Ventral Respiratory Group Neurons Research Articles

Dual orexin receptor blocker suvorexant attenuates hypercapnic ventilatory augmentation in mice

Suvorexant (Belsomra(R)), a dual orexin receptor antagonist widely used in the treatment of insomnia, inhibits the arousal system in the brain. However, the drug’s ventilatory effects have not been fully explored. This study aims to investigate the expression of orexin receptors in respiratory neurons and the effects of suvorexant on ventilation. Immunohistology of brainstem orexin receptor OX2R expression was performed in adult mice (n = 4) in (1) rostral ventral respiratory group (rVRG) neurons projecting to the phrenic nucleus (PhN) retrogradely labeled by Fluoro-Gold (FG) tracer, (2) neurons immunoreactive for paired like homeobox 2b (Phox2b) in the parafacial respiratory group/retrotrapezoid nucleus (pFRG/RTN), and (3) neurons immunoreactive for neurokinin 1 receptor (NK1R) and somatostatin (SST) in the preBötzinger complex (preBötC). Additionally, we measured in vivo ventilatory responses to hyperoxic hypercapnia (5% CO2) and hypoxia (10% O2) before and after suvorexant pretreatment (10 and cumulative 100 mg/kg) in unrestrained mice (n = 10) in a body plethysmograph. We found the OX2R immunoreactive materials in pFRG/RTN Phox2b and preBötC NK1R/SST immunoreactive neurons but not in FG-labeled rVRG neurons, which suggests the involvement of orexin in respiratory control. Further, suvorexant expressly suppressed the hypercapnic ventilatory augmentation, otherwise unaffecting ventilation. Central orexin is involved in shaping the hypercapnic ventilatory chemosensitivity. Suppression of hypercapnic ventilatory augmentation by the orexin receptor antagonist suvorexant calls for caution in its use in pathologies that may progress to hypercapnic respiratory failure, or sleep-disordered breathing. Clinical trials are required to explore the role of targeted pharmacological inhibition of orexin in ventilatory pathologies.

Large scale neural dynamics of breathing in‐vivo and in‐vitro

The neural control of breathing involves the coordinated activity of populations of medullary neurons distributed along the rostrocaudal aspect of the ventrolateral medulla: the so called Ventral Respiratory Group (VRG). The VRG consists of genetically diverse and anatomically distributed populations of neurons that form interconnected microcircuits necessary for the maintenance of the respiratory rhythm and the recruitment of respiratory muscles. Additionally, the VRG is subject to modulation from extra-medullary centers as well as feedback from ascending afferents. Together, the VRG is capable of robust, yet labile, generation of respiration. This generation arises from the dynamic coordination of VRG neurons, but how the activity of these neurons is coordinated across the VRG in-vivo remains poorly understood. Here, we use cutting edge electrophysiological recording techniques (Neuropixels) to record simultaneously from hundreds of neurons across the VRG in anesthetized mice and horizontal slices in vitro. We couple this with an optogenetic tagging approach to determine the genetic identity of a subset of the recorded neurons. We find inspiratory and expiratory related neurons distributed throughout the VRG, with higher proportions of expiratory neurons than expected from in-vitro studies. Moreover, correlated activity across simultaneously recorded neurons uncovers dynamically coordinated ensembles of neurons that define “cell assemblies”. These cell assemblies give rise to discretely different patterns of respiratory activity, including specific, distributed populations recruited during hypoxia induced gasping. Together, these data provide an integrated view of the dynamic coordination of neural activity driving breathing in the intact animal.

AAV2-BDNF promotes respiratory axon plasticity and recovery of diaphragm function following spinal cord injury.

