Presynaptic heteroreceptors in regulation of neuronal transmission

The cholinergic system and neostriatal memory functions

The striatum is one of the major forebrain regions that strongly expresses muscarinic and nicotinic cholinergic receptors. This article reviews the current knowledge and our new findings about the striatal cholinoceptive organization and its role in a variety of cognitive functions. Pharmacological and genetic manipulations have indicated that the cholinergic and dopaminergic system in the striatum modulate each other's function. In addition to modulating the dopaminergic system, nicotinic cholinergic receptors facilitate GABA release, whereas muscarinic receptors attenuate GABA release. The striatal cholinergic system has also been implicated in various cognitive functions including procedural learning and intradimensional set shifting. Together, these data indicate that the cholinergic system in the striatum is involved in a diverse set of cognitive functions through interactions with other neurotransmitter systems including the dopaminergic and GABAergic systems.

Changes in the regulation of 5-hydroxytryptamine release by alpha2-adrenoceptors in the rat hippocampus after long-term desipramine treatment

In vivo microdialysis was used to measure the effects of long-term treatment of rats with desipramine upon the regulation by alpha2-adrenoceptors of serotonin (5-hydroxytryptamine, 5-HT) release from the serotonergic neurons in the hippocampus. Rats were injected with saline or desipramine, 10 mg/kg, i.p., every 12 h for 14 days. When added to the perfusion solution, brimonidine, an alpha2-adrenoceptor agonist, significantly inhibited the K+-evoked release of 5-HT in the hippocampi of saline-treated, control rats. This action of brimonidine was prevented by pretreating the rats with idazoxan, an alpha2-adrenoceptor antagonist. Long-term desipramine treatment significantly reduced the inhibitory effect of brimonidine upon the K+-evoked 5-HT release. With long-term administration of desipramine, noradrenaline content in the hippocampi was significantly decreased as compared with that of the control rats, whereas the basal noradrenaline concentration in the dialysate was significantly increased. On the other hand, both the 5-HT content of the hippocampus and the basal 5-HT concentration in the dialysate were significantly increased. The present study suggests that long-term administration of desipramine causes a functional subsensitivity of the presynaptic alpha2-adrenoceptors that regulate serotonergic neuronal function in the rat hippocampus. It also supports the concept that changes in the sensitivity of alpha2-adrenoceptors that regulate neurotransmitter release play an important role in the mechanism of antidepressant drug action.

Dopamine D2 autoreceptors in rats are behaviorally functional at 21 but not 10 days of age

Previous studies used either racemic 3-(3-hydroxyphenyl)-N-n-propylpiperidine [(+/-)-3-PPP] or lower doses of the mixed dopamine (DA) D1/D2 agonist apomorphine (APO) to conclude that brain DA D2 autoreceptors are not behaviorally functional until 28 days of age. The purpose of this study was to provide behavioral evidence for functional D2 autoreceptors before 28 days of age using DA agonists with greater selectivity for D2 autoreceptors. The locomotor activity of 10-, 21-, 35-day-old and adult rats was monitored after injection of a D2 autoreceptor agonist. There were significant decreases in the locomotor activity of 21-, 35-day-old, and adult rats injected with (-)-3-PPP, SND 919, or PD 128483. Lower doses of APO significantly decreased the activity of adult and 35-day-old rats but not younger rats. The only significant effect on the locomotor activity of 10-day-old rats was an increase in activity after injection of APO, 0.01 mg/kg or higher, or B-HT 920, 0.01 mg/kg. The results suggest that brain DA D2 autoreceptors are behaviorally functional at 21, but not 10, days of age.

Transport of receptors

The axonal transport of neurotransmitter receptors is thought to be a common phenomenon in many neuronal systems. The "machinery" for receptor (protein) "assembly" is found in the cell bodies of neurons and the "manufacture" of receptors takes place there. These receptors are then "shipped" to their ultimate destinations by a transport process. This is an axonal transport mechanism in the case of presynaptic receptors. Some form of transport process may also exist to send receptors out into the dendritic arborizations of neurons, although the latter is more difficult to verify. Axonal transport has been demonstrated, in the peripheral nervous system, for many different neurotransmitter receptors. In the central nervous system, the results are less clear, but indicate the presence of a transport mechanism for catecholamine, acetylcholine, and opiate sites. One important component then, in the development of receptors, is the transportation to terminal membrane sites where they are ultimately incorporated and available for interaction with neurotransmitters and drugs.

