The low affinity neurotensin receptor antagonist levocabastine impairs brain nitric oxide synthesis and mitochondrial function by independent mechanisms.

Neurotensin is known to inhibit neuronal Na+ , K+ -ATPase, an effect that is rescued by nitric oxide (NO) synthase inhibition. However, whether the neurotensinergic and the nitrergic systems are independent pathways, or are mechanistically linked, remains unknown. Here, we addressed this issue and found that the administration of low affinity neurotensin receptor (NTS2) antagonist, levocabastine (50 µg/kg, i.p.) inhibited NO synthase (NOS) activity by 74 and 42% after 18 h in synaptosomal and mitochondrial fractions isolated from the Wistar rat cerebral cortex, respectively; these effects disappeared 36 h after levocabastine treatment. Intriguingly, whereas neuronal NOS protein abundance decreased (by 56%) in synaptosomes membranes, it was enhanced (by 86%) in mitochondria 18 h after levocabastine administration. Levocabastine enhanced the respiratory rate of synaptosomes in the presence of oligomycin, but it failed to alter the spare respiratory capacity; furthermore, the mitochondrial respiratory chain (MRC) complexes I-IV activities were severely diminished by levocabastine administration. The inhibition of NOS and MRC complexes activities were also observed after incubation of synaptosomes and mitochondria with levocabastine (1 µM) in vitro. These data indicate that the NTS2 antagonist levocabastine regulates NOS expression and activity at the synapse, suggesting an interrelationship between the neurotensinergic and the nitrergic systems. However, the bioenergetics effects of NTS2 activity inhibition are likely to be independent from the regulation of NO synthesis.

The Administration of Levocabastine, a NTS2 Receptor Antagonist, Modifies Na(+), K(+)-ATPase Properties.

Neurotensin behaves as a neuromodulator or as a neurotransmitter interacting with NTS1 and NTS2 receptors. Neurotensin in vitro inhibits synaptosomal membrane Na(+), K(+)-ATPase activity. This effect is prevented by administration of SR 48692 (antagonist for NTS1 receptor). The administration of levocabastine (antagonist for NTS2 receptor) does not prevent Na(+), K(+)-ATPase inhibition by neurotensin when the enzyme is assayed with ATP as substrate. Herein levocabastine effect on Na(+), K(+)-ATPase K(+) site was explored. For this purpose, levocabastine was administered to rats and K(+)-p-nitrophenylphosphatase (K(+)-p-NPPase) activity in synaptosomal membranes and [(3)H]-ouabain binding to cerebral cortex membranes were assayed in the absence (basal) and in the presence of neurotensin. Male Wistar rats were administered with levocabastine (50 µg/kg, i.p., 30 min) or the vehicle (saline solution). Synaptosomal membranes were obtained from cerebral cortex by differential and gradient centrifugation. The activity of K(+)-p-NPPase was determined in media laking or containing ATP plus NaCl. In such phosphorylating condition enzyme behaviour resembles that observed when ATP hydrolyses is recorded. In the absence of ATP plus NaCl, K(+)-p-NPPase activity was similar for levocabastine or vehicle injected (roughly 11 µmole hydrolyzed substrate per mg protein per hour). Such value remained unaltered by the presence of 3.5 × 10(-6) M neurotensin. In the phosphorylating medium, neurotensin decreased (32 %) the enzyme activity in membranes obtained from rats injected with the vehicle but failed to alter those obtained from rats injected with levocabastine. Levocabastine administration enhanced (50 %) basal [(3)H]-ouabain binding to cerebral cortex membranes but failed to modify neurotensin inhibitory effect on this ligand binding. It is concluded that NTS2 receptor blockade modifies the properties of neuronal Na(+), K(+)-ATPase and that neurotensin effect on Na(+), K(+)-ATPase involves NTS1 receptor and -at least partially- NTS2 receptor.

Neurotensin decreases high affinity [3H]-ouabain binding to cerebral cortex membranes.

Previous work from this laboratory showed the ability of neurotensin to inhibit synaptosomal membrane Na(+), K(+)-ATPase activity, the effect being blocked by SR 48692, a non-peptidic antagonist for high affinity neurotensin receptor (NTS1) [López Ordieres and Rodríguez de Lores Arnaiz 2000; 2001]. To further study neurotensin interaction with Na(+), K(+)-ATPase, peptide effect on high affinity [(3)H]-ouabain binding was studied in cerebral cortex membranes. It was observed that neurotensin modified binding in a dose-dependent manner, leading to 80% decrease with 1 × 10(-4)M concentration. On the other hand, the single addition of 1 × 10(-6)M, 1 × 10(-5)M and 1 × 10(-4)M SR 48692 (Sanofi-Aventis, U.S., Inc.) decreased [(3)H]-ouabain binding (in %) to 87 ± 16; 74 ± 16 and 34 ± 17, respectively. Simultaneous addition of neurotensin and SR 48692 led to additive or synergic effects. Partial NTS2 agonist levocabastine inhibited [(3)H]-ouabain binding likewise. Saturation assays followed by Scatchard analyses showed that neurotensin increased K(d) value whereas failed to modify B(max) value, indicating a competitive type interaction of the peptide at Na(+), K(+)-ATPase ouabain site. At variance, SR 48692 decreased B(max) value whereas it did not modify K(d) value. [(3)H]-ouabain binding was also studied in cerebral cortex membranes obtained from rats injected i. p. 30 min earlier with 100 µg and 250 µg/kg SR 48692. It was observed that the 250 µg/kg SR 48692 dose led to 19% decrease in basal [(3)H]-ouabain binding. After SR 48692 treatments, addition of 1 × 10(-6)M led to additive or synergic effect. Results suggested that [(3)H]-ouabain binding inhibition by neurotensin hardly involves NTS1 receptor.

