Paul M. Pilowsky

Limitations of the technique of pressure microinjection of excitatory amino acids for evoking responses from localized regions of the CNS.

The aim of this study, performed on anaesthetized cats and rabbits, was to test the assumption that pressure microinjections of excitatory amino acids cause long-lasting excitation of neurones located close to the injection site. Unitary action potentials or antidromic field potentials were recorded from respiratory or reticular neurones in the medulla oblongata and from phrenic motoneurones at different distances from the injection site. Injection of 10-150 nl (5-150 nmol) of L-glutamate or DL-homocysteic acid into these areas resulted in complex and widespread neuronal events. Generally, more distant neurones (500-1300 microns) were excited for variable periods of time (3-15 min), while neurones in the vicinity of the injection site (0-500 microns) showed, after a brief period of excitation time, a long-lasting (up to 30 min) decrease in excitability or silencing of discharge, probably due to a depolarizing block and disturbances in the ionic composition of the extracellular space. These findings show that interpretation of physiological responses following such injections should not be based on an assumption of local neuronal excitation. Some recommendations regarding the use of this technique are made.

The tungstate-stabilized tetramethylbenzidine reaction for light and electron microscopic immunocytochemistry and for revealing biocytin-filled neurons

A peroxidase reaction product that can be easily distinguished from standard diaminobenzidine (DAB) reaction products is needed for pre-embedding electron microscopic double-antibody labelling studies. Benzidine dihydrochloride (BDHC) and gold-substituted silver peroxidase reactions are unsatisfactory for double labelling because they lack sensitivity and reliability and/or compromise ultrastructure. We show here that light and electron microscopic immunocytochemistry can be done with a modification of the tungstate-stabilized tetramethylbenzidine (TMB) reaction (Weinberg and Van Eyck 1991) which yields a crystalline reaction product. With this method, we have obtained excellent immunolabelling for a variety of antigens, including tyrosine hydroxylase, enkephalin, serotonin, Fos protein and retrogradely transported cholera toxin B subunit (CTB). The TMB-tungstate reaction is useful for ultrastructural double labelling because the crystals contrast well with the amorphous product of diaminobenzidine reactions. The TMB-tungstate reaction is more sensitive and reliable for immunocytochemistry than the benzidine dihydrochloride reaction and gives better ultrastructure than the gold-substituted silver peroxidase reaction. We also show that neurons filled with biocytin by intracellular injection can be visualized with TMB-tungstate for either light (LM) or electron (EM) microscopy.

Spinal cord serotonin release and raised blood pressure after braintem kainic acid injection

The recently developed technique of in vivo dialysis has permitted us to make direct measurements of serotonin release in a specific region of the spinal cord and to relate this to changes in blood pressure elicited by chemical stimulation of the brainstem. In the present experiments we have shown that chemical stimulation of bulbospinal neurons in the region of the B3 cell group in the ventromedial medulla, causes an increase in the release of serotonin in the thoracic spinal cord and that this release is associated with an increase in blood pressure.

Glutamate-immunoreactive synapses on retrogradely-labelled sympathetic preganglionic neurons in rat thoracic spinal cord.

Retrograde tracing with cholera toxin B subunit (CTB) combined with post-embedding immunogold labelling was used to demonstrate the presence of glutamate-immunoreactive synapses on sympathetic preganglionic neurons that project to the adrenal medulla or to the superior cervical ganglion in rat thoracic spinal cord. At the electron microscope level, glutamate-immunoreactive synapses were found on retrogradely labelled nerve cell bodies and on dendrites of all sizes. Two-thirds of the vesicle-containing axon profiles that were directly apposed to, or synapsed on, CTB-immunoreactive sympathoadrenal neurons were glutamate positive. The proportion of glutamate-immunoreactive contacts and synapses on sympathoadrenal neurons decreased to zero when the anti-glutamate antiserum was absorbed with increasing concentrations of glutamate from 0.1 mM to 10 mM. Double immunogold labelling for glutamate and gamma-aminobutyric acid (GABA) showed that glutamate-immunoreactive profiles did not contain GABA and that GABA-immunoreactive profiles did not contain glutamate. These results suggest that glutamate is the major excitatory neurotransmitter to sympathoadrenal neurons and possibly to other sympathetic preganglionic neurons in the intermediolateral cell column of the spinal cord.

Glutamate in spinally projecting neurons of the rostral ventral medulla

Phosphate activated glutaminase (PAG), an enzyme of glutamate synthesis, was localized by immunohistochemistry in all PNMT-immunoreactive and all serotonin-immunoreactive neurons in the rostral ventral medulla of the rat. Between 71 and 83% of bulbospinal neurons localised in the rostral ventral medulla projecting to the intermediolateral cell column in the upper thoracic spinal cord contained PAG immunoreactivity. Of these bulbospinal PAG-immunoreactive neurons 17-27% contained PNMT immunoreactivity and 9-16% contained serotonin immunoreactivity. Other bulbospinal PAG-immunoreactive neurons (60-70%) contained neither PNMT- nor serotonin immunoreactivity. The results provide anatomical evidence suggestive of a glutamatergic input to the sympathetic preganglionic neurons of the spinal cord arising from different populations of neurons located in the rostral ventral medulla.

