Monoaminergic and GABAergic terminations in phrenic nucleus of rat identified by immunohistochemical labeling

Close appositions between tyrosine hydroxylase immunoreactive boutons and respiratory neurons in the rat ventrolateral medulla

The extent of the adrenergic input to respiratory neurons in the ventrolateral medulla oblongata of rats was assessed by using a combination of intracellular recording, dye filling, and immunohistochemistry. Twenty-two neurons that displayed a pronounced respiration-related modulation of their membrane potential, and could not be antidromically activated by electrical stimulation of the superior laryngeal, vagus, or facial nerves, were labelled by intracellular injection of biocytin. Three types of respiration-related neurons were labelled: small neurons located in the Bötzinger complex between 0.5 and 1.0 mm caudal to the facial nucleus; medium-sized neurons located in the ventral respiratory group 1.0 to 2.0 mm caudal to the facial nucleus; and large motoneurons located within the nucleus ambiguus 0.5 to 2.0 mm caudal to the facial nucleus. Small Bötzinger neurons [length = 22 +/- 5 microns, width = 13 +/- 3 microns, area = 222 +/- 79 microns2; (mean +/- SD, n = 5)] had membrane potentials of -15 to -27 mV during the recording period. Four of five of these cells had profuse axonal terminations between 50 microns caudal and 450 microns rostral to their somata, suggesting that they may form part of local networks responsible for generating respiratory activity. Medium-sized ventral respiratory group neurons (length = 26 +/- 5 microns, width = 18 +/- 4 microns, area = 377 +/- 141 microns2; n = 5) were found in the vicinity of the nucleus ambiguus dorsal to the lateral reticular nucleus. Three of five of these neurons had an axon that crossed the midline and travelled caudally. One axon had a collateral with varicosities close to its soma. The somata of motoneurons (length = 29 +/- 6 microns, width = 21 +/- 4 microns, area = 485 +/- 142 microns2; n = 12) were located within the nucleus ambiguus, and had axons that could be traced to exist points from the medulla. Tyrosine hydroxylase immunoreactive cells and their terminal fibres within the medulla were localised by immunocytochemistry. Small Bötzinger neurons received the largest number of close appositions from tyrosine hydroxylase immunoreactive boutons (13 +/- 2 appositions/neuron; n = 5). Medium-sized ventral respiratory group neurons received fewer appositions (8 +/- 4 appositions/neuron; n = 5). Most motoneurons (n = 10) received few appositions from tyrosine hydroxylase immunoreactive boutons, while two received none. The average number was 3 +/- 3 appositions/neuron (n = 12).(ABSTRACT TRUNCATED AT 400 WORDS)

Serotonin reveals ineffective spinal pathways to contralateral phrenic motoneurons in spinally hemisected rats

Serotonin reveals ineffective (subthreshold) pathways from the C2 lateral funiculus to ipsilateral phrenic motoneurons in spinalized rats. The objective of the present study was to investigate serotonergic modulation of crossed-spinal pathways to contralateral phrenic motoneurons. Rats (n = 10) were anesthetized (urethane), paralyzed, vagotomized, and artificially ventilated. The spinal cord was hemisected at C1-C2 and, on the intact side, a tungsten stimulating electrode was placed ventral to the C2 dorsal root entry zone in the dorsolateral (approximately 1.1 mm) or the ventrolateral funiculus (approximately 2.2 mm depth). Single shocks (100-750 microA, 0.1-0.5 ms, 2 Hz) elicited a short-latency (approximately 1.0 ms to peak) excitation in the ipsilateral phrenic nerve, but usually evoked little or no response in the contralateral phrenic nerve at either stimulus site. Following systemic injection of the monoamine oxidase inhibitor pargyline (25 mg/kg) and the serotonin precursor 5-hydroxytryptophan (5-10 mg/kg), complex responses were revealed in the contralateral phrenic nerve, including: (1) spontaneous tonic activity; (2) a short-latency (approximately 1.0 ms to peak) evoked excitation; and (3) two long-latency (approximately 2.2 and 7.8 ms to peak) evoked excitations. The longest latency excitation was expressed only when the stimulating electrode was positioned in the dorsolateral funiculus. Contralateral evoked responses were blocked by systemic methysergide (2-6 mg/kg), a broad-spectrum serotonin receptor antagonist. These results indicate that serotonin converts ineffective crossed phrenic pathways in the spinal cord to effective pathways. It remains to be determined whether serotonin is both necessary and sufficient in this modulatory process, or if it is a nonspecific result of increased phrenic motoneuron excitability.

