Location and electrophysiological characterization of rostral medullary adrenergic neurons that contain neuropeptide Y mRNA in rat medulla.

The objective of this study was to characterize the projection pattern and electrophysiological properties of the rostral medullary adrenergic neurons (C(1)) that express neuropeptide Y (NPY) mRNA in rat. NPY mRNA was found in a variable fraction of tyrosine hydroxylase immunoreactive (TH-IR) neurons depending on the medullary level. By retrograde labeling (Fast Blue, FluoroGold), NPY mRNA was detected in virtually all C(1) cells (96%) and C(3) cells (100%) with hypothalamic projections but in only 9% of C(1) cells and 58% of C(3) cells projecting to thoracic segment 3 (T(3)) or T(6) of the spinal cord. To identify the electrophysiological properties of the C(1) cells that express NPY mRNA, we recorded from baroinhibited neurons within the C(1) region of the ventrolateral medulla (RVLM) and tested for projections to segment T(3), the hypothalamus, or both. By using the juxtacellular method, we labeled these cells with biotinamide and determined whether the recorded neurons were TH-IR and contained NPY mRNA. At rostral levels (Bregma -11.8 mm), barosensitive neurons had a wide range of conduction velocities (0.4-6.0 m/second) and discharge rates (2-28 spikes/second). Most projected to T(3) only (27 of 31 cells), and 4 projected to both the hypothalamus and the spinal cord. Most of the baroinhibited cells with spinal projections but with no hypothalamic projections had TH-IR but no NPY mRNA (11 of 17 cells). Only 1 cell had both (1 of 17 cells), and 5 cells had neither (5 of 17 cells). Both TH-IR and NPY mRNA were found in neurons with dual projections (2 of 2 cells). At level Bregma -12.5 mm, baroinhibited neurons had projections to the hypothalamus only (13 of 13 cells) and had unmyelinated axons and a low discharge rate. Four of five neurons contained both TH-IR and NPY mRNA, and 1 neuron contained neither. In short, NPY is expressed mostly by C(1) cells with projection to the hypothalamus. NPY-positive C(1) neurons are barosensitive, have unmyelinated axons, and have a very low rate of discharge. Most bulbospinal C(1) cells with a putative sympathoexcitatory role do not make NPY.

Properties of C1 and other ventrolateral medullary neurones with hypothalamic projections in the rat.

1. This study compared (i) the properties of C1 cells with those of neighbouring non-C1 neurones that project to the hypothalamus and (ii) the properties of C1 cells that project to the hypothalamus with those of their medullospinal counterparts. 2. Extracellular recordings were made at three rostrocaudal levels of the ventrolateral medulla (VLM) in alpha-chloralose-anaesthetized, artificially ventilated, paralysed rats. Recorded cells were filled with biotinamide. 3. Level I (0-300 microm behind facial nucleus) contained spontaneously active neurones that were silenced by baro- and cardiopulmonary receptor activation and virtually unaffected by nociceptive stimulation (firing rate altered by < 20 %). These projected either to the cord (type I; 36/39), or to the hypothalamus (type II; 2/39) but rarely to both (1/39). 4. Level II (600-800 microm behind facial nucleus) contained (i) type I neurones (n = 3) (ii) type II neurones (n = 11), (iii) neurones that projected to the hypothalamus and were silenced by baro- and cardiopulmonary receptor activation but activated by strong nociceptive stimulation (type III, n = 2), (iv) non-barosensitive cells activated by weak nociceptive stimulation which projected only to the hypothalamus (type IV, n = 9), (v) cells that projected to the hypothalamus and responded to none of the applied stimuli (type V, n = 7) and (vi) neurones activated by elevating blood pressure which projected neither to the cord nor to the hypothalamus (type VI, n = 4). 5. Level III (1400-1600 microm behind facial motor nucleus) contained all the cell types found at level II except type I. 6. Most of type I and II (17/26) and half of type III cells (4/8) were C1 neurones. Type IV-V were rarely adrenergic (2/12) and type VI were never adrenergic (0/3). 7. All VLM baroinhibited cells project either to the cord or the hypothalamus and virtually all (21/23) C1 cells receive inhibitory inputs from arterial and cardiopulmonary receptors.