Blockade of neurotensin receptors during amphetamine discontinuation indicates individual variability.

Psychostimulant-induced locomotor sensitization has been related to changes within the mesolimbic dopamine system and has been suggested to be useful to study mechanisms underlying drug craving. Neurotensin is a neuropeptide co-localized with dopamine in the mesolimbic system. The response to novelty has been suggested to be a predictor of enhanced vulnerability to behavioral sensitization. The effects of repeated treatment with the neurotensin antagonist SR48692 after amphetamine discontinuation were investigated in mice previously classified as high responders (HRs) or low responders (LRs) to novelty. Mice were repeatedly treated with 2.0mg/kg amphetamine, every other day for 11 days. During the first 7 days after amphetamine discontinuation, the animals received a daily injection of saline or 0.3mg/kg SR48692. On the eighth day after amphetamine discontinuation all subjects received a 2.0mg/kg amphetamine challenge injection. Then, mice were tested for an open field behavior and after 90min, were sacrificed for Fos expression quantification in the nucleus accumbens. Both HRs and LRs expressed amphetamine-induced sensitized locomotor activation and increased expression of Fos protein. Treatment with SR48692 prevented behavioral sensitization and Fos protein expression enhancement in LRs but not in HRs mice. These data suggest that neurotensin plays a role in individual variability to amphetamine-induced sensitization.

Microinfusions of neurotensin antagonist SR 48692 within the nucleus accumbens core impair spatial learning in rats.

The involvement of neurotensin (NT) within the nucleus accumbens core (NAC) in behavior has been sparsely investigated. Moreover, little is known of what role NT within the ventral striatum has on spatial learning. The present study investigated whether NT receptors in the NAC are implicated in learning of spatial information. Male Long-Evans rats were trained on a food search spatial learning task. Rats were microinfused with either NT antagonist SR 48692 (50 nM/0.5 =L) or saline in the NAC before each training session. Rats treated with SR 48692 made more reference and working memory errors during the acquisition of spatial learning than did rats infused with saline. These results suggest that NT receptors contribute to NAC-mediated spatial learning.

High-affinity neurotensin receptor is involved in phosphoinositide hydrolysis stimulation by carbachol in neonatal rat brain.

Ontogenetic studies indicate that inositol phosphate accumulation in rodent brain tissue by cholinergic muscarinic agonists as well as expression of high-affinity neurotensin receptor (NTS1) peak at 7 days after birth. Herein, potential participation of this receptor in such effect was investigated. Cerebral cortex prisms of 7-day-old rats were preloaded with [3H]myoinositol and later incubated during 60 or 20 min in the presence of muscarinic agonist carbachol plus neurotensin and SR 48692, a non-peptide NTS1 antagonist. In 60-min incubation experiments, inositol phosphate accumulation by 10(-3) M carbachol was roughly 320%, an effect which remained unaltered plus 10(-6) M to 10(-4) M neurotensin but partially decreased with equimolar SR 48692 concentration. In 20-min incubation experiments, inositol phosphate accumulation by 10(-3) M carbachol was circa 240%, a value which attained 320-360% plus 10(-7) M neurotensin; this effect was totally blocked by 10(-7) M SR 48692. It was concluded that in inositol phosphate accumulation by carbachol, besides the cholinergic muscarinic receptor, the NTS1 receptor is likewise involved; findings at 60 min are attributable to the effect of endogenous neurotensin whereas those at 20 min most likely involve both endogenous and exogenously added peptide.

Neurotensin modulates synaptic transmission in the nucleus of the solitary tract of the rat.

Whole-cell patch clamp recordings were made from neurons of the rat subpostremal region of the nucleus tractus solitarius (NTS) in transverse brainstem slices. Neurotensin (NT) enhanced the firing rate of action potentials from 0.8 +/- 0.4 Hz in control to 1.9 +/- 1.3 Hz (n = 9) and increased their decay time. The peak amplitude of the after-hyperpolarization was decreased by 34+/-5% (n = 9). These effects were associated with a depolarization of 4 +/- 1 mV (n = 10) in the resting membrane potential and an increase in the input resistance (from 768 +/- 220 MOmega to 986+/-220 MOmega; n = 5) and were compensated by manually hyperpolarizing the cell to control values. In voltage clamp experiments NT decreased an outward current (from 488 +/- 161 to 340 +/- 96 pA at +40 mV; n = 5) which reversed near the potassium equilibrium potential. In addition, NT increased the frequency of both excitatory and inhibitory spontaneous synaptic currents, an effect blocked by tetrodotoxin, and did not change the evoked excitatory or inhibitory postsynaptic currents. The selective NTR1 receptor antagonist SR48692 reversibly blocked the effects of NT on both action potentials and spontaneous synaptic currents. Our results suggest that NTR1 receptors can modulate post-synaptic responses in neurons of the subpostremal NTS by increasing cell excitability as a result of blockade of a potassium conductance.

