Abstract
All neuronal networks are modulated by multiple neuropeptides and biogenic amines. Yet, few studies investigate how different modulators interact to regulate network activity. Here we explored the state-dependent functional interactions between three excitatory neuromodulators acting on neurokinin1 (NK1), α1 noradrenergic (α1 NE), and 5-HT2 serotonin receptors within the pre-Bötzinger complex (pre-BötC), an area critical for the generation of breathing. In anesthetized, in vivo mice, the reliance on endogenous NK1 activation depended on spontaneous breathing frequency and the modulatory state of the animal. Endogenous NK1 activation had no significant respiratory effect when stimulating raphe magnus and/or locus ceruleus, but became critical when α1 NE and 5-HT2 receptors were pharmacologically blocked. The dependence of the centrally generated respiratory rhythm on NK1 activation was blunted in the presence of α1 NE and 5-HT2 agonists as demonstrated in slices containing the pre-BötC. We conclude that a modulator's action is determined by the concurrent modulation and interaction with other neuromodulators. Deficiencies in one neuromodulator are immediately compensated by the action of other neuromodulators. This interplay could play a role in the state dependency of certain breathing disorders.
Introduction
Neuromodulators play critical roles in regulating every aspect of neuronal activity. Their functional roles are typically identified by using a variety of pharmacological and genetic approaches aimed at activating or blocking the action of a specific neuromodulator and characterizing the resulting functional consequences (Ptak et al., 2000, 2002; Peña and Ramirez, 2004; Duangdao et al., 2009; Hodges et al., 2009; Ward and Walker, 2009; Jansen et al., 2010). However, the functional outcome of a given manipulation, be it the activation or the deletion of a neuromodulator or ion channel, is often more complex than expected. This is most evident in genetically manipulated animals in which unexpected results are often attributed to compensatory mechanisms (Telgkamp et al., 2002; Hilaire et al., 2003; Swensen and Bean, 2005; Ortinski et al., 2006; Higuchi et al., 2008). The introduction of conditional gene knock-outs (Benavides et al., 2007; Djukic et al., 2007) or the recent development of approaches such as the use of allatostatin in genetically modified mammalian networks helped to overcome some of the difficulties in interpreting the potential influence of long-term compensatory mechanisms (Tan et al., 2008; Wehr et al., 2009; Zhou et al., 2009). However, a major conceptual problem in assessing the role of specific modulators or specific ion channels is the fact that neurons and networks are never controlled by single types of ion channels, receptors, and neuromodulators. Instead, neuronal activity is typically the result of a complex orchestration involving multiple ion channels, multiple receptors, and multiple neuropeptides and biogenic amines (Thoby-Brisson and Simmers, 1998; Doi and Ramirez, 2008; Grashow et al., 2009), and this orchestration is state dependent (Nadim et al., 2008). Thus, manipulating or lesioning a single type of ion channel, receptor, or neuromodulator will have unexpected effects, due to the interference with multiple regulatory systems and the state of the animal. In fact, it may be wrong to assume that any neuronal function depends on a single modulator, receptor, or ion channel. The multitude of regulatory processes is a fundamental biological property, and understanding how multiple receptors, ion channels, and neuromodulators are functionally integrated is of great basic scientific and clinical relevance.
Unfortunately, only a few studies directly investigate the role and interaction between different modulators and receptor subtypes (Peck et al., 2006; Stein et al., 2007; Fadok et al., 2009; Grashow et al., 2009). Here, we explored the converging influence of three excitatory neuromodulators on the mammalian respiratory network. The respiratory rhythm is generated within the ventrolateral side of the brainstem distributed between the pontine respiratory group, pre-Bötzinger complex (pre-BötC), and rostral ventral respiratory group (VRG) (Onimaru and Homma, 2003; Feldman and Del Negro, 2006; Smith et al., 2007). The pre-BötC is essential for generating rhythmic breathing activity (Achard et al., 2005), and is thought to play a role in generating different forms of inspiratory activities (Lieske et al., 2000).
Respiratory rhythm generation depends on classical neurotransmitters, such as amino acids, and acetylcholine, biogenic amines (Peña and Ramirez, 2002; Pagnotta et al., 2005; Shao and Feldman, 2005; Viemari and Ramirez, 2006), and neuropeptides (Bianchi et al., 1995). The release of these neuromodulators varies by awake/sleep/anesthetized states (Dringenberg and Vanderwolf, 1998; Brown et al., 2001; Ursin, 2002; Berridge and Waterhouse, 2003). Here, we investigate the role of substance P (SP) in relation to norepinephrine and serotonin. Our study suggests that the relative contribution of these modulators depends on network state, and the state dependency of the network is partly determined by the interplay between these neuromodulators.
Materials and Methods
The transverse slice preparation
Brainstem transverse slice preparations from CD1 mice (P6–P10, Charles River Laboratories) were obtained using a technique described in detail previously (Ramirez et al., 1996). The most important steps are summarized here. Experimental procedures were approved by the Institutional Animal Care and Use at the Seattle Children's Research Institute. Mice were deeply anesthetized with ether and decapitated. Isolated brainstems were then placed in ice-cold artificial CSF (aCSF) bubbled with carbogen (95% O2–5% CO2). The aCSF contained the following (in mm): 128 NaCl, 3 KCl, 1.5 CaCl2, 1 MgCl2, 24 NaHCO3, 0.5 NaH2PO4, and 30 d-glucose, pH 7.4. Brainstems were glued rostral end up onto an agar block for mounting into a vibratome (Leica Microsystems). Brainstems were serially sliced until the rostral boundary of the pre-BötC (Smith et al., 1991) was identified by anatomical landmarks such as disappearance of the facial nucleus, and the first appearance of the inferior olive, the nucleus ambiguous, and hypoglossal nucleus. A single 500- to 680-μm-thick slice was then taken. Because the slices also contained regions caudal to the pre-BötC, we refer to the region encompassed in the slice as the VRG. Slices were transferred into a recording chamber, continuously superfused with oxygenated aCSF, and maintained at a temperature of 30 ± 0.5°C. To initiate and maintain fictive respiratory rhythmic activity, the potassium concentration of the perfusate was raised from 3 to 8 mm over 30 min (Ramirez et al., 1996; Tryba et al., 2003).