More than half of spinal cord injury (SCI) cases occur in the cervical region, leading to respiratory dysfunction due to damaged neural circuitry that controls critically important muscles such as the diaphragm. The C3-C5 spinal cord is the location of phrenic motor neurons (PhMNs) that are responsible for diaphragm activation; PhMNs receive bulbospinal excitatory drive predominately from supraspinal neurons of the rostral ventral respiratory group (rVRG). Cervical SCI results in rVRG axon damage, PhMN denervation, and consequent partial-to-complete paralysis of hemidiaphragm. In a rat model of C2 hemisection SCI, we expressed the axon guidance molecule, brain-derived neurotrophic factor (BDNF), selectively at the location of PhMNs (ipsilateral to lesion) to promote directed growth of rVRG axons toward PhMN targets by performing intraspinal injections of adeno-associated virus serotype 2 (AAV2)-BDNF vector. AAV2-BDNF promoted significant functional diaphragm recovery, as assessed by in vivo electromyography. Within the PhMN pool ipsilateral to injury, AAV2-BDNF robustly increased sprouting of both spared contralateral-originating rVRG axons and serotonergic fibers. Furthermore, AAV2-BDNF significantly increased numbers of putative monosynaptic connections between PhMNs and these sprouting rVRG and serotonergic axons. These findings show that targeting circuit plasticity mechanisms involving the enhancement of synaptic inputs from spared axon populations is a powerful strategy for restoring respiratory function post-SCI.-Charsar, B. A., Brinton, M. A., Locke, K., Chen, A. Y., Ghosh, B., Urban, M. W., Komaravolu, S., Krishnamurthy, K., Smit, R., Pasinelli, P., Wright, M. C., Smith, G. M., Lepore, A. C. AAV2-BDNF promotes respiratory axon plasticity and recovery of diaphragm function following spinal cord injury.

In vivo Studies of Brainstem Neurons with Respiratory Rhythm Activity in a Rat Model of Rett Syndrome

People with Rett Syndrome (RTT), a neurodevelopmental disorder caused by mutations of the MECP2 gene, show breathing abnormalities that are attributable to the high incidence of sudden death. To understand the underlying mechanisms for the breathing disorders, direct in vivo recordings from brainstem neurons with respiratory rhythm are needed, which is a challenge in mouse RTT models. The newly available rat model may allow such a study. Therefore, we performed electrophysiological recording from individual neurons of the medullary ventral respiratory group (VRG) in decerebrate Mecp2‐null and wild‐type (WT) rats. In both groups of rats, neurons with expiratory rhythm were recorded from the rostral and caudal VRG, and cells with inspiratory rhythm were found in between. Firing frequency of the inspiratory neurons was significantly lower in null rats than in WT rats, while expiratory neurons in both rostral and caudal VRG did not show such a difference. Firing durations of both expiratory and inspiratory neurons were elongated in null rats compared with the WT. The ratio of inspiratory to expiratory firing duration (Ti/Te) was lower in null rats. A large number of cells showed E‐I phase‐spanning in null rats. The null rats had a frequent breathing pattern of apneusis followed by apnea, during which inspiratory neurons showed increased firing frequency and caudal expiratory neurons showed decreased firing frequency, whereas no significant change was observed in rostral expiratory neurons. Although this breathing pattern of apneusis followed by apnea was also seen in WT rats, the firing frequency of either respiratory neurons did not seem to change. These findings suggest that Mecp2 disruption appears to cause a large scale of changes in firing activity and pattern of medullary respiratory neurons consistent with the broad range of breathing abnormalities seen in people with RTT and animal models.Support or Funding InformationThis work was supported by NIH grant R01‐NS‐073875 and International Rett Syndrome Foundation.

Atomic force microscopy to characterize binding properties of α7‐containing nicotinic acetylcholine receptors on neurokinin‐1 receptor‐expressing medullary respiratory neurons