Altered c-fos in Rostral Medulla and Spinal Cord of Spontaneously Hypertensive Rats

Neurons immunoreactive for Fos, the protein product of the immediate early gene c-fos, have been compared in the rostral ventral medulla and spinal cord of conscious normotensive Wistar-Kyoto rats (WKY) and spontaneously hypertensive rats (SHR) after baroreceptor unloading. Hypotension induced by a 60-minute intravenous infusion of sodium nitroprusside reduced baroreceptor activity; controls received intravenous saline. In WKY, 474 +/- 56 (n=6) Fos-positive neurons were identified in the rostral ventral medulla after nitroprusside infusion, a fivefold increase from controls; 50% of the tyrosine hydroxylase-containing neurons in the rostral ventral medulla were activated by this hypotension. Sympathetic preganglionic neurons, mainly sympathoadrenal neurons, were Fos positive after nitroprusside, but Fos-positive sympathetic preganglionic neurons were not observed in control WKY. In SHR, Fos immunoreactivity in the rostral ventral medulla was elevated in the control group compared with the WKY controls (236 +/- 31 and 93 +/- 15, respectively, n=6 for both). Nitroprusside hypotension did not further increase Fos immunoreactivity in the rostral ventral medulla, although the number of Fos-positive spinal sympathetic neurons increased. Our results have identified different neuronal activities between WKY and SHR in sites that are critical to sympathetic outflow. In WKY, nitroprusside effects are consistent with an activation of rostral ventral medulla neurons, including bulbospinal neurons, that are normally inhibited by baroreceptor activity. In SHR, basal nerve activity is increased, so even at rest, rostral ventral medulla neurons and sympathetic preganglionic neurons, mainly sympathoadrenal neurons, are Fos immunoreactive. These activated neurons are likely to contribute to the elevated blood pressure in this rat strain.

N‐METHYL‐d‐ASPARTATE RECEPTORS IN THE SPINAL CORD MEDIATE PRESSOR RESPONSES TO STIMULATION OF THE ROSTRAL VENTROLATERAL MEDULLA IN THE RAT

1. Activation of bulbospinal neurons projecting from the C1 area of the rostral ventrolateral medulla evokes a pressor response. The nature of the neurotransmitters involved in mediating this response at spinal cord level has not been established.

The One Hundred Percent Hypothesis: Glutamate Or Gaba in Synapses on Sympathetic Preganglionic Neurons

The synaptic input from glutamate- or gamma-aminobutyric acid (GABA)-immunoreactive nerve fibers to sympathetic preganglionic neurons projecting to the superior cervical ganglion was assessed using retrograde tracing with cholera toxin B subunit and post-embedding immunogold labelling. Half the boutons that synapsed on or directly contacted this group of neurons were immunoreactive for glutamate and half were immunoreactive for GABA. In previous studies, about 2/3 of the synapses on sympathoadrenal neurons were found to be glutamate-immunoreactive and about 1/3, GABA immunoreactive and these two amino acids were not co-localized. Thus, 100% of the boutons that synapse on sympathetic preganglionic neurons supplying the superior cervical ganglion or the adrenal medulla are likely to contain either glutamate or GABA. Anterograde tracing combined with amino acid immunocytochemistry indicated that at least some glutamate-containing and some GABA-containing nerve fibers in the intermediolateral cell column could come from the rostral ventral medulla.

Differential regulation of the central neural cardiorespiratory system by metabotropic neurotransmitters

Central neurons in the brainstem and spinal cord are essential for the maintenance of sympathetic tone, the integration of responses to the activation of reflexes and central commands, and the generation of an appropriate respiratory motor output. Here, we will discuss work that aims to understand the role that metabotropic neurotransmitter systems play in central cardiorespiratory mechanisms. It is well known that blockade of glutamatergic, gamma-aminobutyric acidergic and glycinergic pathways causes major or even complete disruption of cardiorespiratory systems, whereas antagonism of other neurotransmitter systems barely affects circulation or ventilation. Despite the lack of an ‘all-or-none’ role for metabotropic neurotransmitters, they are nevertheless significant in modulating the effects of central command and peripheral adaptive reflexes. Finally, we propose that a likely explanation for the plethora of neurotransmitters and their receptors on cardiorespiratory neurons is to enable differential regulation of outputs in response to reflex inputs, while at the same time maintaining a tonic level of sympathetic activity that supports those organs that significantly autoregulate their blood supply, such as the heart, brain, retina and kidney. Such an explanation of the data now available enables the generation of many new testable hypotheses.

GOOD VIBRATIONS? RESPIRATORY RHYTHMS IN THE CENTRAL CONTROL OF BLOOD PRESSURE

1. Arterial blood pressure is maintained, and reflexly controlled, by the activity of neurons in the medulla and spinal cord.