K(+)-p-nitrophenylphosphatase inhibition by neurotensin involves high affinity neurotensin receptor: influence of potassium concentration and enzyme phosphorylation.

Neurotensin (NT), a 13-amino acid peptide, is widely distributed in the brain and peripheral tissues of several mammalian species including man. In adult rat brain NT can bind to two distinct sites, one of high and the other of low affinity, corresponding to NT(1) and NT(2) receptor, respectively; structurally unrelated to these two, a third NT receptor (NT(3)) has been described. We have previously shown that Na(+), K(+)-ATPase is inhibited by NT when using ATP as substrate. In order to determine whether K(+)-stimulated dephosphorylation of this enzyme is involved, we tested NT effect by using p-nitrophenylphosphate, a non-natural substrate. K(+)-p-nitrophenylphosphatase activity was inhibited 42% by NT at 8.6 x 10(-6) M using an incubation medium containing 2 mM KCl but was unaffected in the presence of 5 or 20 mM KCl; however, with such KCl concentrations, NT was enabled to inhibit enzyme activity ( congruent with 35%) provided a suitable ATP:NaCl mixture (0.6:45.0 mM) was added. Mg(2+)-p-nitrophenylphosphatase activity remained unaltered at all conditions tested. Since SR 48692, a selective non-peptide NT(1) antagonist, abolished NT effect, involvement of NT(1) receptor in enzyme inhibition is suggested.

The neurotensin receptor antagonist, SR48692, attenuates the expression of amphetamine-induced behavioural sensitisation in mice.

The effects of acute administration of the neurotensin receptor antagonist, SR48692 (2-[[1-(7-chloroquinolin-4-yl)-5-(2,6-dimethoxyphenyl)-1H-pyrazol-3-carbonyl]amino]adamantane-2-carboxylic acid), on amphetamine-induced behavioural sensitisation were studied with the locomotor activity of mice in an open-field as an experimental parameter. The animals were repeatedly pretreated with saline or amphetamine (2.0 mg/kg, i.p. once a day, every other day for 13 days) and 2, 9 and 16 days after the last injection they received an acute i.p. administration of saline or 0.3 mg/kg SR48692 15 min before a challenge i.p. injection of 2.0 mg/kg amphetamine. Locomotor activity of the amphetamine-challenged mice was significantly higher in amphetamine-pretreated animals than in saline-pretreated mice on days 9 and 16 after withdrawal. SR48692 prevented the expression of this behavioural sensitisation. In addition, in saline-pretreated mice, the first two challenge injections of amphetamine sufficed to induce a sensitized locomotor response to the third challenge injection of the drug. SR48692 administration before amphetamine challenge injections prevented the development of this challenge injection-induced sensitisation in saline-pretreated mice but not in amphetamine-pretreated animals. In order to determine the effects of SR48692 on the expression of amphetamine-induced behavioural sensitisation in the absence of this challenge injection-induced sensitisation, the experiment was redone with a single challenge test 9 days after pretreatment. Once again, SR48692 prevented the expression of amphetamine-induced behavioural sensitisation. These results suggest that neurotensinergic transmission has a critical role in both the initiation and expression of locomotor sensitisation to amphetamine.

Release-depletion and receptor-mediated neuronal internalization of endogenous neurotensin in the stellate ganglion of the cat.

The release and depletion of neurotensin in sympathetic preganglionic axon terminals and internalization in principal ganglion cells were investigated in the cat stellate ganglion by means of combined immunohistochemical staining, image analysis and confocal microscopy. Neurotensin stored in preganglionic boutons was released by 40 or 5 Hz electrical stimulation of preganglionic nerves, being depleted to 7.4 and 19.2% of control levels by continuous stimulation lasting 20 or 160 min (both stimuli delivered 48,000 pulses). Once released, neurotensin was internalized by the principal ganglion cells as evidenced by a ring of bright spot-like granules in the perinuclear region indicating the sites of intracellular neurotensin accumulation. Neurotensin internalization was time-dependent, thus, different content was found when the time between the end of stimulation and start of perfusion was varied. The onset of neurotensin internalization appeared in the first minutes, intracellular accumulation was evident at 20 min, maximal internalization occurred at 120 min and, 24 h later internalized neurotensin content had faded. Internalization was partially blocked by the nonpeptide neurotensin antagonist SR48692. These data provide evidence of presynaptic neurotensin release and depletion by electrical stimulation with varied frequencies. They also provide evidence for in situ receptor-mediated internalization of endogenously released neurotensin, raising the possibility that internalization may represent, in addition to some kind of turnover dynamics, an important part of the mechanisms of neuropeptide signaling.