Accumulation and release of adrenaline, and the modulation by adrenaline of noradrenaline release from rabbit blood vessels in vitro

The accumulation of (-)-3H-adrenaline (3H-A) by rabbit isolated aorta was studied. In all experiments, monoamine oxidase and catechol-O-methyltransferase were inhibited by treatment with pargyline and 3',4'-dihydroxy-2-methyl-propiophenone, respectively. The relationship between the accumulation of 3H derived from 3H-A and the duration of incubation was linear. The 3H-accumulation after 3 h incubation was 22.5 ml/g. In reserpine-treated tissue, the 3H-accumulation levelled off after 30 min and was 8.5 ml/g after 3 h. The concentration of 3H-A or (-)-3H-noradrenaline (3H-NA) and the 3H-accumulation (ml/g) were inversely related. At 10(-8) M, the 1-hour accumulation of 3H derived from 3H-A and 3H-NA was 7.8 and 15.2 ml/g, respectively. With increasing concentrations the accumulation values approached each other. The accumulation of 3H derived from 3H-A by reserpine-treated tissue also showed an inverse relationship with concentration. The accumulation of 3H derived from 3H-A was dependent on the bath temperature. Storage of tissue (0-5 days in salt solution without equilibration with 95% O2/5% CO2; 4 degrees C) did not affect the accumulation of 3H derived from 3H-A. Thereafter (7-14 days), the accumulation decreased. The inhibitory potency (IC50; -log M) of desipramine, cocaine, propranolol, isoprenaline, and normetanephrine on accumulation of 3H derived from 3H-A was found to be 8.26; 6.50; 5.48; 4.88, and 4.02, respectively. The maximal degree of inhibition was almost the same for these drugs, while that of clonidine and corticosterone was 50 and 20%, respectively. In the presence of desipramine, either clonidine, corticosterone or isoprenaline reduces the accumulation of 3H derived from 3H-A. Ouabain and iodoacetic acid, but not sodium cyanide and 2,4-dinitrophenol, reduced the accumulation of 3H derived from 3H-A. Anoxia (95% N2/5% CO2; 37 degrees C; 1-24 h) did not alter the accumulation of 3H derived from 3H-A. Glucose deprivation alone or combined with anoxia markedly reduced the 3H-accumulation. The release of 3H-A from rabbit isolated aorta was studied. This release was compared with that of 3H-NA. The stimulation-evoked 3H-overflow from aorta preloaded with 3H-A decreased with repeated stimulation. In contrast, prestimulation enhanced subsequent stimulation-evoked 3H-overflows. For both 3H-amines, the 3H-overflow increased concomitantly to the same degree with the number of pulses. The time course of 3H-overflows with either 3H-A or 3H-NA was compared.(ABSTRACT TRUNCATED AT 400 WORDS)

Quinolinic acid lesion of nucleus accumbens reduces D1 but not D2 dopamine receptors: an autoradiographic study

Information concerning the cellular localization of dopamine receptor subtypes in the nucleus accumbens (NAcc) was obtained using receptor autoradiographic analysis. Unilateral, stereotaxic injection of the axon-sparing neurotoxin, quinolinic acid, into the NAcc resulted in a prominent loss of dopamine D1 receptors (as labeled by [3H]SCH 23390). Contrarily, no appreciable decrement in D2 receptors (labeled by [3H]raclopride) could be identified within the same region of the NAcc. The findings support the view that accumbens D1 receptors are located postsynaptically on neurons or their processes, while D2 receptors within this nucleus are primarily located on afferent terminals.