In vivo anesthetized mouse preparation
CD1 mice (P15–P23) were anesthetized with urethane (1.5 g/kg). The electrical signal of the hypoglossal nerve and/or the electromyography (EMG) of intercostal muscles were recorded. Mice were placed in a supine position, and the head was fixed with a stereotaxic apparatus. The neck of the mice was opened from the ventral side, the trachea was cut, and plastic Y-shaped tubing for supplying oxygen was inserted into the proximal end of the trachea (cannulation). The bone of the skull covering the ventral brainstem was partially removed with small scissors and forceps. In this preparation, the reverse Y-shaped basilar artery and the branches of the hypoglossal nerve could be observed. The dura and arachnoid membrane were removed to expose the ventral medulla. The surface of the ventral medulla was continuously perfused with 95% O2–5% CO2 equilibrated aCSF solution at 30 ± 0.5°C. In all cases, 100% oxygen was supplied through cannulation without artificial ventilation.
Electrical measurements
Extracellular recordings.
In the transverse slice preparation, population activity recordings were obtained with suction electrodes positioned on the surface of the ventrolateral region containing the pre-BötC. Signals were amplified 2000×, filtered (low-pass, 1.5 kHz; high-pass, 250 Hz), rectified, and integrated using an electronic filter (time constant of 30–50 ms). Integrated population activity from the VRG was always in phase with integrated inspiratory activity of the hypoglossal motor nucleus (Telgkamp and Ramirez, 1999). All recordings were stored on a personal computer using pClamp software (version 9.2, Molecular Devices) and analyzed off-line using customized analysis software written with IGOR Pro and Mini Analysis (Wavemetrics and Synaptosoft) (Viemari and Ramirez, 2006). Burst amplitude, frequency, and duration were detected and calculated automatically and manually. An irregularity score was determined for each cycle by applying the following formula for consecutive cycle length value: Sn = 100 × ABS(Pn − Pn−1)/Pn−1, where Sn is the score of the nth cycle, Pn is the period of the nth cycle, Pn−1 is the period of the cycle preceding the nth cycle, and ABS is the absolute value (Barthe and Clarac, 1997). Detected values were automatically sorted into tables that were imported into Excel and graphics programs (Corel Draw). These values were also used to analyze regularity of the VRG population.
Extracellular hypoglossal nerve or EMG recordings from intercostal muscles in anesthetized mice.
A glass monopolar suction electrode (tip diameter 100–200 μm) held in a micromanipulator was used to record from the hypoglossal nerve. Without cutting the hypoglossal nerve, the suction electrode was placed on the nerve. Extracellular signals were recorded using a patch-clamp amplifier (HEKA EPC8, HEKA Electronic). A Teflon-covered Ag bipolar electrode was used for EMG recordings. The skin over the abdominal and intercostal area on the right side was partially removed, and the bipolar electrode was placed on the surface of the intercostal muscle. Signals were AC amplified and bandpass filtered (8 Hz to 3 kHz)
Electrical stimulation of raphe magnus and locus ceruleus.
After mice were full anesthetized and immobilized, concentric bipolar stimulation electrodes (TM53CCINS, World Precision Instruments) were inserted into both raphe magnus (RM) and locus ceruleus (LC) from the ventral side of the medulla. Electrical stimulation for both nuclei used repetitive rectangular pulses (duration, 1 ms; intensity, 10–100 μA). Because of the large electrical stimulus artifacts created while RM and/or the LC were stimulated, it was impossible to record activity from the hypoglossal nerve during electrical stimulation. EMG activity was very stable and much less affected by the artifacts caused by electrical stimulation. We therefore recorded EMG from intercostal muscle as a measure of breathing activity for these stimulation experiments.
Drug application
Slice preparation.
In slice preparations, a perfusion system was used that allowed rapid drug applications within 5 s, using a modification of the “Y-tube technique” (Murase et al., 1990). The Y-tube technique uses both negative vacuum pressure and gravity. The Y-shaped tube is created from polyethylene tubing bent into a V shape, with a small hole made at the curve end, into which a short segment of thinner polyethylene tubing was inserted and affixed with silicon-based glue, forming the tip of the Y-tube. One end of the V-shaped tubing was connected to the test aCSF reservoir by silicon tubing. Separate control and test solution reservoirs were held 50 cm above the level of the Y-tube tip, so that solution flowed from the Y-tube tip by gravity. The other end of the V-shaped tubing was connected to a drain bottle through an electrical valve (Series 075T, Bio-Chem). Constant negative pressure (6.77 psi) was maintained in the drain bottle by the vacuum pump (VPO435A, MEDO USA). Closing the valve to the drain bottle allowed the flow of perfusate by gravity (10 ml/3 min), whereas opening the valve closed this flow. The system was used as follows. The tip of the Y-tube was positioned at a distance 1–2 mm from the pre-BötC. For control perfusions, the input end of the Y-tubing was placed in the control aCSF reservoir, with the drain valve closed. To apply drugs, the input end of the Y-tubing was removed from the control aCSF reservoir, wiped on tissue paper, and transferred to the test aCSF reservoir. The difference of temperature between control and test aCSF was measured to be constant within ±0.3°C
Microinjection studies in in vivo anesthetized mice.
