Response of limbic neurotensin systems to methamphetamine self-administration.

Methamphetamine (METH) abuse is personally and socially devastating. Although effects of METH on dopamine (DA) systems likely contribute to its highly addictive nature, no medications are approved to treat METH dependence. Thus, we and others have studied the METH-induced responses of neurotensin (NT) systems. NT is associated with inhibitory feedback action on DA projections, and NT levels are elevated in both the nucleus accumbens and dorsal striatum after noncontingent treatment with high doses of METH. In the present study, we used a METH self-administration (SA) model (linked to lever pressing) to demonstrate that substitution of an NT agonist for METH, while not significantly affecting motor activity, dramatically reduced lever pressing but was not self-administered per se. We also found that nucleus accumbens NT levels were elevated via a D1 mechanism after five sessions in rats self-administering METH (SAM), with a lesser effect in corresponding yoked rats. Extended (15 daily sessions) exposure to METH SA manifested similar NT responses; however, more detailed analyses revealed (i) 15 days of METH SA significantly elevated NT levels in the nucleus accumbens shell and dorsal striatum, but not the nucleus accumbens core, with a lesser effect in the corresponding yoked METH rats; (ii) the elevation of NT in both the nucleus accumbens shell and dorsal striatum significantly correlated with the total amount of METH received in the self-administering, but not the corresponding yoked METH rats; and (iii) an NT agonist blocked, but an NT antagonist did not alter, lever-pressing behavior on day 15 in SAM rats. After 5 days in SAM animals, NT levels were also elevated in the ventral tegmental area, but not frontal cortex of rats self-administering METH.

Sex-dependent effects of chronic unpredictable stress in the water maze.

Exposure to chronic predictable stress, such as restraint, can affect performance on spatial memory tasks and these effects have been shown to be sex-specific in rats. It is not known whether unpredictable stress has similar sex-specific effects on spatial memory and whether those effects are present after the stress procedure has ended. Therefore, the current study tested male and female rats in the Morris water maze either immediately or 3 weeks following exposure to 10 days of unpredictable stress (CUS). Male and female rats were exposed to 10 days of stressors that varied by type and time of stressor application. Exposure to CUS decreased the distance swam to locate the hidden platform during acquisition training in the water maze for female but not male rats. Overall, male rats performed better than female rats during the acquisition, probe and matching to place trials. These effects were observed when assessing spatial memory performance immediately or 3 weeks following the last stressor. Plasma corticosterone levels followed the behavioral differences during the acquisition trials in that control female rats had increased basal and swim-stimulated corticosterone levels compared to CUS female rats and control male rats. These data demonstrate that unpredictable stress influences performance on the water maze in a sex-specific manner, which parallel plasma corticosterone levels. The improved performance of female rats following CUS exposure was present 3 weeks after the termination of the stress procedures, suggesting that stress may have lasting effects on underlying neural systems.