Regulation of the synthesis and metabolism of striatal dopamine after disruption of nerve conduction in the medial forebrain bundle

1. After physical (knife-cut) or chemically-mediated (tetrodotoxin 300 nM, 1.5 microliters; 1.0 microliters min-1) interruption of nerve conduction in the nigrostriatal tract, there was a marked increase in the synthesis and metabolism of dopamine in the isolated dopaminergic nerve terminals of the striatum. The effect peaked at 4 h post-transection, at which time 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA) were increased by 300% and 700% respectively (DOPAC: 27 +/- 13 vs 80 +/- 17 nmol g-1; HVA: 6.66 +/- 3.57 vs 54 +/- 18 nmol g-1). The increases in dopamine content and metabolism are secondary to an increase in the rate of synthesis on the lesioned side, versus the intact, control side. 2. In both experimental situations, haloperidol (1.0 mg kg-1, i.p.) retained its known ability to induce a significant increase in DOPAC and HVA in the striatum, despite the interruption of nerve conduction in the nigrostriatal tract. 3. Six days after cutting the left nigrostriatal tract, dopamine in the left striatum was reduced to less than 5% of the control value, and DOPAC and HVA were not detectable. In the denervated, left striatum, the synthesis of dopamine (from injected L-DOPA), and its metabolism to DOPAC and HVA, occurred to the same degree as in the intact right side. In these DOPA-treated rats, haloperidol (1.0 mg kg-1, i.p.) caused a further increase in DOPAC and HVA in the intact striatum, but not in the denervated striatum. 4. Under non-stressful conditions, using a combination of anaesthetic treatments, electrical stimulation (400 muA, 0.4 ins, 15 Hz, 15 min) of the nigrostriatal tract did not increase DOPAC or HVA in the striatum on the stimulated side. 5. It is concluded (a) that there is a significant presynaptic, and/or local circuit mechanism capable of activating the synthesis and metabolism of dopamine in the isolated, striatal, dopaminergic nerve terminals. Furthermore, haloperidol can act directly on the striatal, dopaminergic nerve terminal, to cause an increase in the synthesis and metabolism of striatal dopamine. (b) After degeneration of the striatal dopaminergic nerves, the denervated striatum retains the ability to synthesize (from L-DOPA) and metabolize dopamine, to the same degree as the intact, innervated, contralateral striatum. (c) When stress is minimized, and release of dopamine is induced by electrical stimulation of the medial forebrain bundle, the catabolism of dopamine (to DOPAC and HVA) during the release-uptake cycle may not be a significant factor under physiological conditions. (d) When dopamine synthesis is increased in the striatum, the normal blood concentration of tyrosine is adequate to sustain the increased synthesis, and precursor availability is not a limiting factor. (e) These results suggest that some of the basic concepts about the neurochemical/neurophysiological regulation of monoaminergic neurones may require further reevaluation.

Effects of adrenergic agonists and adenosine on cholinergic neurotransmission in human tracheal smooth muscle

There is only limited information available on the prejunctional regulation of acetylcholine (ACh) release from cholinergic nerves in human airway smooth muscle. Stimulation of cholinergic nerves in fresh postmortem tracheal muscle strips with electrical field stimulation (EFS) causes reproducible contractions. We have studied the effect on contractile responses of: 1) The alpha 2-adrenoceptor agonist effect of noradrenaline (NA, 0.1-30 microM) and clonidine (10 nM-30 microM), in the presence of 1 microM propranolol and prazosin +/- idazoxan (0.1 microM); 2) The beta-adrenoceptor agonist effect of fenoterol (FEN) and isoprenaline (ISO, 1 nM-30 microM) +/- ICI 118,551 (10 nM), comparing EFS responses to comparable responses to exogenous ACh; 3) The A1 and A2 adenosine receptor agonists effects of L-PIA and NECA (1 nM-10 microM). NA caused a concentration-dependent depression of the cholinergic frequency-response curve. However responses at 5 Hz were not modified by the addition of idazoxan. Similarly clonidine did not reduce contractile responses. The concentrations of isoprenaline (56 nM) and fenoterol (165 nM) required to inhibit EFS (5 Hz) by 50% (IC50) were significantly less than those required to inhibit closely matched ACh responses to a comparable degree (ISO = 117 and FEN = 304 nM), and the maximum inhibition of EFS was greater. Following isoprenaline and the beta 2-antagonist ICI 118,551 the IC50's for EFS and ACh were not different. NECA and PIA had no effect on cholinergic EFS. We conclude that a prejunctional beta 2 receptor may be present on cholinergic nerves in post-mortem tracheal smooth muscle but no evidence for alpha 2-adrenoceptor or adenosine-receptor regulation was obtained.

