurons outside the preBötC core can show plasticity after preBötC lesion remains to be determined (Gray et al., 2001; McKay et al., 2005; McKay and Feldman, 2008). The finding that Dbx1-derived, glutamatergic neurons extend throughout the VLM, however, suggests that Dbx1-derived neurons outside the preBötC may be capable of aspects of respiratory rhythm generation given the maintenance of sufficient connectivity (Forster et al., 2010; Neumueller et al., 2010).
Dbx1 mutant mice do not generate either inspiratory or expiratory output in vivo, nor do they generate inspiratory output in vitro. The data suggest that the loss of inspiratory activity in Dbx1 mutants is a direct consequence of the loss of VLM glutamatergic neurons and that remaining brainstem populations are insufficient to recover respiratory output. We further hypothesize the inspiratory rhythm is generated by VLM Dbx1-derived neurons, including the preBötC, as Dbx1-derived neurons meet many of the criteria for respiratory rhythm generation (Feldman and Del Negro, 2006). It should be pointed out, however, that Dbx1-derived neurons in the spinal cord have been shown to directly drive motoneurons (Lanuza et al., 2004). It is possible that the absence of respiratory behavior may be at least in part the consequence of the inability of non-Dbx1-derived neurons outside the VLM to propagate their signal to motoneurons (Koizumi et al., 2008). While the loss of inspiratory activity might be expected by the absence of VLM glutamatergic neurons, expiratory activity has been proposed to be generated by Atoh1- and/or Phox2b-expressing populations. It remains to be determined whether Dbx1-derived populations within the VLM or elsewhere in the CNS are necessary for the expression of independent expiratory activity in vivo or in vitro.
In summary, we provide a genetic description for a population of neurons necessary for a fundamental homeostatic behavior, breathing. These data suggest that the network underlying the breathing rhythm is genetically encoded and may represent an ideal model system for examining the functional, developmental, and evolutionary origins of behavior. We propose that breathing behavior is generated by a genetically definable population and that all the properties that comprise this quintessential mammalian CPG, including the rhythmogenic, synaptic, and intrinsic membrane properties of the constituent neurons, can be generated from a single developmental precursor population. These data may provide a genetic framework for addressing the evolution of neural circuits as well as for understanding disorders of breathing with a central etiology, such as apnea of prematurity, sudden infant death syndrome, central sleep apnea, and respiratory failure in neurodegenerative disorders such as multiple system atrophy or Perry syndrome (Feldman and Del Negro, 2006).
Footnotes
This work was supported by The College of William and Mary Science Education and Research Program funded by the Howard Hughes Medical Institute (J.A.H., C.A.D.N.), Fondo Nacional de Desarrollo Científico y Tecnológico Grants 1090375 and 7070065 (I.L., J.E.), Jane Coffin Childs and Dystonia Medical Research Foundation Awards (S.E.R.), National Institute of Neurological Disorders and Stroke (NINDS) Grant 1 F31 NS071860-01 (M.C.D.P.), NINDS Grant R21 NS070056-01 (C.A.D.N.), National Heart, Lung, and Blood Institute (NHLBI) Grant R01 HL104127-01 (C.A.D.N.), National Institute on Drug Abuse (NIDA) Grant DA020140 (T.H., J.G.C.), the Parker B. Francis and McDonnell Research Foundations (P.A.G.), and NHLBI Grant R01 HL089742 (G.L., S.T., P.A.G.). The content is solely the responsibility of the authors and does not necessarily represent the official views of the NHLBI, NINDS, NIDA, or National Institutes of Health. We thank Marcelo Otárola and George McMurray for technical assistance. We thank the following for advice, assistance, discussion, and biological resources that made this work possible: Tom Jessell for Dbx1LacZ/+ mice and Lmx1b antibody; Randy Johnson for Lmx1bLacZ/+ mice; Josh Huang for Gad1-GFP mice; Frank Constantini for Rosa26-EYFP mice; Qiufu Ma for Slc6a5 and Gad1 in situ hybridization (ISH) probes; Martyn Goulding for Evx1 ISH probe, antibody, and Evx1 mutant mice; and Michael Greenberg for unpublished bHLHb5 data. P.A.G. conceived the study. J.A.H., M.C.D.P., and C.A.D.N. carried out intracellular recordings and statistical analysis. G.Y.L. sectioned brains and performed IHC and ISH. P.A.G. acquired, analyzed, and quantified anatomical data. S.T. performed in vivo video taping and analysis and in vitro mutant recordings. J.E. performed quantal slowing experiments. J.E. and I.L. performed and analyzed quantal slowing data. S.E.R., T.H., and J.G.C. provided unpublished resources, technical expertise, and edited the manuscript. J.A.H,. I.L., and S.T. edited the manuscript. C.A.D.N., J.E., and P.A.G. designed the experiments and wrote the manuscript.
- Correspondence should be addressed to Paul A. Gray at the above address. pgray{at}pcg.wustl.edu