In the present study, we used atomic force microscopy (AFM) to examine the ligand-binding properties of α7-containing nicotinic acetylcholine receptors (nAChRs) expressed on neurons from the ventral respiratory group. We also determined the effect of acute and prolonged exposure to nicotine on the binding probability of nAChRs. Neurons from neonatal (postnatal day 5-10) and juvenile rats (3-4 weeks old) were cultured. Internalization of Alexa Fluor 488-conjugated substance P was used to identify respiratory neurons that expressed the neurokinin-1 receptor (NK1-R), a recognized marker of ventral respiratory group neurons. To assess functional changes in nAChRs, AFM probes conjugated with anti-α7 subunit nAChR antibody were used to interact cyclically with the surface of the soma of NK1-R-positive neurons. Measurements were made of the frequency of antibody adhesion to the α7 receptor subunit and of the detachment forces between the membrane-attached receptor and the AFM probe tip. Addition of α-bungarotoxin (a specific antagonist of α7 subunit-containing nAChRs) to the cell bath produced a 69% reduction in binding to the α7 subunit (P < 0.05, n = 10), supporting specificity of binding. Acute exposure to nicotine (1 μM added to culture media) produced an 80% reduction in nAChR antibody binding to the α7 subunit (P < 0.05, n = 9). Prolonged incubation (72 h) of the cell culture in nicotine significantly reduced α7 binding in a concentration-dependent manner. Collectively, these findings demonstrate that AFM is a sensitive tool for assessment of functional changes in nAChRs expressed on the surface of living NK1-R-expressing medullary neurons. Moreover, these data demonstrate that nicotine exposure decreases the binding probability of α7 subunit-containing nAChRs.

Reelin demarcates a subset of pre‐Bötzinger complex neurons in adult rat

Identification of two markers of neurons in the pre-Bötzinger complex (pre-BötC), the neurokinin 1 receptor (NK1R) and somatostatin (Sst) peptide, has been of great utility in understanding the essential role of the pre-BötC in breathing. Recently, the transcription factor dbx1 was identified as a critical, but transient, determinant of glutamatergic pre-BötC neurons. Here, to identify additional markers, we constructed and screened a single-cell subtractive cDNA library from pre-BötC inspiratory neurons. We identified the glycoprotein reelin as a potentially useful marker, because it is expressed in distinct populations of pre-BötC and inspiratory bulbospinal ventral respiratory group (ibsVRG) neurons. Reelin ibsVRG neurons were larger (27.1 ± 3.8 μm in diameter) and located more caudally (>12.8 mm caudal to Bregma) than reelin pre-BötC neurons (15.5 ± 2.4 μm in diameter, <12.8 mm rostral to Bregma). Pre-BötC reelin neurons coexpress NK1R and Sst. Reelin neurons were also found in the parahypoglossal and dorsal parafacial regions, pontine respiratory group, and ventromedial medulla. Reelin-deficient (Reeler) mice exhibited impaired respones to hypoxia compared with littermate controls. We suggest that reelin is a useful molecular marker for pre-BötC neurons in adult rodents and may play a functional role in pre-BötC microcircuits.

Identification of NO/sGC signalling in the bulbospinal respiratory pathway after C2–C3 hemisection of the spinal cord in rats

Guanylyl cyclase (GC) as the effector molecule for nitric oxide (NO) plays a key role in the NO/cGMP signalling cascade. Based on these observations, our study focused on NO/sGC signalization in the bulbospinal respiratory pathway. The distribution of neuronal nitric oxide synthase (nNOS), β1 subunit of soluble guanylyl cyclase (β1sGC) and synaptophysin (SYN) was explored in the upper part of the respiratory pathway after C2–C3 hemisection of the spinal cord in male Wistar rats. Unilateral injection of Fluorogold into the phrenic nucleus (PN) at C4 level and survival of animals for 2 days revealed many Fluorogold fluorescent neurons in the ventral respiratory group (VRG) of the medulla, mostly on the contralateral side. Under physiological conditions we noted nNOS-fluorescent terminals of VRG neurons around β1sGC fluorescent motoneurons in the PN. A strong depletion of nNOS/SYN fluorescent terminals was noted 8 days after hemisection around alpha motoneurons in the PN on the contralateral side. On the side of injury, nNOS/SYN fluorescent puncta were detected around phrenic motoneurons only sporadically. Phrenic alpha motoneurons responded to C2–C3 hemisection by a loss of β1sGC positivity. The results confirm, that β1sGC immunoreactive phrenic motoneurons are innervated by nNOS positive terminals coming from the VRG.

