Sex-specific effects of early life stress on social interaction and prefrontal cortex dendritic morphology in young rats.

Early life stress has been linked to depression, anxiety, and behavior disorders in adolescence and adulthood. The medial prefrontal cortex (mPFC) is implicated in stress-related psychopathology, is a target for stress hormones, and mediates social behavior. The present study investigated sex differences in early-life stress effects on juvenile social interaction and adolescent mPFC dendritic morphology in rats using a maternal separation (MS) paradigm. Half of the rat pups of each sex were separated from their mother for 4h a day between postnatal days 2 and 21, while the other half remained with their mother in the animal facilities and were exposed to minimal handling. At postnatal day 25 (P25; juvenility), rats underwent a social interaction test with an age and sex matched conspecific. Distance from conspecific, approach and avoidance behaviors, nose-to-nose contacts, and general locomotion were measured. Rats were euthanized at postnatal day 40 (P40; adolescence), and randomly selected infralimbic pyramidal neurons were filled with Lucifer yellow using iontophoretic microinjections, imaged in 3D, and then analyzed for dendritic arborization, spine density, and spine morphology. Early-life stress increased the latency to make nose-to-nose contact at P25 in females but not males. At P40, early-life stress increased infralimbic apical dendritic branch number and length and decreased thin spine density in stressed female rats. These results indicate that MS during the postnatal period influenced juvenile social behavior and mPFC dendritic arborization in a sex-specific manner.

Enhancing the salience of dullness: behavioral and pharmacological strategies to facilitate extinction of drug-cue associations in adolescent rats.

Extinction of drug-seeking is an integral part of addiction treatment, and can profoundly reverse or ameliorate the harmful consequences of drug use. These consequences may be the most deleterious during adolescence. The studies presented here build from recent evidence that adolescent rats are more resistant to extinction training than adults, and therefore may require unique treatment strategies. We used unbiased place-conditioning in male rats to show that passive, un-explicit extinction pairings resulted in delayed extinction in 40-day-old adolescents relative to 80-day-old adults. However, explicit-pairing of a previously cocaine-associated context with the absence of drug produces extinction in adolescents as rapidly as in adults. These data suggest that successful extinction of drug-paired associations in adolescents may be facilitated by stronger acquisition of a new (extinction) memory. Drug-paired associations are largely controlled by the prelimbic prefrontal cortex (plPFC) and its influence on the nucleus accumbens (NAc). This pathway mediates the motivational salience attributed to incoming stimuli through the D1 dopamine receptor. D1 receptors on plPFC outputs to the accumbens are transiently overproduced during adolescence. Since D1 receptors are selectively responsive to potent stimuli, we hypothesized that the adolescent plPFC hinders competition between potent drug-paired associations and the subtler, drug-free information necessary for extinction. To harness this unique profile of the adolescent plPFC, we aimed to increase the salience of unrewarded extinction memories by activating plPFC D1 receptors during extinction training. In a second study, extinction of drug-cue associations was facilitated in adolescents by elevating dopamine and norepinephrine in the PFC during extinction training with atomoxetine. In a third study, direct microinjection of the D1 receptor agonist SKF38393 mimicked this effect, also facilitating extinction in adolescent subjects. Furthermore, pharmacological intervention attenuated subsequent drug-primed reinstatement of cocaine-conditioned preferences. We establish a potential direction for distinct strategies to treat this vulnerable population.

c-Fos and deltaFosB expression are differentially altered in distinct subregions of the nucleus accumbens shell in cocaine-sensitized rats.

Repeated cocaine administration in rats can lead to sensitization as evidenced by an increased locomotor response to a subsequent exposure (challenge) dose of cocaine even after a drug-free period. Expression of the immediate early gene product, c-Fos, differs among distinct subregions of the nucleus accumbens shell. This would suggest that these subregions may be differentially involved in sensitization. The present study quantified c-Fos- and deltaFosB-immunoreactive nuclei in subterritories of the nucleus accumbens in animals behaviorally sensitized to cocaine. Rats received a sensitization-inducing regimen of cocaine (twice-daily injections of 15 mg/kg i.p. for five consecutive days). Fourteen days following the last injection, rats were given a challenge injection of cocaine (15 mg/kg i.p.), and killed 2 h later. Sections through the nucleus accumbens were processed for tyrosine hydroxylase and either c-Fos or deltaFosB. The number of immunoreactive nuclei was quantified in five subregions of the nucleus accumbens shell: the vertex, arch, cone, intermediate zone and ventrolateral zone, which can be identified by differential histological staining for tyrosine hydroxylase. Repeated cocaine administration resulted in robust sensitization that was associated with more deltaFosB in the vertex, arch, and cone compared with saline-treated controls. As previously reported, c-Fos immunoreactivity was increased in the intermediate zone in cocaine-sensitized rats. deltaFosB was significantly elevated in rats that did not receive a cocaine challenge, attesting to the long half-life of this transcription factor. These results provide further evidence suggesting distinct anatomical neuroadaptations within the nucleus accumbens shell that may play a functional role in psychomotor-stimulant sensitization.