Subcellular distribution of mammalian tachykinins in rat basal ganglia

Influence of maternal pineal gland on the developmental pattern of neurokinin A (NKA) and substance P (SP) in male-rat-offspring: relationship to the season of the year

The present study examines the influence of maternal pineal gland on the frontal cortex, striatal and testicular concentrations of the tachykinins, neurokinin A (NKA) and substance P (SP). Control, pinealectomized (PIN-X) and PIN-X plus melatonin-treated (PIN-X + MEL) mother rats were prepared. Male offspring rats were studied at 21, 31 and 60 days of age, during the four seasons of the year. In control-offspring tachykinin concentrations in frontal cortex were found at their highest levels in 21-day-old rats with a moderate decrease up to 60 days of age. This developmental pattern was season-dependent, observed only during summer and fall. Maternal PIN-X or PIN-X + MEL resulted in alterations in the offspring, showing during spring and summer significantly higher concentrations (P < 0.01) and during fall significantly lower concentrations of tachykinins in the frontal cortex (P < 0.05, P < 0.01) as compared to control-offspring. The tachykinin concentration in the striatum of control-offspring showed no major modifications throughout the ages studied in the four seasons of the year. With very few exceptions, PIN-X- and PIN-X + MEL did not alter tachykinin concentrations in striatum. Testicular SP concentrations showed a decrease from 21 to 60 days of age. PIN-X or PIN-X + MEL only caused minor and inconsistent modifications in testicular SP levels. In conclusion, our data clearly indicate for the first time that the maternal pineal gland participates in the regulation of the postnatal tachykinin development in some areas of the central nervous system. This effect was more evident in the frontal cortex than in the striatum and testes.

Distribution and neurochemical character of substance P receptor (SPR)-immunoreactive striatal neurons of the macaque monkey: accumulation of SP fibers and SPR neurons and dendrites in "striocapsules" encircling striosomes

The striatal distribution of the substance P receptor (SPR) protein was examined in relation to its ligand, the neuro-peptide SP, as well as to the neurochemical and compartmental composition of the neostriatum in rhesus monkeys (Macaca mulatta) in immunohistochemical experiments. About 2% of striatal neurons, displaying varicose, virtually spine-free dendrites characteristic of large and medium-sized aspiny interneurons, expressed SPR immunoreactivity. SPR/choline acetyltransferase, SPR/somatostatin, SPR/GABA, SPR/calbindin D28k, and SPR/parvalbumin double immunolabeling experiments demonstrated that SPR-positive cells are either cholinergic or somatostatinergic. Comparison of SP and SPR immunoreactivities in double-labeled and adjacent single-labeled sections revealed compartment-specific match and mismatch between the densities of the peptide and receptor. A matching high density of SP fibers and SPR cells and dendrites was only observed in the rim of the striosome compartments. To our knowledge, this is the first evidence for an anatomical border comprised of dendritic processes that separate striatal compartments. We have termed these zones "striocapsules," because they encircle and encapsulate striosomal cell islands. In the striatal matrix, an abundance of SPR-labeled profiles was complemented with light SP staining. By contrast, in the core of the striosomes, SPR labeling was sparse and SP staining intense. SP-positive axon-like puncta frequently contacted SPR-positive dendrites in all striatal compartments. The SP receptor/ligand match indicates a sharp increase in the efficacy of SP action in the striocapsules, and suggests that the influence of SP might be heightened in this striatal subcompartment.

Regulation of substance P receptor system in rat striatum by chronic naltrexone treatment

Chronic blockade of opioid receptors by naltrexone increases opioid peptides in the striatum, and up-regulates brain opioid receptors resulting in functional supersensitivity. Striatal SP content was increased 3.5-fold after 8 days of naltrexone treatment relative to control animals. The present study was undertaken to determine whether SP receptors in the striatum and SP receptor-coupled second messenger system are modulated by increased striatal SP content induced by chronic opioid receptor blockade. The binding affinity and capacity of SP receptors, determined using [125I]Bolton-Hunter SP ([125I]BHSP) labeled at Lys3, in striatal synaptosomal membranes were not significantly altered by chronic blockade of opioid receptors. Although the concentrations of [Sar9,Met (O2)11]SP, a NK-1 receptor-specific agonist, and SP(1-7), an aminoterminal major metabolite of SP, required to inhibit half of [125I]BHSP binding (IC50) in striatal synaptosomal membranes were significantly decreased, the IC50s for SP and an NK-2 receptor-specific agonist, [Nle10]NK A (4-10), remained unchanged by chronic naltrexone treatment. The data suggest that naltrexone which has no SP receptor antagonistic action, not only indirectly acts on SP-ergic neurons but also causes a change in the apparent affinity of NK-1 receptor (as reflected by changes in IC50 values) in the striatum. Cellular inositol-1,4,5-trisphosphate [Ins(1,4,5)P3], quantified by a highly sensitive and selective radioreceptor mass assay, was increased in the striatum by 28% relative to control levels. With [3H]Ins(1,4,5)P3 as a ligand, Scatchard analyses of the concentration-dependent saturation curves showed that the density of striatal intracellular Ins(1,4,5)P3 receptors was increased by 53%. The levels of SP and cellular Ins(1,4,5)P3, and the density of Ins(1,4,5)P3 receptors in the cerebellum, used as a positive control, were unchanged by chronic naltrexone treatment. The findings of opiate antagonist-induced increases in SP striatal content and Ins(1,4,5)P3 receptor densities, appear to support the concept of a role of endogenous opioids in the regulation of SP receptor activity. The data also suggest that inter-regulatory mechanisms exist between phospholipase C/phosphoinositide-coupled receptors such as SP receptors, and adenylate cyclase-coupled inhibitory receptors, such as opioid receptors.