Effects of treadmill running exercise on neuronal expression of c-Fos protein in the medulla oblongata after unilateral phrenicotomy in Wistar rats

The purpose of this study was to examine whether treadmill running exercise after phrenicotomy resulted in change in neuronal expression of c-Fos protein in the medulla oblongata in Wistar rats. All rats were subjected to left-sided unilateral phrenicotomy. In test experiments, rats were trained with treadmill running for 4 weeks, while in control experiments rats were not provided with the opportunity to exercise. c-Fos protein, a transient transcription factor, was immunohistochemically stained by the ABC method, and surveyed in the medulla oblongata. Numbers of c-Fos-immunoreactive (c-Fos-ir) neurons were counted microscopically, and their distribution in the medulla oblongata was mapped. In the dorsal respiratory group (DRG), numbers of c-Fos-ir neurons were found to be significantly increased in the test rats compared with control rats, while in the ventral respiratory group (VRG) no significant differences were found in numbers of c-Fos-ir neurons between test and control rats. These findings suggest that DRG neurons may play more important roles than VRG neurons in recovery of respiration in treadmill exercise after unilateral phrenicotomy in Wistar rats.

Endogenous activation of neurokinin‐1 receptor (NK1R) expressing ventral respiratory group (VRG) neurons by somatic afferent stimulation

Previous work from our laboratory has demonstrated that: 1) exogenous activation of NK1Rs increased the firing rate of functionally-identified VRG neurons (Fong and Potts, 2004); and 2) somatic afferent stimulation excited augmenting expiratory neurons (Eaug, Potts et al., 2005). The aim of the current study was to examine the role of endogenous activation of NK1Rs on inspiratory- (I) and expiratory-(E) related VRG neurons. Using the in situ arterially-perfused rat preparation, we used multibarrel microelectrodes to record extracellular activity from 32 VRG neurons during electrically-evoked muscle contraction. Muscle contraction inhibited I (6/12) and post-inspiration (post-I, 7/7) neurons when the stimulus was delivered during its normal firing phase. In contrast, the firing rate of Eaug (5/6) and pre-inspiratory (Pre-I, 3/5) neurons was increased when somatic stimulation was delivered during late-expiration (E2 phase). To determine whether contraction-evoked changes in firing rate of VRG neurons was mediated by endogenous release of substance P, the NK1R antagonist CP99,994 (10mM) was picoejected onto 13 of 32 VRG neurons. NK1R blockade had no effect on contraction-evoked inhibition of I (3/3) or post-I (4/4) neurons. However, CP99,994 attenuated contraction-induced excitation of E2 (2/3) by 60% and Pre-I (2/3) by 50 percent. NK1R blockade reduced basal firing rate in only 1 of 6 neurons. These data suggest that endogenous activation of NK1R by contraction-sensitive somatic afferents modulates the excitability of E2 and Pre-I neurons. This work was supported by NIH grant HL059167 (JTP).

Lack of the Kir4.1 Channel Subunit Abolishes K+ Buffering Properties of Astrocytes in the Ventral Respiratory Group: Impact on Extracellular K+ Regulation

Ongoing rhythmic neuronal activity in the ventral respiratory group (VRG) of the brain stem results in periodic changes of extracellular K+. To estimate the involvement of the weakly inwardly rectifying K+ channel Kir4.1 (KCNJ10) in extracellular K+ clearance, we examined its functional expression in astrocytes of the respiratory network. Kir4.1 was expressed in astroglial cells of the VRG, predominantly in fine astrocytic processes surrounding capillaries and in close proximity to VRG neurons. Kir4.1 expression was up-regulated during early postnatal development. The physiological role of astrocytic Kir4.1 was studied using mice with a null mutation in the Kir4.1 channel gene that were interbred with transgenic mice expressing the enhanced green fluorescent protein in their astrocytes. The membrane potential was depolarized in astrocytes of Kir4.1-/- mice, and Ba2+-sensitive inward K+ currents were diminished. Brain slices from Kir4.1-/- mice, containing the pre-Bötzinger complex, which generates a respiratory rhythm, did not show any obvious differences in rhythmic bursting activity compared with wild-type controls, indicating that the lack of Kir4.1 channels alone does not impair respiratory network activity. Extracellular K+ measurements revealed that Kir4.1 channels contribute to extracellular K+ regulation. Kir4.1 channels reduce baseline K+ levels, and they compensate for the K+ undershoot. Our data indicate that Kir4.1 channels 1) are expressed in perineuronal processes of astrocytes, 2) constitute the major part of the astrocytic Kir conductance, and 3) contribute to regulation of extracellular K+ in the respiratory network.