Galanin immunoreactivity in rat spinal lamina IX: emphasis on sexually dimorphic regions

Fibers and puncta that contained galanin-like immunoreactivity (GAL-LI) were distributed within lamina IX in a heterogeneous fashion. In cervical spinal segments, GAL-LI was almost absent except for the phrenic nucleus, which received the most robust GAL-LI innervation in lamina IX. In high and mid-thoracic segments, GAL-LI was found in moderate amounts, but the number of GAL-LI fibers gradually diminished in a caudal fashion, so that in low thoracic segments GAL-LI was sparse. Throughout all thoracic segments, GAL-LI fibers surrounded some clusters of motoneurons, while other groups of motoneurons were devoid of GAL-LI fibers. In lumbar segments, three sexually dimorphic nuclei received sparse to moderate amounts of GAL-LI, while GAL-LI in the remainder of lumbar lamina IX was very sparse. In sacral spinal segments, GAL-LI was very sparse. These data indicate that fibers and puncta that contain GAL-LI preferentially surround motoneurons that innervate muscles associated with the axial skeleton, while motoneurons that innervate appendicular or tail-associated skeletal muscles only have an occasional GAL-LI fiber associated with them.

Effects of GABAB receptor agonists and antagonists on the bulbar respiratory network in cat

We examined the involvement of the GABAB receptor in central respiratory mechanisms. Respiratory neurons (RNs) from the ventral respiratory group in the medulla of the cat were subjected to iontophoretic applications of the GABAB receptor agonist baclofen and the antagonists saclofen and CGP 35348. In all types of RNs baclofen decreased the firing rate. This reduction was antagonized by CGP 35348. Application of either antagonist increased the spontaneous discharge in both inspiratory and expiratory RNs. CGP 35348 excited 57% of the neurons tested, on the average by 34% with ejection currents of 100 nA. Saclofen excited 6 of 9 neurons tested. Baclofen administered systemically (8-12 mg/kg i.v.) to either anesthetized, decerebrate or intact freely moving cats, induced a selective lengthening of the inspiratory phase, an effect comparable to the apneusis induced by the NMDA antagonist MK-801. Baclofen also produced either a pronounced decrease in the amplitude of phrenic nerve discharge or an apnea, both of which were reversed by increasing paCO2. The results suggest that endogenously released GABA acting on GABAB receptors may be involved in the control of respiratory neuronal discharge.

Modulation of respiratory activity of neonatal rat phrenic motoneurones by serotonin

1. The effects of serotonin on phrenic motoneurones were studied in an in vitro preparation of the isolated brainstem and spinal cord from neonatal rats. 2. Serotonin (5-HT; > or = 5-10 microM) increased inspiratory-modulated phrenic nerve activity and produced a small amount of tonic activity during expiration. Inspiratory-modulated activity of the fourth cervical ventral root also increased, but was accompanied by robust tonic activity, which often obscured the rhythmic activity. 3. Serotonin, in both normal and tetrodotoxin-containing medium, depolarized phrenic motoneurones and increased cell input resistance. Serotonin also increased inspriatory-modulated firing as well as the response of phrenic motoneurones to injected current. The y-intercept of the relationship between firing frequency and injected current (f-I) was increased, but the slope was not affected. There was no bistable firing behaviour. 4. Under voltage clamp conditions, 5-HT produced a tonic inward current of 0.07-0.37 nA. This current increased with less negative holding potentials and decreased with more negative holding potentials (-75 to -90 mV) but did not reverse. 5. In addition, 5-HT decreased inspiratory-modulated synaptic current by 23 +/- 6%. The degree of attenuation was not affected by holding potential. The time course of the decrease in inspiratory-modulated synaptic current was similar to the changes seen in tonic inward current and input resistance. 6. Depolarization, tonic inward current, and shift in the f-I relationship produced by 5-HT were antagonized by the 5-HT2/1C receptor antagonist ketanserin and mimicked by the 5-HT2/1C agonist 1-(2,5-dimethoxy-4-iodophenyl)-2-aminopropane HCl (DOI). However, the 5-HT induced decrease in inspiratory-modulated synaptic current was not reduced by ketanserin nor mimicked by DOI. 7. We conclude that exogenously applied 5-HT simultaneously increases cell excitability and decreases inspiratory-modulated synaptic current in phrenic motoneurones via different types of receptors. When these responses occurred simultaneously, the increase in excitability predominated and the net effect was an augmentation of inspiratory-modulated phrenic motoneurone activity.