Microsyringes (Hamilton microsyringe no. 80330) with 33 gauge needles containing neurokinin1 (NK1) receptor antagonist (100 μm RP67580, 1 μl), α1 noradrenergic (α1 NE) receptor antagonist (60 μm prazosin, 0.5 μl), or cocktail of NE receptor antagonist (α1 NE antagonist 30 μm prazosin, α2 NE antagonist 1 μm yohimbine, β NE antagonist 30 μm alprenolol, total 0.6 μl) and/or 5-HT2 serotonin receptor antagonist (ketanserin 80 μm, 0.5 μl) were positioned with micromanipulators (KITE, World Precision Instruments). The needles of the microsyringes were inserted into the right pre-BötC from the ventral side. During hypoglossal nerve recording or intercostal EMG recordings, these antagonists were microinjected into the right pre-BötC at a rate of 0.3 μl/min. We did not attempt to perform bilateral needle injections to limit the damage to the pre-BötC, which would have compromised respiratory rhythm-generating mechanisms.
Identification of drug injection and electrical stimulation sites in in vivo preparations.
Anodal electrolytic lesions were made by DC currents (500 μA) to mark the stimulation sites. Evans blue (Sigma 0.1 μl) was injected into the pre-BötC to label NK1 antagonist injection sites. After electrophysiological recordings were completed, mice were deeply anesthetized with supplemental urethane. Then, transcardial perfusions with 4% paraformaldehyde (PFA) in 0.1 m PBS, pH 7.4, were performed. The medulla was removed and immersed overnight in 4% PFA with 30% sucrose. The medulla was subsequently cut into 50 μm sections on a cryostat and stained with cresyl violet.
Drugs
The following drugs were used in this study: SP (Tocris Cookson), [Sar9,Met(O2)11]-SP (Sar,Met-SP, Tocris Cookson), (3aR,7aR)-octahydro-2-[1-imino-2-(2-methoxyphenyl) ethyl]-7,7-diphenyl-4H-isoindol (RP67580, Tocris Cookson), GR82334 (Tocris Cookson), (2S,3S)-3-[[3,5-bis(trifluoromethyl)phenyl] methoxy]-2-phenylpiperidine hydrochloride (L733060, Tocris Cookson), N-acetyl-l-tryptophan 3,5-bis(trifluoromethyl)benzyl ester (L732138, Tocris Cookson), 1-(4-amino-6, 7-dimethoxy-2-quinazolinyl)-4-(2-furanylcarbonyl)piperazine hydrochloride (prazosin, Tocris Cookson), 3-(2-[4-(4-fluorobenzoyl)-1-piperidinyl (ketanserin, Sigma-RBI), 1-(o-allylphenoxy)-3-(isopropylamino)-2-propanol hydrochloride (alprenolol, Sigma-RBI), 2-[(2-cyclopropylphenoxy) methyl]-4,5-dihydro-1H-imidazole hydrochloride (cirazoline hydrochloride, Sigma-RBI), and (±)-1-(2,5-dimethoxy-4-iodophenyl)-2-aminopropane hydrochloride (DOI hydrochloride, Sigma-RBI).
All drugs were initially dissolved in dimethylsulfoxide (DMSO, Sigma-RBI) or distilled water and were mixed to final concentrations in aCSF. The final concentration of DMSO was <0.3% in the aCSF.
Statistical analysis
Data were analyzed with SPSS and StatView software (SPSS 8.0) and StatView-J5.0 (Adept Scientific). Burst frequency and irregularity score were assessed by Wilcoxon signed-rank test as a paired nonparametric statistical test. The Mann–Whitney U test was used for unpaired nonparametric statistical analysis. In other cases, a one-way ANOVA was used for repeated measurements on the same subjects, followed by Tukey's or Bonferroni tests for multiple-comparison analysis. Statistical significance was assumed to be significant if p < 0.05. Deviations from the mean are given in SE.
Results
Endogenous SP release consistently activates respiratory activity in slice preparations containing the pre-BötC
The endogenous SP release and tonic NK1 receptor activation were characterized in isolated transverse slice preparations containing the pre-BötC. SP and the NK1 agonist Sar,Met-SP increased extracellularly recorded rhythmic population activity in a dose-dependent manner (Fig. 1), while NK1 receptor-specific antagonists RP67580, L733060, L732138, and GR82334 produced an inhibitory effect on respiratory frequency in a dose-dependent manner (Fig. 2; supplemental Fig. 1, available at www.jneurosci.org as supplemental material). The inhibitory effects of RP67580 on population activity was confirmed in reduced pre-BötC island preparations (Fig. 3), suggesting that the source for endogenous SP release is contained within the pre-BötC region.
Exogenous application of either SP or NK1 agonist facilitates respiratory population activity recorded in medullary slice preparation containing the pre-BötC. Shown are effects of SP and NK1 agonist Sar,Met-SP on respiratory rhythmic activity recorded in a portion of the VRG containing the pre-BötC in vitro. A, B, Two traces of integrated activity obtained from extracellular population activity recorded from the surface of a portion of the VRG that contains the pre-BötC. Upward deflections reflect bursts of fictive inspiratory activity. Note that application of 30 nm SP (A) and 100 nm Sar,Met-SP (B) facilitates respiratory activity. C, D, Graphs indicating that SP (C) and Sar,Met-SP (D) enhance respiratory rhythmic activity in a dose-dependent manner (collected number is shown in each bar graph).