Ionotropic glutamate receptors mediate excitatory drive to caudal medullary expiratory neurons in the rabbit

Most of the neurons of the caudal ventral respiratory group (cVRG) are bulbospinal expiratory neurons that receive their main excitatory drive from more rostral, but not yet defined regions. This study was devoted to investigate the functional role of ionotropic excitatory amino acid (EAA) receptors in the excitatory drive transmission to cVRG expiratory neurons during eupnoeic breathing and some respiratory reflexes including cough induced by mechanical stimulation of the tracheobronchial tree. The experiments were performed on spontaneously breathing rabbits under pentobarbitone anesthesia making use of microinjections (30–50 nl) of EAA receptor antagonists into the cVRG. Phrenic nerve and abdominal muscle activities were recorded. Bilateral microinjections of 50 mM kynurenic acid (KYN), a broad-spectrum EAA antagonist, and 10 mM 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), a non-NMDA antagonist, or 5 mM 6-nitro-7-sulphamoylbenzo(f)quinoxaline-2,3-dione (NBQX), a more specific non-NMDA antagonist, completely suppressed spontaneous rhythmic abdominal activity and reflex expiratory responses either to tracheal occlusion at end-inspiration (Breuer–Hering inflation reflex) or to expiratory threshold loading (5 cm H 2O); they also suppressed both the inspiratory and expiratory components of the cough reflex. Spontaneous rhythmic abdominal activity and the reflex respiratory responses were strongly reduced, but not completely abolished by microinjections of 10 mM d(−)-2-amino-5-phosphonopentanoic acid (D-AP5), an NMDA antagonist. The results provide evidence that the excitatory drive to cVRG bulbospinal expiratory neurons during eupnoeic breathing and the investigated respiratory reflexes is mediated by EAA receptors. They also support the view that neurons located in the cVRG are not merely elements of the expiratory output system.

Ultrastructure of the rostral ventral respiratory group neurons in the ventrolateral medulla of the rat

The neurons in the ventrolateral medulla that project to the spinal cord are called the rostral ventral respiratory group (rVRG) because they activate spinal respiratory motor neurons. We retrogradely labeled rVRG neurons with Fluoro-Gold (FG) injections into the fourth cervical spinal cord segment to determine their distribution. The rostral half of the rVRG was located in the area ventral to the semicompact formation of the nucleus ambiguus (AmS). A cluster of the neurons moved dorsally and intermingled with the palatopharyngeal motor neurons at the caudal end of the AmS. The caudal half of the rVRG was located in the area including the loose formation of the nucleus ambiguus caudal to the AmS. We also labeled the rVRG neurons retrogradely with wheat germ agglutinin–horseradish peroxidase (WGA–HRP) to determine their ultrastructural characteristics. The neurons of the rVRG were medium to large (38.1×22.1 μm), oval or ellipsoid in shape, and had a dark cytoplasm containing numerous free ribosomes, rough endoplasmic reticulum (rER), mitochondria, Golgi apparatuses, lipofuscin granules and a round nucleus with an invaginated nuclear membrane. The average number of axosomatic terminals in a profile was 33.2. The number of axosomatic terminals containing round vesicles and making asymmetric synaptic contacts (Gray's type I) was almost equal to those containing pleomorphic vesicles and making symmetric synaptic contacts (Gray's type II). The axodendritic terminals were large (1.55 μm), and about 60% of them were Gray's type I. The rVRG neurons have ultrastructural characteristics, which are different from the palatopharyngeal motor neurons or the prorpiobulbar neurons.