Multiple putative neuromessenger inputs to the phrenic nucleus in rat

Immunohistochemical reactions for 12 putative neuromessengers combined with retrograde labeling of phrenic motoneurons identified seven neuromessengers (5-hydroxytryptamine, substance P, thyrotropin-releasing hormone, methionine enkephalin, cholecystokinin, galanin, neuropeptide Y) located within terminal varicosities in the phrenic nucleus. The degree of terminal labeling in the phrenic nucleus varied depending on the peptide. Substance P, thyrotropin-releasing hormone and methionine enkephalin were each tested for colocalization with 5-hydroxytryptamine within terminal varicosities in the phrenic nucleus, and the coincidence of double-labeling varied for each peptide. These results indicate that phrenic motoneurons are subject to modulation by many peptide neuromessengers that may alter their responsiveness to primary excitatory and inhibitory inputs.

5-Hydroxytryptophan (5-HTP) augments spontaneous and evoked phrenic motoneuron discharge in spinalized rats

Experiments on anesthetized, spinalized rats were conducted to determine the effects of systemic 5-hydroxytryptophan (5-HTP) administration on: (1) spontaneous phrenic nerve activity and (2) evoked phrenic responses to short latency, non-serotonergic synaptic inputs elicited by electrical stimulation of lateral funiculus. 5-HTP augmented spontaneous phrenic activity and allowed expression of a second, longer latency evoked response. Both effects were antagonized by methysergide. Our results suggest that spinal serotonin increases the efficacy of synaptic inputs to phrenic motoneurons.

The role of inhibitory amino acids in control of respiratory motor output in an arterially perfused rat

The respiratory effects of drugs affecting GABAergic and glycinergic transmission were examined in order to assess the role of synaptic inhibition in breathing rhythmogenesis. Experiments were performed in the arterially perfused in situ brainstem-spinal cord preparation from adult rats (Hayashi et al., 1991, J. Neurosci. Meth. 36:63-70). Administration to the perfusate of agonists of GABAA, GABAB, and glycine receptors reduced both the frequency and amplitude of the activity recorded from the phrenic and hypoglossal nerves. Similar effects were observed following the infusion of aminooxyacetic acid (a blocker of GABA-transaminase). Picrotoxin (0.1-2 microM), bicuculline (0.05-0.2 microM), strychnine (0.1-1 microM) and phaclofen (0.1-0.2 mM) usually increased the frequency and amplitude of inspiratory bursts. Perfusion with low Cl- (8 mM) solution elicited tonic discharge followed by reversible arrest of the respiratory activity. It is concluded that synaptic inhibition is involved in the respiratory rhythm generation process in the mature mammalian brain. As data from the literature indicate that interference with central inhibitory processes does not largely affect the rhythm generation process in newborn rats, a possibility is discussed that the brainstem respiratory generator undergoes a developmental change from a 'pacemaker' driven circuit at the neonatal stage to a network requiring post-synaptic inhibition in the mature brain.

Serotonergic excitatory drive to hypoglossal motoneurons in the decerebrate cat

In decerebrate, paralyzed, vagotomized and artificially ventilated cats, serotonin (5-HT) and its analogues, microinjected into the hypoglossal (XII) motor nucleus, altered the activity of the genioglossal branch of XII nerve. 5-HT, carboxamidotryptamine maleate (5-CT) and DOI (1-5 mM) increased the activity by over 200%. Methysergide reversed this increase. Methysergide, mianserin, or ketanserin (100-250 nl, 1 mM) reduced the spontaneous hypoglossal activity by 20-50%. Buspirone, 8-OH-DPAT and (-)-propranolol were without effect. Thus, 5-HT provides a substantial tonic excitatory drive to XII motoneurons. The 5-HT receptors involved are likely to be type 1C or 2, but uncertainty regarding the affinity profiles of the drugs used in in vivo conditions in the cat precludes a definite identification.