Lack of evidence for axonal transport of D1 and D2 receptors in the nigro-striatal pathway of the rat

The possibility that D1 and D2 dopamine receptors are axonally transported in the nigro-striatal pathway has been investigated in the rat by placing a coronal knife cut (sparing the striato-nigral pathway) through the medial forebrain bundle (MFB) and autoradiographically examining the density of D2 (as labeled by [3H]spiperone in the presence of ketanserin) and D1 (as labeled by [3H]SCH 23390) receptors. The efficacy of MFB transection has been assessed by measuring in parallel the binding of [3]ketanserin, a ligand that has been reported to be axonally transported in this bundle. At 12 h post-transection, there was a minor accumulation of [3H]spiperone binding on both sides of the transection. However, (+)butaclamol (1 microM) failed to displace the ligand build-up at the knife cut, thus demonstrating the nonspecific nature of [3H]spiperone accumulation. Similar results were observed at 24, 48, and 72 h after severing the MFB. MFB transection also failed to cause changes in specific [3H]SCH 23390 binding at the knife cut at 12-72 h post-surgery. In contrast, a dramatic accumulation of [3H]ketanserin binding sites was observed rostral and caudal to the cut at 12 h post-transection, attesting to the efficacy of the lesion. These results confirm the existence of both anterograde and retrograde transport of [3H]ketanserin binding sites and suggest that D1 and D2 receptors are not axonally transported in fibers of the nigro-striatal pathway.

Axonal transport of neuroreceptors: possible involvement in long-term memory

Evidence is presented that neuroreceptors move bidirectionally along axons of neurons through fast axoplasmic transport mechanisms. The retrograde transport of receptor-bound signal molecules from nerve terminals to the perikaryon represents a corridor of information between synapses and the cell body of neurons. It is speculated that this process could be involved in long-term memory.

Parasympathetic effects on in vivo rat heart can be regulated through an alpha 1-adrenergic receptor

A prejunctional mechanism involving an alpha 1-adrenergic receptor may exert control on the release of acetylcholine from parasympathetic nerve endings in the heart. To test this hypothesis in vivo, rats were prepared for electrical stimulation of the vagus nerves. Blood pressures and heart rates were monitored, and the animals were treated with alpha-agonists and alpha-antagonists. The alpha 1-selective agonist phenylephrine significantly attenuated vagally induced bradycardia in a dose-dependent fashion (ED50 = 19 micrograms/kg). This is consistent with the hypothesis that there is alpha-adrenergic inhibition of ACh release. In contrast, the alpha 2-selective agonist, BHT-920, caused no change in heart rate during vagal stimulation. The effects of phenylephrine to raise heart rate and blood pressure during vagal stimulation were blocked by the alpha 1-selective antagonist prazosin (ID50 approximately 1 microgram/kg) but not by the alpha 2-selective antagonists yohimbine and rauwolscine. This further supports an alpha 1 assignment to the prejunctional adrenergic receptor mechanism, which can regulate the release of acetylcholine from cardiac parasympathetic neurons.

Axonal transport of receptors: characterization, role in receptor regulation and possible involvement in learning

There is an increasing amount of evidence indicating that presynaptic receptors move antero- and retrogradely along axons of neurones through axoplasmic transport mechanisms. The main features of this dynamic process will be presented: it is bidirectional, fast, microtubule dependent and associated with vesicles which are presumably recycled in the cell body. Receptor axonal transport is impaired or enhanced in certain pathological conditions. The implications of this process and its possible involvement in long-term memory will be discussed.