Presynaptic Δ opioid receptors differentially modulate rhythm and pattern generation in the ventral respiratory group of the rat

The specific role of the Δ opioid receptor (DOR), in opioid-induced respiratory depression in the ventral respiratory group (VRG) is largely unknown. Here, we sought to determine (1) the relationship between DOR-immunoreactive (ir) boutons, bulbospinal and functionally identified respiratory neurons in the VRG and (2) the effects of microinjection of the selective DOR agonist, d-Pen 2,5-enkephalin (DPDPE), into different subdivisions of the VRG, on phrenic nerve discharge and mean arterial pressure. Following injections of retrograde tracer into the spinal cord or intracellular labelling of respiratory neurons, in Sprague-Dawley rats, brainstem sections were processed for retrograde or intracellular labelling and DOR-ir. Bulbospinal neurons were apposed by DOR-ir boutons regardless of whether they projected to single (cervical or thoracic ventral horn) or multiple (cervical and thoracic ventral horn) targets in the spinal cord. In the VRG, a total of 24±5% (67±13/223±49) of neurons projecting to the cervical ventral horn, and 37±3% (96±22/255±37) of neurons projecting to the thoracic ventral horn, received close appositions from DOR-ir boutons. Furthermore, DOR-ir boutons closely apposed six of seven intracellularly labelled neurons, whilst the remaining neuron itself possessed boutons that were DOR-ir. DPDPE was microinjected (10 mM, 60 nl, unilateral) into regions of respiratory field activity in the VRG of anaesthetised, vagotomised rats, and the effects on phrenic nerve discharge and mean arterial pressure were recorded. DPDPE depressed phrenic nerve amplitude, with little effect on phrenic nerve frequency in the Bötzinger complex, pre-Bötzinger complex and rVRG, the greatest effects occurring in the Bötzinger complex. The results indicate that the DOR is located on afferent inputs to respiratory neurons in the VRG. Activation of the DOR in the VRG is likely to inhibit the release of neurotransmitters from afferent inputs that modulate the pattern of activity of VRG neurons.

Distribution of μ receptors in the ventral respiratory group neurons; immunohistochemical and pharmacological studies in decerebrate cats

Immunoreactivity for μ receptors was investigated in 21 bulbar respiratory neurons, individually identified by intracellular recording and labeling with neurobiotin. In 14 of these neurons, effects of iontophoresed morphine were examined. Morphine hyperpolarized the membrane and decreased spike discharges in 4/6 augmenting inspiratory (aug-I), 4/5 postinspiratory (post-I) and 3/3 augmenting expiratory (aug-E) neurons. It had no effect on two aug-I and one post-I neurons. Strong immunoreactivity for μ receptor was detected in the soma and dendrites of 5/8 aug-I, 5/7 post-I and 6/6 aug-E neurons. In the remaining three aug-I and two post-I neurons that included cells unresponsive to morphine, weak immunoreactivity was detected only in the dendrites. These results demonstrated wide, but uneven, distribution of μ receptors in bulbar respiratory neurons and suggest their contribution to respiratory depression by opioids.

Cardiorespiratory neurons of the rat ventrolateral medulla contain TASK-1 and TASK-3 channel mRNA.

The potassium channels TASK-1 and TASK-3 are neuronal 'leak' channels that are inhibited by extracellular acidification and numerous neurotransmitters. Here we tested whether in the rat TASK-1 and TASK-3 mRNAs are present in ventrolateral medulla neurons that regulate respiration or circulation (C1 adrenergic neurons). The mRNAs were identified by in situ hybridization. Respiratory neurons were identified by anatomical markers (neurokinin-1 receptors, NK1R, or somatostatin) or directly by juxtacellular labeling of bulbospinal neurons. C1 neurons were identified by the presence of tyrosine-hydroxylase. TASK-1 and TASK-3 transcripts were present in all hypoglossal and facial motor neurons, in most C1 cells (85-95%), in most small and large NK1R-ir neurons (>90%) of the ventral respiratory group (VRG) and in all the inspiratory-augmenting bulbospinal neurons of the rostral ventral respiratory group. In conclusion, TASK channels are expressed by respiratory cells with putative rhythmogenic function and by premotor and motor neurons. TASK channels presumably mediate excitatory effects of numerous transmitters on these neurons and may contribute to their pH-sensitivity.