Locus coeruleus control of spinal motor output

Using electrophysiological techniques, we investigated the functional properties of the coeruleospinal system for regulating the somatomotor outflow at lumbar cord levels. Many of the fast-conducting, antidromically activated coeruleospinal units were shown to exhibit the alpha 2-receptor response common to noradrenergic locus coeruleus (LC) neurons. Electrically activating the coeruleospinal system potentiated the lumbar monosynaptic reflex and depolarized hindlimb flexor and extensor motoneurons via an alpha 1-receptor mechanism. The latter synaptically induced membrane depolarization was mimicked by norepinephrine applied iontophoretically to motoneurons. That LC inhibited Renshaw cell activity and induced a positive dorsal root potential at the lumbar cord also reinforced LC's action on motor excitation. We conclude that LC augments the somatomotor output, at least in part, via an alpha 1-adrenoceptor-mediated excitation of ventral horn motoneurons. Such process is being strengthened by LC's suppression of the recurrent inhibition pathway as well as by its presynaptic facilitation of afferent impulse transmission at the spinal cord level.

Intracellular recording from respiratory neurones in the perfused 'in situ' rat brain

The study describes an arterially perfused in situ rat brain preparation, which uses an 'open circuit' flow of blood substitute with or without an oxygen carrier (2% perfluorotributylamine). The respiratory motor output was recorded from the phrenic and hypoglossal nerves, and could be maintained for up to 11 h from the start of perfusion (temperature of perfusate: 27-30 degrees C). The preparation allowed stable intracellular recordings from respiratory neurons in the brain stem and cervical spinal cord, and should be suitable for other studies which cannot be performed in standard whole animal models. The advantages of this approach compared with other in vitro or perfused in situ preparations are discussed.

Ventral respiratory group projections to phrenic motoneurons: electron microscopic evidence for monosynaptic connections

The hypothesis that excitatory drive is transmitted monosynaptically from bulbospinal medullary respiratory neurons to spinal respiratory motoneurons was tested by an ultrastructural analysis of the phrenic motoneuronal pool in the rat. Combined anterograde labeling of the principal inspiratory bulbospinal neuron population (ventral respiratory group) and retrograde labeling of the phrenic motoneuron pool demonstrated the presence of labeled synaptic profiles, indicating that at least some bulbospinal inspiratory neurons make monosynaptic contacts with phrenic motoneurons. The synaptic boutons of ventral respiratory group neurons that were labeled in the phrenic nucleus had asymmetrical membrane densities at sites of synaptic contact with labeled phrenic somal or dendritic profiles, supporting the notion that this bulbospinal pathway has excitatory contacts with phrenic motoneurons. The morphological types of labeled boutons included three of the eight previously identified bouton types in the phrenic nucleus (Goshgarian and Rafols: Journal of Neurocytology 13:85-109, 1984), including the "S"-terminal, the "NFs"-terminal, and the "F"-terminal. There was no conclusive evidence of labeled double synapses, indicating that this type of synaptic contact is not common in the intact bulbospinal pathway.

Ultrastructural evidence for serotonin-immunoreactive terminals contacting phrenic motoneurons in the cat

The innervation of the phrenic motor nucleus in the cat by serotonin-containing neurons has been studied using retrograde tracing combined with immunohistochemistry at the electron microscope level. It was found that phrenic motoneuron cell bodies and dendrites are contacted by serotonin-immunoreactive synaptic terminals. This finding suggests that the activity of phrenic motoneurons is directly affected by serotonergic neurons.

Serotonergic control of phrenic motoneuronal activity at the level of the spinal cord of the rabbit

The role of serotonin (5-hydroxytryptamine, 5-HT)-mediated modulation of phrenic motoneuronal activity was evaluated by microapplication of 5-HT and methysergide into the phrenic nuclei of the rabbit. 5-HT facilitated phrenic nerve activity (PNA) considerably resulting in a long-lasting augmentation of the peak amplitude of integrated PNA. In contrast, the blockade of intrinsically active 5-HT by methysergide decreased PNA and led to a strong reduction of the peak amplitude of integrated PNA. MDL 72222 was ineffective. Blockade of 5-HT receptors by preceding administration of methysergide effectively abolished the effects of microinjected 5-HT. Respiratory timing was unaffected by both the agonist and the antagonist. These results suggest that a considerable portion of the facilitatory influence of caudal raphe nuclei on central respiratory activity takes place at the phrenic nuclei level.