Distribution of alpha 2A-adrenergic receptor-like immunoreactivity in the rat central nervous system.

In this study, we analyzed immunohistochemically the distribution of the A subtype of alpha 2-adrenergic receptor (alpha 2A-AR) in the rat central nervous system using light level immunohistochemistry. By using affinity-purified antisera, we found perikaryal labeling was diffuse and/or punctate; immunoreactive puncta were heterogeneous in size and number in a region-specific manner. Dense deposits of immunoreaction product were found associated with neuropil also, particularly in the lateral parabrachial nucleus, locus coeruleus, lateral septum, diagonal band, stratum lacunosum-moleculare of CA1, and various nuclei of the amygdala and extended amygdala. Prominently immunoreactive olfactory structures include the anterior olfactory nucleus and the granular layer of the olfactory bulb. The cortex was generally light to moderately labeled with greater immunoreactivity in the cingulate and insular cortices. alpha 2A-AR-like immunoreactivity was intense in the basal forebrain and continuous from the nucleus accumbens through the substantia innominata and fundus of the striatum. Most immunoreactivity in the diencephalon was restricted to the hypothalamus with light to moderate labeling in the thalamus. Generally light immunoreactivity was observed in midbrain structures. In the pons and medulla, both perikaryal and neuropil labeling were observed. Together with the accompanying paper describing the neural distribution of alpha 2C-AR-like immunoreactivity, our results provide an extensive immunohistochemical cartography of alpha 2-ARs in the adult rat central nervous system.

Central noradrenergic neurons: the autonomic connection.

Most CNS noradrenergic (NE) cell groups reside in portions of the medulla oblongata primarily involved in autonomic control (A1, A2, A5) and even the pontine locus coeruleus (A6) receives a major innervation from these medullary areas. This review examines the neuroanatomical and neurophysiological literature relevant to the issue of the role of CNS NE neurons in central autonomic control (with emphasis on cardiovascular control). It is concluded that NE cells, with the possible exception of certain A5 and A1 neurons, have relatively weak or no inputs from visceral cardiovascular afferents but provide a complex "open loop" control over non-aminergic circuits which are more specialized in the processing of cardiovascular and other autonomic reflexes. The question of whether the C1 "adrenergic" cells of the rostral medulla oblongata actually use noradrenaline as a neurotransmitter is also briefly addressed.

Hypothalamic glutamatergic input to medullary sympathoexcitatory neurons in rats.

In the halothane-anesthetized paralyzed rat, electrical or chemical stimulation of lateral hypothalamic sites dorsolateral to the fornix produced pressor effects, increases in lumbar sympathetic nerve discharge (SND), and excitation of the majority of bulbospinal sympathoexcitatory neurons of nucleus paragigantocellularis lateralis (PGCL sympathoexcitatory neurons). The relationship between SND and mean arterial pressure (MAP) was shifted upward by electrical hypothalamic stimulation, whereas the gain of the baroreflex was unchanged. A similar upward shift of the relationship between the discharge rate of PGCL sympathoexcitatory neurons and MAP was observed during stimulation. The excitatory effect of L-glutamate on PGCL sympathoexcitatory neurons was blocked by iontophoretic applications of kynurenic acid, whereas identical amounts of 8-OH kynurenic acid were ineffective. Bilateral pressure injections of kynurenic acid (but not of 8-OH kynurenic acid) into nucleus PGCL markedly reduced the pressor and sympathoexcitatory effects of hypothalamic stimulation without altering the on-going level of SND or its baroreflex inhibition. Applied by iontophoresis, kynurenic acid also attenuated the excitation of PGCL sympathoexcitatory neurons produced by hypothalamic stimulation. It is concluded that descending sympathoexcitatory pathways, originating in part in the lateral hypothalamus, relay in nucleus PGCL. This relay involves synapses that release an endogenous glutamate receptor agonist. These results suggest that synaptic integration between these glutamatergic inputs and gamma-aminobutyric acid baroreceptor inputs occurs in the immediate vicinity of PGCL bulbospinal sympathoexcitatory neurons or perhaps directly on their somadendritic surface.