Endogenous SP release activates NK1 receptors in medullary slice preparation containing the pre-BötC. A, C, Integrated activity obtained from extracellular population activity recorded from the surface of a portion of the VRG containing the pre-BötC. Increasing concentrations of the NK1 antagonists RP67580 (A) and L733060 (C) cause an increased inhibitory effect on rhythmic population activity (traces). B, D, Graphs indicating that RP67580 (B) and L733060 (D) inhibit the frequency of respiratory rhythmic activity (ordinate) in a dose-dependent manner (abscissa; *p < 0.05, number is shown in each bar graph). The frequency values were normalized to the control frequency obtained before the application of the NK1 antagonists (100%).
Endogenous SP activation persists in pre-BötC island preparation. Shown is the effect of the NK1 antagonist on respiratory population activity recorded from a pre-BötC island slice. A, Schematic of a transverse slice (left schematic), which is used to isolate an island slice (right schematic) that contains the pre-BötC and a minimal amount of surrounding tissue. B, Integrated population activity obtained from extracellular activity recorded from the surface of a portion of the VRG containing the pre-BötC under control conditions (top trace) and following the application of the NK1 antagonist RP67580 (bottom trace). C, D, The application of the NK1 antagonist RP67580 decreases significantly the frequency (C) and increases the irregularity of respiratory rhythmic activity (D). The irregularity is expressed as the “irregularity score” as explained in Materials and Methods (white bar: control, gray bar: 1 μm RP67580, n = 5).
Inhibition of respiratory rhythm by NK1 antagonist in hemilateral pre-BötC depends on the breathing rate in anesthetized whole animals
We next investigated the effects of endogenous NK1 receptor activation within the pre-BötC on spontaneous breathing rhythms using anesthetized in vivo mice. In a series of experiments, we directly delivered the specific NK1 antagonist RP67580 by focal hemilateral injection into the pre-BötC region (Fig. 4A,B), while monitoring respiration in a hypoglossal nerve recording. Control needle insertions and aCSF injections (1 μl) into the right pre-BötC had no significant effect on respiratory activity (Fig. 4C). Injection of the NK1 antagonist RP67580 (100 μm, 1 μl) in the same location significantly decreased both the rate (Fig. 4D,E; supplemental Fig. 2, available at www.jneurosci.org as supplemental material) and regularity (Fig. 4G) of respiratory rhythm. However, in contrast to the in vitro experiments, the effect on the respiratory rhythm was not as consistent, and we observed that blocking NK1 receptor had striking effects in some, but not all, animals. Indeed, we found a significant correlation between the degree of inhibition on respiratory rate and initial breathing rate (Fig. 4F). This effect was most notable for slow initial breathing rates less than 2 Hz. We observed no significant correlation between NK1 antagonist-dependent decreases in irregularity score and initial breathing rate (Fig. 4H). We hypothesize that spontaneous breathing rates of ∼2 Hz and those below 2 Hz reflect different modulatory states of the respiratory network, determined by other excitatory neuromodulators.
The inhibitory effect of NK1 antagonist on respiratory activity depends on the breathing frequency in the anesthetized animal. Shown is the effect of NK1 antagonist on respiratory activity in in vivo mice. A, Left, Identification of the injection site by Evans blue, which was injected together with the NK1 antagonist. Right, The tract of a single needle that was inserted into the pre-BötC from the ventral side. B, Schematic of the medulla indicating that all injection sites were located in the ventral medulla in the area of the pre-BötC. C, Graph indicating that the needle insertion (white bar) and the injection of saline (green bar) have no significant effect on respiratory activity. D, Extracellularly recorded XII activity in control (top trace) and following the injection of NK1 antagonist into the hemilateral pre-BötC (bottom trace). E, The injection of the NK1 antagonist (RP67580, 100 μm, 1 μl) modulates the respiratory frequency (*p < 0.05, n = 16). F, Scatter plot illustrates a direct relationship between the percentage change in respiratory frequency (ordinate) and the baseline breathing frequency of the animal before the injection of the antagonist (abscissa). The percentage change in respiratory frequency describes the percentage frequency decrease caused by the NK1 antagonist compared to the control frequency before the antagonist injection. Note that the inhibitory effect of the NK1 antagonist depends significantly on the control breathing frequency in the anesthetized animal (y = 31.96x − 74.11, R2 = 0.633). G, The injection of NK1 antagonist increases the irregularity score (*p < 0.05). H, Scatter plot illustrates that there is no significant relationship between the irregularity score (ordinate) and the baseline respiratory frequency (abscissa) (y = −24.4x − 83.5, R2 = 0.11).
To address this hypothesis, we manipulated the modulatory state of the respiratory network using various pharmacological and electrophysiological approaches targeted at the pre-BötC.
In one series of experiments, we only used anesthetized mice with an initial spontaneous respiratory rate of 2 Hz. Before injecting NK1 antagonist into the pre-BötC, we preinjected antagonists of both α1 NE receptors (prazosin, 60 μm, 0.5 μl), and 5-HT2 receptors (ketanserin, 80 μm, 0.5 μl) into the same hemilateral site in the pre-BötC (Fig. 5A,B). The combined injection of both prazosin and ketanserin decreased both the frequency and regularity of respiratory rhythms. These results suggest that tonic activation of both α1 NE receptors and 5-HT2 receptors within the pre-BötC is required for the maintenance of both high respiratory frequency and regularity. In the absence of tonic α1 NE and 5-HT2 receptor activation, subsequent injection of NK1 receptor antagonist further reduced respiratory rate (Fig. 5B–D). This shows that endogenous activation of NK1 receptors becomes critical for respiratory rhythm generation when α1 NE and 5-HT2 receptor activation is decreased and baseline respiratory rate is low.