Brainstem connections of the rostral ventral respiratory group of the rat

The pontomedullary connections of the rostral division of the ventral respiratory group (rVRG), the largest medullary population of inspiratory bulbospinal and propriobulbar neurons, were identified in the rat by retrograde and anterograde tracing techniques. These experiments revealed that: (i) the Kölliker-Fuse nucleus, portions of the medial and lateral parabrachial nuclei, and all levels of the ipsilateral and contralateral VRG complex have dense reciprocal connections with the rVRG; (ii) the lateral paragigantocellular nucleus has reciprocal but less dense connections with rVRG; (iii) portions of the nucleus of the solitary tract have prominent projections to, but weaker inputs from rVRG; (iv) the raphe, magnocellular tegmental field and spinal trigeminal nuclei have minor projections to rVRG and receive only sparse inputs from rVRG, and; (v) the retrotrapezoid nucleus, pontine lateral tegmental field and area postrema each have only efferent projections to rVRG. These findings are consistent with previous studies of pontomedullary connections of rVRG in the cat, and further document the extensive reciprocal connections between principal respiratory groups. These connections are likely to be important for generation of the respiratory pattern, for the coordination of effector responses of the cranial and spinal respiratory motor neurons to afferent stimuli, and coordination of the central respiratory and cardiovascular control systems.

Subnuclear organization of the lateral tegmental field of the rat. II: Catecholamine neurons and ventral respiratory group

Bulbospinal and propriobulbar respiratory neurons of the ventral respiratory group and catecholamine neurons of the A1 and C1 cell groups were simultaneously labelled in the rat medulla by a combination of retrograde tracing and immunohistochemical identification. The ventral respiratory group and catecholamine cell groups form adjacent, parallel cell columns in the lateral tegmental field of the ventrolateral medulla. The ventral respiratory group is located immediately dorsal to the A1 and C1 groups, although some A1 neurons are intermingled with neurons of the rostral ventral respiratory group, and some C1 neurons are intermingled with those of the Bötzinger complex. The proximate populations of respiratory, catecholamine, and (presumptive) cardiovascular neurons identified in this study provide further support to the hypothesis that this region of the lateral tegmental field of the ventrolateral medulla is a site of cardiorespiratory coordination.

Origin of serotonin-containing projections to the ventral respiratory group in the rat

The major purpose of the present study was to determine the origin of the serotonin-containing neurons which project to the rostral ventral respiratory group in the rat. This was accomplished by using the technique of retrograde tracing with rhodamine-labeled latex microspheres (beads) combined with immunochemistry. The rhodamine-labeled beads were microinjected into electrophysiologically identified groups of inspiratory neurons in the rostral ventral respiratory group to retrogradely label neurons projecting to this site. Immunohistochemical processing of the tissue was then done to determine if serotonin was present in the retrogradely-labeled neurons. Serotonin-containing neurons projecting to the rostral ventral respiratory group were found in the raphe magnus, raphe obscurus, raphe pallidus and in the paraolivary region extending to the ventral medullary surface. No serotonin-containing neurons in more rostrally located raphe nuclei were found to project to the rostral ventral respiratory group. The findings suggest that caudal raphe serotonergic projections may affect the activity of respiratory neurons in the rostral ventral respiratory group. Projections to the rostral ventral respiratory group from other pontomedullary nuclei were also identified. Rhodamine-labeled neurons were found in the area of the Kölliker-Fuse nucleus, lateral and medial parabrachial nuclei, retrofacial nucleus, nucleus ambiguus/retroambigualis, nucleus tractus solitarius, A5 region, nucleus paragigantocellularis lateralis, retrotrapezoid nucleus, area postrema and spinal trigeminal nucleus. The projections to the rostral ventral respiratory group in the rat are similar to those previously described in the cat and suggest a common circuitry for the CNS control of breathing.