Effect of substance P on acetylcholine and dopamine release in the rat striatum: a microdialysis study

In vivo microdialysis in urethane anaesthetised rats was used to investigate the effects of substance P (SP) on acetylcholine (ACh) and dopamine (DA) release in the rat striatum. Results showed that SP elicited a dose-dependent increase in ACh release between 1 and 50 pmol/l. The rise in ACh release occurred both during SP administration and for up to 60 min after it. Dose-response curves either based on the initial rise in ACh release, or the total duration of increased release, showed a bell shape with 100 fmol/l and 5 nmol/l doses failing to significantly alter release and a 500 pM dose being less effective than 50 pmol/l. In contrast to this, SP did not significantly alter DA release at doses ranging between 100 fmol/l and 5 nmol/l. There was evidence for a strong desensitisation effect of SP administration since after initial treatment with SP subsequent doses of the peptide, even at very high doses, failed to provoke further changes in ACh still showed the expected increase in release in response to a potassium challenge. Physalaemin and neurokinin A increased ACh release with a similar potency to SP at a 50 pmol/l dose whereas neurokinin B and neuropeptide gamma, while increasing ACh release at a 50 pmol/l dose, were less potent than SP. The effect of SP on ACh release is probably mediated via NK-1 receptors since ACh release in response to SP was reduced in a dose dependent manner by the NK-1 receptor antagonists CP-96,345 and RP-67580.

Biochemical characterization of particles from rat striatum containing dopamine, cholecystokinin or both

Cholecystokinin (CCK) containing particles were isolated from rat striatum. After differential and isopycnic sucrose density gradient centrifugation, CCK containing particles equilibrated around 1.2 M sucrose. Dopamine (DA) containing particles equilibrated around the same buoyant density, but the colocalization of a cytosolic as well as a mitochondrial enzyme marker and the low enrichment at this density indicated an incomplete isolation of CCK containing particles from other subcellular organelles. Alternatively, differential centrifugation and gel filtration on Sephacryl S-1000 did yield advanced isolation of CCK containing vesicles. These vesicles also contain particle-bound DA. During hypo-osmotic lysis, these CCK and/or DA containing particles behaved like synaptic vesicles. Therefore, it was concluded that CCK containing vesicles from rat corpus striatum were indeed isolated and characterized and that the same or similar vesicles contain DA as well as CCK.

In vitro and in vivo release of neurokinin A-like immunoreactivity from rat substantia nigra

In vivo and in vitro perfusion techniques have been used to study the release of neurokinin A-like immunoreactivity from the rat substantia nigra. Potassium depolarization and electrical field stimulation evoked calcium-dependent release from nigral slices. Potassium depolarization was also effective in vivo. Tetrodotoxin (1 microM) completely blocked electrically stimulated release but only diminished release in response to depolarizing potassium. Neurokinin A-like immunoreactivity release showed frequency dependence and a clear facilitation phenomenon between 5 and 25 Hz. High-performance liquid chromatography analysis of the immunoreactivity released in vitro revealed the presence of neurokinin A, neuropeptide K and neurokinin B, along with their sulphoxide forms. A marked depletion of neuropeptide K and neurokinin B content was observed when the tachykinin content of the nigral slices was examined before and after stimulation. However, the neurokinin A content of the slices was unchanged or even increased, suggesting an accelerated processing of neurokinin A precursors during the stimulation. The tachykinin peptides were degraded at different rates by substantia nigra homogenates; degradation was fastest for neuropeptide K and slowest for neurokinin A. The addition of a mixture of peptidases inhibitors (thiorphan, phosphoramidon, bestatin and captopril) substantially reduced the degradation of all three tachykinins, but did not completely block degradation. GABA-A receptor antagonists such as bicuculline and, particularly, picrotoxin potentiated the stimulated neurokinin A-like immunoreactivity release in vitro, but the GABA-agonist muscimol had no effect. Picrotoxin was even more potent in vivo. The results presented in this study demonstrate that neurokinin A, neuropeptide K and neurokinin B can be released by depolarizing stimuli from rat substantia nigra. Furthermore, the features exhibited by this release suggest that these peptides may have a neurotransmitter/neuromodulator role in the rat substantia nigra.