The modulatory role of NK1 receptors depends on the activation of α1 NE and 5-HT2 receptors. A, Schematic illustrating the experimental protocol used for examining the relationship between NK1, α1 NE, and 5-HT2 receptors. B, EMG activity recorded from intercostal muscles under control conditions (top trace), following the injection of the NK1 antagonist (RP67580, second trace), control conditions of the other case (third trace), following the injection of a cocktail containing prazosin and ketanserin (fourth trace), and following the additional injection of the NK1 antagonist (bottom trace). C, D, The effects of the NK1 antagonist (gray bars) on respiratory frequency (C) and irregularity score (D) of the respiratory frequency are enhanced following the concurrent injection of α1 NE and 5-HT2 antagonists (red bars). The inset in C illustrates that blocking both α1 NE and 5-HT2 receptors decreases the respiratory frequency, indicated as a negative percentage change (red dots).
Electrical stimulation of LC and RM blocks the effect of NK1 receptor antagonist
We next performed ipsilateral electrical stimulation of LC and RM in combination with hemilateral injection of NK1 antagonist within the pre-BötC in semi-intact mice to investigate how increased aminergic drive influences the dependency on endogenous NK1 activation. In the CNS, the LC and RM provide the main sources for NE and 5-HT, respectively (Mason, 2001; VanderHorst and Ulfhake, 2006). Both these nuclei provide strong projections to the pre-BötC (Bianchi et al., 1995). Under control conditions, electrical stimulation of either LC or RM increased the frequency of the breathing activity, in an intensity-dependent manner (Fig. 6A–C, electrical stimulation for 10 s). Electrical stimulation-induced facilitation of respiration was acute and reversible, suggesting that the effect was due to the neuronal stimulation and not due to a collateral structural damage (Fig. 6D). In all of the five examined cases, the actual increase in breathing rate caused by the simultaneous LC and RM stimulation was smaller than the sum of the rate increases expected from the experiments in which LC and RM were stimulated separately (Fig. 6E).
Electrical stimulation of LC or RM facilitates respiratory activity in an intensity-dependent manner. A, EMG activity obtained from intercostal muscles under control condition (top trace), in the presence of 0 μA LC stimulation (second trace), 10 μA LC stimulation (third trace), 20 μA LC stimulation (fourth trace), 30 μA LC stimulation (fifth trace), 30 μA RM stimulation (sixth trace), and 30 μA LC plus RM stimulation (bottom trace). B, C, Bar graphs illustrating that electrical stimulation of LC (pink bar) and/or RM (blue bar) increase respiratory activity in an intensity-dependent manner (B and C, *p < 0.05). D, Graph illustrating that the effect on respiratory activity is completely reversible upon termination of the stimulation (pink bar, LC; blue bar, RM stimulation). E, Graph illustrating the percentage increases in respiratory frequency caused by separate LC stimulation (pink bar) and RM stimulation (blue bar), the sum calculated from the sum of each of these separate stimulations, and the actual increases caused by the simultaneous stimulation of LC and RM. Each dot represents a stimulation experiment. Experiments conducted in the same animals are connected by lines.
After injection of the NK1 receptor antagonist into the pre-BötC (Fig. 7D, second trace), electrical stimulation of either LC or RM nuclei facilitated the respiratory rhythm (Fig. 7D, third and fourth traces).
Electrostimulation of LC or RM blunts inhibitory effects of NK1 receptors. A, Schematic illustrating the experimental protocol for the electrical stimulation of LC (pink bars) and RM (blue bars) in the absence and presence of NK1 antagonist (gray bar). B, C, Stimulation sites of LC (B, pink circles) and RM (C, blue circles) were labeled at the end of each experiment by injecting a high current amplitude into the stimulation electrode (anatomical labeling is indicated by arrows in the histological sections shown in B and C). D, EMG activity obtained from intercostal muscles under control conditions (top trace), during the injection of the NK1 antagonist (second trace), during electrical stimulation of LC while injecting the NK1 antagonist (third trace), and during RM electrical stimulation while injecting the NK1 antagonist (bottom trace).
The respiratory frequency reduced by the NK1 receptor antagonist returned to control levels following stimulation of LC and/or RM (Fig. 8A,B,D,E,G,H). Stimulation of LC and/or RM significantly reduced also the breathing irregularity caused by the NK1 antagonist. However, the regularity of the respiratory rhythm did not fully return to control levels (Fig. 8C,F,I).
Effects of electrical stimulation of LC and/or RM on the frequency and regularity changes caused by NK1 antagonists. A, D, G, The inhibitory effect of the NK1 antagonist on respiratory frequency is abolished by electrical stimulation of LC (A, *p < 0.05; ns, no significance; n = 6), RM (D, *p < 0.05; ns, no significance; n = 6), or both (G, *p < 0.05; ns, no significance; n = 5). B, E, H, Scatter plots illustrating the relationship between percentage change in respiratory frequency (ordinate) and baseline respiratory frequency (abscissa) before manipulating the preparations. The ordinate reflects the percentage change in frequency compared to the control frequency (100%) in any given preparation. Note that electrical stimulation of LC and/or RM significantly reduces the irregularity score caused by the NK1 antagonist, but does not fully recover the regularity when compared to control conditions (C, F, I, *p < 0.05).
Electrical stimulation of LC induces endogenous release of NE and acts on NE receptors presumably in the pre-BötC
To investigate the mechanisms underlying the facilitation of the respiratory rhythm by LC electrical stimulation (Fig. 6), we compared the increase of the respiratory frequency in the presence and absence of NE receptor antagonists. The cocktail injection of NE receptor antagonists (α1 NE antagonist prazosin 30 μm, α2 NE antagonist yohimbine 1 μm, and β NE antagonist alprenolol 30 μm, total 0.6 μl) into the hemilateral pre-BötC decreased the frequency and increased the irregularity score (Fig. 9A,D,E, *p < 0.05, n = 5). Under this condition, further LC stimulation enhanced the respiratory frequency (Fig. 9B). However, the facilitation induced by LC electrical stimulation in the presence of NE antagonists was significantly lower than the facilitation induced in the absence of NE antagonists (Fig. 9F, *p < 0.05, n = 5). These results suggest that tonic activation of α1, α2, and β NE receptors contributes to an increase in respiratory frequency and regularity, that LC stimulation induces endogenous release of NE, and that the endogenous NE release seems to activate NE receptors within the pre-BötC.
