Inverse agonists of the 5-HT2A receptor reduce nicotine withdrawal signs in rats.

Previous work has shown that chronic nicotine administration causes adaptive changes in 5-HT2A receptor expression. Based on this relationship, it was hypothesized that inactivating 5-HT2A receptors with the inverse agonists pimavanserin and volinanserin (MDL100907), would reduce the symptoms of nicotine withdrawal syndrome. Sprague-Dawley rats were rendered nicotine-dependent by subcutaneous infusion of nicotine bitartrate, 9 mg/kg/day for seven days. The infusions were then terminated, and 22 h later, rats were observed under "blind" conditions for somatically expressed behavioral nicotine withdrawal signs. One hour before observations, the nicotine dependent rats were injected i.p. with saline alone, or either 0.3 or 1.0 mg/kg pimavanserin in saline. Total withdrawal signs were reduced in a dose-dependent manner. A one-way ANOVA (total withdrawal signs as a function of dose) was highly significant, as was the descending linear trend of withdrawal signs as a function of dose. The 1.0 mg/kg dose reduced withdrawal signs nearly to the level exhibited by a comparison group of non-dependent rats injected with saline. A second experiment was conducted in a similar manner, which showed that volinanserin at 1.0 mg/kg but not 0.25 mg/kg also reduced nicotine withdrawal signs to nearly the level of non-dependent rats. In vitro experiments demonstrated that both pimavanserin and volinanserin potently antagonize 5-HT2A receptors, with approximately 25-fold, and 300-fold selectivity over 5-HT2C receptors, respectively. The results suggest that the 5-HT2A receptor contributes to mediating nicotine withdrawal syndrome, and thus represents a potential target for interventions to aid smoking cessation.

A subtype-specific neuropeptide FF receptor antagonist attenuates morphine and nicotine withdrawal syndrome in the rat.

Considerable evidence suggests the Neuropeptide FF (NPFF) and related peptides exert pro-nociceptive and anti-opiate actions, particularly at the supra-spinal level, which may contribute to opiate dependence. The FF1 receptor subtype appears to be primarily responsible for anti-opiate effects. In contrast, stimulation of the FF2 receptor primarily induces pro-opiate effects. AC-262620 is a small molecule, systemically active, selective FF1 receptor antagonist. An initial experiment showed that 10 mg/kg i.p. AC-262620 significantly reduced subsequent naloxone-precipitated somatically expressed withdrawal signs in rats infused s.c. for seven days with 0.3 mg/kg/hr morphine sulfate. A second experiment showed that the same dose of AC-262620 significantly reduced subsequent spontaneous withdrawal signs 23.75 h after termination of seven days s.c. infusion of 0.6 mg/kg/hr morphine sulfate. Chronic nicotine intake may contribute to dependence by overstimulating opiate receptors through release of opiate peptides. By analogy to opiate dependence, it was hypothesized that FF1 receptor activation contributes to nicotine dependence and withdrawal syndrome. AC-262620 significantly reduced somatically expressed withdrawal signs precipitated by the nicotinic antagonist mecamylamine in rats infused for seven days with nicotine bitartrate. Taken together, these findings suggest that NPFF or related neuropeptides contribute to opiate, as well as nicotine, dependence and withdrawal syndrome through the FF1 receptor.

Reversal of morphine tolerance by a compound with NPFF receptor subtype-selective actions.

Neuropeptide FF (NPFF) modulates opiate actions. It has pro-nociceptive effects, primarily through the NPFF receptor 1 subtype, and anti-nociceptive effects, primarily through the NPFFR2 subtype. AC-263093 is a small l, organic, systemically active molecule that was previously shown to functionally activate NPFFR2, but not NPFFR1. It was hypothesized that AC-263093 would attenuate morphine tolerance. Rats were tested for radiant heat tail-flick latency before and after 5 mg/kg morphine sulfate s.c. They were then rendered morphine-tolerant by continuous subcutaneous infusion of 17.52 mg/kg/day morphine sulfate. On the seventh day of infusion, they were retested for analgesia 10 and 20 min after 5mg/kg morphine sulfate s.c. Tolerance was indicated by reduction of morphine analgesia from the pre-infusion test. Fifty minutes prior to morphine challenge, rats received either 10 mg/kg i.p. AC-263093 or injection vehicle alone. AC-2623093-treated rats had far smaller tolerance scores than control rats. This drug effect was significant, p = 0.015. The same dose of AC-263093 had almost no analgesic effect in non-tolerant, saline-infused rats. In vitro experiments revealed that AC-263093 had equal affinity for NPFFR1 and NPFFR2, and functionally inactivated NPFFR1, in addition to its previously shown ability to activate NPFFR2. Thus, altering the balance between activation of NPFF receptor subtypes may provide one approach to reversing opiate tolerance.

Validation and scopolamine-reversal of latent learning in the water maze utilizing a revised direct platform placement procedure.

The Morris water maze is routinely used to explore neurobiological mechanisms of working memory. Humans can often acquire working memory relevant to performing a task by mere sensory observation, without having to actually perform the task followed by reinforcement. This can be modeled in the water maze through direct placement of a rat on the escape platform so that it can observe the location, and then assessing the subject's performance in swimming back to the platform. However, direct placement procedures have hardly been studied for two decades, reflecting a controversy about whether direct placement resulted in sufficiently rapid and direct swims back to the platform. In the present study, utilizing revised training methods, a more comprehensive measure of trajectory directness, a more rigorous sham-trained control procedure and an optimal placement-test interval, rats swam almost directly back to the platform in under 4s, significantly more quickly and directly than sham-trained subjects. Muscarinic cholinergic mechanisms, which are inactivated by scopolamine, are essential to memory for standard learning paradigms in the water maze. This experiment determined whether this would also be true for latent learning. ANOVA revealed significant negative effects of scopolamine on both speed and accuracy of trajectory, as well as significant positive effects of direct placement training vs. sham-training. In a probe trial, placement-trained animals without scopolamine spent significantly more time and path length in the target quadrant than trained rats with scopolamine and sham-trained rats without scopolamine. Scopolamine impairments are likely due to effects on memory, since the same dose had little effect on performance with a visible platform. The revised direct placement model offers a means of further comparing the neural mechanisms of latent learning with those of standard instrumental learning.