Response of the respiratory network of mice to hyperthermia.

Most mammals modulate respiratory frequency (RF) to dissipate heat (i.e., panting) and avoid heat stroke during hyperthermic conditions. During hyperthermia, the RF of intact mammals increases and then declines or ceases (apnea). It has been proposed that this RF modulation depends on the presence of higher brain structures such as the hypothalamus. However, the direct effects of hyperthermia on the respiratory neural network have not been examined. To address this issue, the respiratory neural network [i.e., ventral respiratory group (VRG)] was isolated in a brain stem preparation taken from the medulla of mice (P0 -P6). Integrated population activity, predominated by inspiratory neurons, was recorded extracellularly from VRG neurons. The bath temperature was then heated from 30 to 40 degrees C, resulting in a biphasic frequency response in VRG activity. Following an initial six- to sevenfold increase and subsequent decline, fictive RF was maintained at a frequency that was higher than baseline frequency; at 40 degrees C, the RF was maintained at about two to four times that at 30 degrees C. The inspiratory burst amplitude and duration were significantly reduced during hyperthermic conditions. An increase in RF and decrease in VRG burst amplitude and duration also occurred when heating from 37 to 40 degrees C. Fictive apnea typically occurred during cooling to the control temperature. Furthermore, changes in hypoglossal motor nucleus activity paralleled those of the VRG, suggesting that temperature modulation of the VRG is likely to have a behaviorally relevant impact on respiration. We conclude that the VRG activity itself is modulated during hyperthermia and the respiratory network is particularly sensitive to temperature changes.

Differential Processing of Excitation by GABAergic Gain Modulation in Canine Caudal Ventral Respiratory Group Neurons

The discharge frequency (F(n)) patterns of medullary respiratory premotor neurons are subject to potent tonic GABAergic gain modulation. Studies in other neuron types suggest that the synaptic input for tonic inhibition is located on the soma where it can affect total neuronal output. However, our preliminary data suggested that excitatory responses elicited by highly local application of glutamate receptor agonists are not gain modulated. In addition, modulation of the amplitude of spike afterhyperpolarizations can gain modulate neuronal output, and this mechanism is located near the spike initiation zone and/or soma. The purpose of this study was to determine if these two gain-modulating mechanisms have different functional locations on the somatodendritic membrane of bulbospinal inspiratory and expiratory neurons. Four-barrel micropipettes were used for extracellular single-neuron recording and pressure ejection of drugs in decerebrate, paralyzed, ventilated dogs. The net increases in F(n) due to repeated short-duration picoejections of the glutamate receptor agonist, alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA), was quantified before and during locally induced antagonism of GABA(A) receptors by bicuculline or small-conductance, calcium-activated potassium channels by apamin. The AMPA-induced net increases in F(n) were not significantly altered by BIC, although it produced large increases in the respiratory-related activity. However, the AMPA-induced net responses were amplified in accordance with the gain increase of the respiratory-related activity by apamin. These findings suggest that GABAergic gain modulation may be functionally isolated from the soma/spike initiation zone, e.g., located on a dendritic shaft. This could allow other behavioral signals requiring strong neuronal activation (e.g., coughing, sneezing, vomiting) to utilize the same neuron without being attenuated by the GABAergic modulation.

Inspiratory augmenting bulbospinal neurons express both glutamatergic and enkephalinergic phenotypes.