Electrical stimulation of LC induces endogenous release of NE and acts on NE receptors presumably within the pre-BötC. A, Integrated EMG activity obtained from intercostal muscle under control conditions (top trace) and following the injection of a cocktail of NE antagonists containing prazosin (30 μm), yohimbine (1 μm), and alprenolol (30 μm, total 0.6 μl, bottom trace). B, EMG activity recorded during LC stimulation under control conditions (top trace) and following the injection of the cocktail containing NE antagonists (bottom trace). C–E, Bar graphs illustrating the effects of NE antagonists on integrated respiratory amplitude (C, ns, n = 5), frequency (D, *p < 0.05), and regularity of respiratory frequency (E, *p < 0.05). F, G, Bar graphs illustrating that LC stimulation (pink bars) affects only respiratory frequency (F, *p < 0.05, n = 5), but not the regularity of the frequency (G, irregularity score, ns) under control conditions (white bars) and following the injection of the cocktail containing NE antagonists (red bars).
Electrical stimulation of RM facilitates endogenous release of 5-HT and activates 5-HT2 receptor in the pre-BötC
To explore the mechanisms underlying the increase of the respiratory rhythm by RM electrical stimulation (Fig. 6), we compared the RM-induced frequency increase in the absence and presence of a 5-HT2 receptor antagonist. The injection of the 5-HT2 receptor antagonist ketanserin (80 μm, 0.6 μl) into the hemilateral pre-BötC decreased the frequency, but did not significantly increase the irregularity score (Fig. 10A,D,E, *p < 0.05, n = 8). Under these conditions, further RM stimulation enhanced the respiratory frequency (Fig. 10B). However, the RM-evoked respiratory facilitation in the presence of the 5-HT2 receptor antagonist was significantly lower than the facilitation evoked in the absence of the antagonist (Fig. 10F, *p < 0.05, n = 8). These results suggest that tonic activation of 5-ΗΤ2 receptor increases respiratory rhythm, that RM stimulation induces the endogenous release of 5-HT, and that endogenous 5-HT release seems to activate 5-HT2 receptors within the pre-BötC.
Electrical stimulation of RM facilitates endogenous release of 5-HT and activates 5-HT2 receptor presumably in the pre-BötC. A, Integrated EMG activity obtained from intercostal muscle under control conditions (top trace) and following the injection of the 5-HT2 antagonist (ketanserin 80 μm, 0.6 μl, bottom trace). B, EMG activity recorded during RM stimulation under control conditions (top trace) and following the injection of ketanserin (bottom trace). C–E, Bar graphs illustrating the effects of ketanserin on integrated EMG amplitude (C, ns, n = 8), frequency (D, *p < 0.05), and regularity of respiratory frequency (E, ns). F, G, Bar graphs illustrating that RM stimulation (blue bars) affects respiratory frequency (F, *p < 0.05, n = 8) and the regularity of the frequency (G, irregularity score, *p < 0.05) under control conditions (white bars) and following the injection of ketanserin (green bars).
Activation of α1 NE receptors or 5-HT2 receptors masks the inhibitory effect of NK1 antagonists on respiratory activity in the slice preparation
Our in vivo data suggested that the modulation of respiratory frequency by endogenous NK1 receptor activation is dependent on the interaction with α1 NE and 5-HT2 receptors (Fig. 5). We next examined whether this is also the case under in vitro conditions. We pharmacologically manipulated these receptors using the NK1 receptor antagonist L733060, the α1 NE receptor agonist cirazoline, and the 5-HT2 receptor agonist DOI. Pretreatment with any of these drugs suppressed the inhibitory effects of the NK1 antagonist (3 μm L733060) on frequency and regularity of the respiratory rhythm (Fig. 11B,C) (ns, n = 5). These results suggest that, also in the reduced slice preparation, the activation of α1 NE and 5-HT2 receptors can mask the effects of endogenous NK1 receptor activation.
Interactions between NK1, α1 NE, and 5-HT2 receptors in slice preparations. A, Integrated activity obtained from population activity recorded extracellularly from the surface of a portion of the VRG containing the pre-BötC. Note the slice exhibited spontaneously normal respiratory activity (small upward deflections) as well as large amplitude deflections that reflect fictive sigh activity (Lieske et al., 2000). Integrated activity was recorded in the presence of the α1 NE agonist cirazoline before (top trace, white bar) and during the application of the NK1 antagonist L733060 (second trace, gray bar), as well as in the presence of the 5-HT2 agonist DOI before (third trace, green bar) and during the application of the NK1 antagonist L733060 (fourth trace, gray bar). B, C, Bar graphs quantifying the effects on frequency (B) and irregularity score (C) under the conditions before (white bars) and during the application of the NK1 antagonist (3 μm L733060; black bars). The bar graphs from left to right illustrate the effects of the NK1 antagonist under control conditions, in the presence of 1 μm cirazoline, 1 μm DOI, and 0.3 μm DOI plus 0.3 μm cirazoline (bar graphs from left to right, *p < 0.05, n = 5).
Discussion
Our study indicates that the dependency of the respiratory rhythm on endogenous SP release and tonic NK1 receptor activation is partly determined by the interaction with other excitatory neuromodulators. Respiration depends on endogenous NK1 receptor activation only at low breathing frequency (<1.5 Hz) or at decreased α1 NE and/or 5-HT2 receptor activation. At high breathing rates (∼2 Hz) or when locus ceruleus or raphe magnus are stimulated, NK1 activation is not essential for regulating breathing frequency.