Electrophysiological study of cardiovascular neurons in the rostral ventrolateral medulla in rats.

In urethane-anesthetized rats, electrophysiological recordings of spontaneously active neurons in the vasopressor area of the rostral ventrolateral medulla were analyzed for participation in cardiovascular regulation. A total of 138 units were found which were inhibited by transient increases in mean arterial pressure elicited by intravenous injection of norepinephrine, aortic occlusion, or electrical stimulation of the hypothalamus, with 100% inhibition occurring at 148 mm Hg. Histograms of postsystolic activity showed that these units had pulse-synchronous rhythms which grew more prominent as arterial pressure increased. Furthermore, electrical stimulation of the superior laryngeal nerve, which elicited a vasodepressor response, strongly inhibited these units. Thus, these neurons were termed negatively correlated cardiovascular units. At least half of these cells project to or through the thoracic spinal cord. In addition, arterial pressure sensitivity is conveyed through carotid sinus and aortic arch afferents. Approximately half of the cardiovascular units are also excited by hypothalamic stimulation. Finally, analysis of neighboring cells showed that it is possible to distinguish between cardiovascular and respiratory units. These data are consistent with the concept of a medullary center which supports tonic sympathetic vasomotor tone and which mediates baroreceptor reflexes, as well as vascular responses of the defense reaction.

Antidromic identification of dopaminergic and other output neurons of the rat substantia nigra.

In the present study dopamine (DA)-containing and other output neurons of the substantia nigra (SN) wer identified by antidromic stimulation from postulated target nuclei, the caudate-putamen, the thalamus, the cortex and the pontine reticular formation. To guide electrode placements, the topography of the nigrostriatal projection system was determined by retrograde tracing methods. Spontaneously active cells present in the SN were then classified in two groups according to the shape of their action potentials and their firing rate. Type I cells were located mainly in the pars compacta and could be antidromically-activated (AD-activated) from various locations along the course of the nigrostriatal pathway (caudate-putamen, globus pallidus, MFB) but not from other brain areas (ventromedial thalamus, motor cortex, pontine reticular formation). These neurons had a slow bursting pattern of firing, a very slow conduction velocity (0.58 m/sec), and a wide action potential. Their firing rate was dramatically reduced following the intravenous administration of apomorphine (ID 50: 9.3 microgram/kg), or the iontophoretic application of DA and GABA. Type II cells were located predominantly in the pars reticulata; most of them could be AD-activated from the ventromedial thalamus and the MFB but not from the motor cortex. A few of these cells could be AD-activated from the pontine reticular formation and the thalamus. A minority of type II cells, located in or near the pars compacta could be AD-activated from the caudate-putamen. In addition, their conduction velocuty was much higher (2.8 m/sec) and their firing rate far in excess of that exhibited by type I neurons. These neurons were inhibited by the iontophoretic application of GABA but not of DA. The microinjection of 6-hydroxydopamine (a neurotoxin relatively specific against catecholamine-containing neurons) in the vicinity of the MFB blocked selectively the propagation of antidromic spikes in type I but not type II cells. It is concluded that type I cells are the DA neurons of the nigrostriatal pathway. Type II cells are mainly oupput neurons that project to the ventromedial thalamus, the pons and the forebrain. This telencephalic projection most likely constitutes a second, non-DA, fast-conducting nigrostriatal pathway.