Many of the inspiratory augmenting (I-AUG) neurons of the rostral ventral respiratory group (rVRG) are premotor neurons that excite phrenic motor neurons during inspiration, probably by releasing glutamate. In the present study, we demonstrate that these neurons are indeed glutamatergic, in that their cell bodies contain vesicular glutamate transporter-2 (VGLUT2) mRNA and spinal terminals from neurons in the region of the rVRG contain VGLUT2 protein. We also demonstrate by using parallel in situ hybridization and immunocytochemical evidence that most rVRG inspiratory premotor neurons are enkephalinergic. After iontophoretic deposits of biotinylated dextran amine (BDA) in the area of the rVRG, many BDA-labeled terminals in the ventral horn of cervical spinal cord (C4-C5) were immunoreactive for enkephalin and VGLUT2. Injections of Fluoro-Gold amidst phrenic motor neurons in C4-C5 labeled neurons in the area of the rVRG that contained both VGLUT2 mRNA and preproenkephalin (PPE) mRNA as revealed by double in situ hybridization. Thirty-eight bulbospinal I-AUG neurons were recorded in the rVRG and filled with biotinamide by using the juxtacellular labeling technique. Every biotinamide-filled cell tested was positively labeled for VGLUT2 mRNA (n = 14), and most of the cells tested in a separate population exhibited PPE mRNA (16/18). We conclude that most of the phrenic inspiratory premotor neurons of the rVRG are glutamatergic neurons that may also release enkephalins.

Effects of lignocaine blockades and kainic acid lesions in the Bötzinger complex on spontaneous expiratory activity and cough reflex responses in the rabbit

We investigated the role played by Bötzinger complex (Böt. c.) region in the genesis of the cough reflex and expiratory drive to expiratory neurons of the caudal ventral respiratory group (cVRG) in pentobarbitone-anesthetized spontaneously breathing rabbits. Phrenic nerve and abdominal muscle activities were monitored. Microinjections (30–50 nl) of 4% lignocaine or 4.7 mM kainic acid in the Böt. c. region suppressed spontaneous rhythmic expiratory activity as well as the inspiratory and expiratory components of the cough reflex evoked by mechanical stimulation of the tracheobronchial tree. These results support the view that neurons located in the Böt. c. have an important role not only in the genesis of the synaptic drive to cVRG expiratory neurons, but also in determining the overall characteristics of the cough motor pattern.

Neurokinin-1 receptor-expressing cells of the ventral respiratory group are functionally heterogeneous and predominantly glutamatergic.

According to a recent theory (Gray et al., 1999) the neurokinin-1 receptor (NK1R)-immunoreactive (ir) neurons of the ventral respiratory group (VRG) are confined to the pre-Bötzinger complex (pre-BötC) and might be glutamatergic interneurons that drive respiratory rhythmogenesis. In this study we tested whether the NK1R-ir neurons of the VRG are glutamatergic. We also examined whether different groups of NK1R-ir neurons coexist in the VRG on the basis of whether these cells contain preproenkephalin (PPE) mRNA or project to the spinal cord. NK1R immunoreactivity was found in two populations of VRG neurons that are both predominantly glutamatergic because most of them contained vesicular glutamate transporter 2 mRNA (77 +/- 9%; n = 3). A group of small fusiform neurons (somatic cross section: 91 +/- 3.6 microm2) that has neither PPE mRNA nor spinal projections is primarily restricted to the pre-BötC. These cells may be the interneurons the destruction of which produces massive disruptions of the respiratory rhythm (Gray et al., 2001). The rest of the NK1R-ir neurons of the VRG are multipolar, are larger (somatic cross section: 252 +/- 15 microm2), and express high levels of PPE mRNA. Some of these cells located in the rostral half of the rostral VRG project to the spinal cord (C4 or T3). Using electrophysiological methods, we showed that these bulbospinal NK1R-ir neurons are slowly discharging inspiratory-augmenting neurons, suggesting that they may control phrenic or intercostal motor neurons. In summary, NK1R-expressing cells of the VRG are a heterogeneous group of predominantly glutamatergic neurons that include subpopulations of respiratory premotor neurons.