However, it must be emphasized that respiratory rhythm generation will depend also on numerous other neuromodulators. Endogenously released NE from the A5 region and LC bind both α1 and α2 NE receptors that contribute to respiratory rhythm generation (Hilaire et al., 2004). These nuclei also contain acetylcholine acting on M3 ACh receptors in the pre-BötC (Shao and Feldman, 2005). Serotonin released from RM will also activate 5-HT4 and 5-HT7 receptors known to exert Gs protein-mediated excitatory effects on the respiratory rhythm (Manzke et al., 2003; Kvachnina et al., 2005). RM stimulation might also release CCK and TRH (Ellenberger and Smith, 1999; Hodges and Richerson, 2008). Moreover, orexin originating from hypothalamus might enhance LC and RM activity (Bernard et al., 2003; Tao et al., 2006; Dias et al., 2010). Thus, it is likely that these and many other yet unidentified modulatory actions will contribute to respiratory rhythm generation. To appreciate the complexity of neuromodulation, it is insightful to learn from the elegant studies performed in a small crustacean neuronal network (Nusbaum, 2002; Thirumalai and Marder, 2002; Birmingham et al., 2003; Peck et al., 2006).
We focused on the concurrent modulation of NK1, α1 NE, and 5-HT2 receptors, because all three receptors presumably act on Gq/11 proteins, and possibly converge on common downstream targeted channels. Here, we demonstrated that stimulating LC and RM facilitates release of NE and 5-HT, respectively. These neuromodulators bind to NE and 5-HT2 receptors within the pre-BötC (Figs. 9, 10). The effects caused by stimulating LC and RM were not additive (Fig. 6E), suggesting the involvement of common downstream targets. These targets could include, e.g., TRPM4/5 (Crowder et al., 2007), TRPC3/7 (Ben-Mabrouk and Tryba, 2010), NALCN (leak Na+) (Lu et al., 2009), and TASK (leak K+) channels (Hodges and Richerson, 2008).
The localization and physiological and pharmacological properties of NK1 receptors in the pre-BötC are well established, and NK1 receptor abundance defines the pre-BötC (Gray et al., 1999; Guyenet et al., 2002; Liu et al., 2004; Morgado-Valle and Feldman, 2004; Hayes and Del Negro, 2007; Fong and Potts, 2008). However, in the brainstem SP and NK1 receptors are also expressed in the nucleus of solitary tracts (NTS), raphe nucleus, and nucleus ambiguus (Colin et al., 2002; Guyenet et al., 2002; Léger et al., 2002). These nuclei have connections within the VRG, which includes the pre-BötC (Bianchi et al., 1995; Zec and Kinney, 2003). To reduce the possibility of endogenous SP diffusing from NTS and raphe, we characterized the NK1 effects also in pre-BötC island preparations (Fig. 3). Although, suggestive for a direct pre-BötC effect, SP may be released also from SP-containing active presynaptic terminals from areas including NTS, raphe, or nucleus ambiguus (Guyenet et al., 2002). This applies not only to the island but to all in vitro slices regardless of size and thickness; presynaptic terminals from other areas may still be active and effective. Thus, we cannot exclude the possibility that some effects caused in this study (in vivo and in vitro) were mediated by areas other than the pre-BötC.
Blocking endogenous NK1 activation affected respiratory frequency and regularity. The frequency decreased by ∼30% in response to NK1 antagonists, suggesting that endogenous NK1 activation contributes only partly to the regulation of the respiratory frequency. LC and RM stimulation was capable of restoring the respiratory frequency and also reducing respiratory irregularity in vivo. But, some irregularity remained. By contrast, exogenously applied α1 NE and 5-HT2 agonists were capable of fully restoring respiratory frequency and regularity in vitro. A possible explanation is that LC and RM stimulation caused more complex modulatory effects and the release of different modulators that together could partly oppose the full recovery of the regularity. It could also be that the electrical stimulation of LC and RM was not sufficiently strong to cause sufficient neuromodulator release to fully compensate for the irregularity. However, to avoid unspecific effects, we did not attempt to further increase the current injected into LC and RM. Hence some irregularity remained in the stimulation experiments, while the pharmacological application of specific agonists in the more reduced in vitro network sufficed to fully restore frequency and regularity.
Although, pacemaker and nonpacemaker neurons were not intracellularly recorded in the present study, it is known that substance P (Peña and Ramirez, 2004), serotonin (Peña and Ramirez, 2002), and NE (Viemari and Ramirez, 2006) endogenously modulate respiratory neurons and differentially alter two types of bursting mechanisms described within the pre-Bötzinger complex: bursting that depends on the activation of the calcium-activated nonspecific cation current (ICAN, TRPM4,5) (Peña et al., 2004; Crowder et al., 2007) and bursting that relies on the persistent sodium current (INap) (Del Negro et al., 2002; Peña et al., 2004). These inward currents as well as some outward currents such as the TASK channel are present not only in pacemaker neurons, but also in many nonpacemaker neurons and are thought to contribute to the amplification of synaptic transmission and rhythm generation (Ramirez et al., 1996; Del Negro et al., 2002; Crowder et al., 2007; Koizumi et al., 2010). Following blockade of INap with riluzole, NE causes irregularities and a breakdown of respiratory rhythm generation. By contrast, the respiratory rhythm remains stable following blockade of ICAN (Viemari and Ramirez, 2006). This finding suggests that INap is critical for the modulatory effect on the regularity of the respiratory rhythm. Given that INap-dependent bursting is also modulated by NK1 and 5-HT2A receptor activation (Peña and Ramirez, 2002, 2004; Ramirez et al., 2004), this mechanism could be involved in some of the modulatory effects described in the present study. However, to substantiate this hypothesis, further studies will be necessary that specifically address the convergent endogenous modulation of respiratory nonpacemakers, pacemakers, and their bursting mechanisms. But, it is important to emphasize that the modulatory effects described in the present study are likely more complex.
The electrical stimulation of LC and RM will also activate fibers of passage. Moreover, neurons in LC and RM release not only NE and serotonin, but also other neuromodulators that are colocalized in these neurons. Serotonergic neurons from raphe pallidus, raphe magnus, and raphe obscurus project to the pre-BötC (Paterson et al., 2009), and serotonin colocalizes with SP in presynaptic terminals within the pre-BötC (Hodges and Richerson, 2008; Ptak et al., 2009). 5-HT- and SP-containing neurons in raphe obscurus project and excite neurons in the pre-BötC (Ptak et al., 2009). Indeed, large proportions of 5-HT cell bodies in the raphe region of the lower medulla contain SP (Hökfelt et al., 2000). Thus, if both 5-HT and SP coexist within the broad area of raphe nuclei, it is likely that both molecules may be released not only from raphe obscurus, but also raphe magnus and raphe pallidus. Immunohistological evidence suggests that some substance P in the pre-BötC appears to colocalize with glutamatergic, serotonergic, and also GABAergic presynaptic terminals (Ribeiro-da-Silva and Hökfelt, 2000; Liu et al., 2004).
While generally accepted that NK1 receptor activation is involved in breathing, its relative importance remained uncertain. Newborn NK1 receptor knock-out mice do not exhibit significant changes in the respiratory rhythm (Ptak et al., 2000). In light of the present study, these results are not surprising, since the other excitatory neuromodulators remained presumably active in these mutant mice and were thus able to compensate for the loss of NK1 activation.
Injections aimed at selectively destroying NK1 receptor-immunoreactive (NK1R-ir) neurons using SP-saporin (SP-SAP) had dramatic breathing effects (Gray et al., 2001; Wang et al., 2003; McKay et al., 2005). But this approach lesions NK1R-ir neurons, which eliminates not only NK1R activation, but presumably also the very neurons that receive convergent noradrenergic and serotonergic inputs. Interestingly, when these animals fell asleep, they stopped breathing altogether (McKay et al., 2005; McKay and Feldman, 2008). Our results provide a possible explanation for this state dependency: during sleep, NE and 5-HT activation is low, thus rendering the network more sensitive to the loss of neuromodulatory drive.
Our studies may have also important clinical implications. For example, mutations of the Mafb gene in mice cause respiratory arrest at birth, and result in the loss of approximately one-third of the NK1-positive cells in the pre-BötC (Blanchi et al., 2003). Similar human mutations may be discovered that link respiratory insufficiencies and susceptibilities to sudden infant death syndrome (SIDS) and sleep apnea. In case of SIDS, there is increasing evidence for a role for 5-HT (Paterson et al., 2006; Rand et al., 2007; Broadbelt et al., 2009; Kinney et al., 2009; Duncan et al., 2010). SIDS (and also sleep apnea) occurs predominantly during sleep, when aminergic and presumably also SP levels are reduced. Only in such a reduced modulatory state is the respiratory network critically dependent on an individual neuromodulator, as suggested here for the dependency on SP. In the awake state, it is unlikely that a disruption of a single excitatory neuromodulator will have much of a critical effect, since the modulatory state is relatively high. This may explain why children that later died of SIDS have apparently no breathing problems during the day. Thus, understanding the convergence of different neuromodulators is not only an interesting basic scientific issue, but will also be important for gaining insights into the neurobiology of breathing disorders.
It is well established that gasping critically depends on persistent sodium-dependent pacemaker neurons. This was originally shown in vitro (Peña et al., 2004) and subsequently confirmed in vivo (Paton and St-John, 2007; Peña and Aguileta, 2007). However, whether gasping depends on a single neuromodulator (in this case 5-HT) as suggested by in vitro experiments (Tryba et al., 2006) or on multiple modulators as suggested by an in situ preparation (Toppin et al., 2007) remains unknown. Further studies will be necessary to investigate how the state dependency of these neuromodulatory systems is affected under hypoxic conditions both in vitro and in vivo. Moreover, it will also be important to unravel how gasping, sighs, and apneas are simultaneously controlled by neuropeptides (such as SP) and noradrenergic and serotonergic systems in the intact animal, and how they change during postnatal development (Peña et al., 2008), interesting questions that go beyond the scope of the present study.
Another interesting observation is that conditional KO mice for 5-HT exhibit dramatic respiratory disturbance and excessive mortality when lesioned in neonates (Ptak et al., 2009), while the same manipulation had much less dramatic effects in more mature mice (Ptak et al., 2009). This difference could be explained by the differential maturation of other modulatory systems (Murrin et al., 2007) and/or the respiratory rhythm-generating network (Peña et al., 2008).
Thus, our study emphasizes the importance of considering the convergence of different excitatory neuromodulators when interpreting the outcome of gene knock-outs or when considering the consequences in a patient that is missing one critical neuromodulator. Patients may appear normal during wakefulness, but reveal irregularities at sleep, when modulatory tone is low.
Footnotes
This study was supported by the National Institutes of Health (R01 HL/NS60120; P01 HL090554-01; R01 HL/68860). We thank Dr. Aguan Wei for his wonderful suggestions and editorial comments.
- Correspondence should be addressed to either Dr. Atsushi Doi or Dr. Jan-Marino Ramirez, Center for Integrative Brain Research, Seattle Children's Research Institute, M/S C9S-10 1900 9th Avenue, Seattle, WA 98101. E-mail: atsushi.doi{at}seattlechildrens.org or nino.ramirez{at}seattlechildrens.org
