Stephanie L. Collins

Chronic nicotine differentially alters cocaine-induced locomotor activity in adolescent vs. adult male and female rats.

Tobacco use is prevalent in the adolescent population. It is a major concern because tobacco is highly addictive and has also been linked to illicit drug use. There is not much research, however, on the interaction between nicotine and other stimulant drugs in animal models of early adolescence. This study examined the effects of chronic nicotine alone and on cocaine-stimulated activity in male and female periadolescent rats compared to male and female adult rats. During the seven-day nicotine pretreatment period, nicotine increased locomotor activity in all groups compared to vehicle controls. Male and female adult rats and female periadolescent rats developed sensitization to the locomotor-activating effects of nicotine over the 7-day treatment period, while male periadolescent rats did not. All groups treated with nicotine, however, exhibited sensitization to nicotine-induced repetitive motion over the 7-day nicotine treatment period. On day 8, male periadolescent rats pretreated with nicotine were more markedly sensitized to the locomotor-activating effects of cocaine than male adult rats, while female rats pretreated with nicotine were not sensitized to cocaine. In contrast, male and female periadolescent rats, but not adult rats, had increased amounts of repetitive beam breaks induced by cocaine after nicotine pretreatment. Overall, it appears that cross-sensitization to cocaine is greater in periadolescent than in adult rats, and that males are more sensitized than females. Thus, it may be that nicotine use during adolescence carries a greater risk than during adulthood and that male adolescents may be particularly vulnerable to the risk of cocaine abuse after nicotine use. This information should be taken into account so as to help us better understand the development of drug addiction in adolescents compared to adults.

Cocaine differentially alters behavior and neurochemistry in periadolescent versus adult rats.

This study examined whether there are differences in the behavioral and neurochemical effects of cocaine in periadolescent rats compared to adult rats. Periadolescent (postnatal days 28-35) and adult rats were injected with cocaine or vehicle for 7 days. Ten days later (day 17), rats either were challenged with cocaine, or dopamine transporter and receptor and serotonin transporter binding were examined. Adult rats became sensitized to the locomotor-activating effects of cocaine and there were increases in dopamine transporter density in the caudate putamen compared to vehicle-treated adult rats. In addition, serotonin transporter densities were increased in the ventromedial caudate putamen, nucleus accumbens shell, and the olfactory tubercle in cocaine-treated adult rats compared to vehicle-treated adult rats. In contrast, periadolescent rats did not show sensitization to cocaine and there was no effect of cocaine on either dopamine or serotonin transporter densities. These findings suggest that there are different neurochemical and behavioral adaptations to repeated cocaine administration in periadolescent versus adult rats.

Effects of κ-opioid receptor agonists on long-term cocaine use and dopamine neurotransmission

kappa-Opioid receptor agonists have been suggested as treatments for cocaine addiction based on studies showing that they block cocaine-related behaviors. To determine the effects of kappa-opioid receptor agonists on long-term behavioral effects associated with cocaine and the neurochemical bases underlying these effects, rats were treated with the selective kappa-opioid receptor agonist U-69593 ((+)(5alpha,7alpha,8beta)-N-methyl-N-[7-(1-pyrrolidinyl)-1 oxaspiro[4.5]dec-8-yl]-benzeneacetamide) alone or in combination with cocaine and locomotor activity was measured daily. In addition, dopamine transporter and dopamine receptor densities were measured using autoradiographic techniques, and tyrosine hydroxylase was measured using immunoautoradiographic techniques. Treatment with U-69593 with or without cocaine decreased locomotor activity. When challenged with cocaine after a 5-day treatment period, the effects of cocaine were markedly reduced in rats initially treated with U-69593 compared to vehicle. When U-69593 was administered five times with 3-day intervals, it alone had no effect on locomotor activity but still reduced activity associated with a cocaine injection. After five daily injections, U-69593 decreased dopamine transporter and dopamine D(2) receptor densities and increased tyrosine hydroxylase levels. These changes were not seen after the 3-day interval regimen, even though cocaine-induced activity was greatly reduced. These findings show that the effects associated with daily U-69593 treatment are attenuated if the drug is administered with a greater interval, while maintaining a blockade of cocaine-induced activity. In addition, U-69593 can block cocaine-induced locomotor effects without major perturbation of the dopamine system.

Kappa opioid agonists alter dopamine markers and cocaine-stimulated locomotor activity.

To better understand the influence of κ‐opioid agonists on the effects of cocaine, rats were treated with daily injections of the selective κ‐opioid agonists U‐69593 or bremazocine. In combination with 10 mg/kg cocaine, both compounds, at a dose of 0.32 mg/kg, greatly diminished locomotor activity, and these effects were maintained over a period of 5 days. In addition, the response to a challenge injection of 10 mg/kg cocaine several days after the end of κ‐opioid agonist treatment with or without cocaine was markedly reduced. When naltrexone was given in combination with U‐69593, it blocked the reduction in cocaine‐induced locomotor activity after U‐69593 treatment alone. However, a single injection of either κ‐opioid agonist alone had no effect on cocaine‐induced locomotion several days later (i.e. no long‐term effects), suggesting that multiple injections of the κ‐opioid agonist are needed to reduce the locomotor activating effects of cocaine other than acutely. In addition, treatment with the κ‐opioid agonist U‐69593 (0.32 mg/kg) over a 5‐day period decreased dopamine transporter densities in the caudate putamen, and this was also blocked by co‐administration of naltrexone.

Role of serotonin on cocaine-mediated effects on prodynorphin gene expression in the rat brain.

The effect of the selective serotonin uptake inhibitor fluoxetine was examined on prodynorphin gene expression. Fluoxetine or vehicle was infused continuously for 7 d via osmotic minipumps into male rats. Northern blot analysis showed significant increases in prodynorphin gene expression in the hypothalamus (171% of controls) and significant decreases in the caudate putamen and nucleus accumbens (62% and 70% of controls, respectively). There were no significant changes in the hippocampus. Thus, chronic inhibition of serotonin uptake can regulate prodynorphin gene expression in the hypothalamus, caudate putamen, and nucleus accumbens. Fluoxetine effects were also evaluated in rats treated with p-chloroamphetamine (PCA), a neurotoxin that depletes serotonin. Because we previously reported that continuous infusion of cocaine for 7 d (which inhibits dopamine, serotonin, and norepinephrine uptake), or GBR 12909 (a selective dopamine uptake inhibitor), produced significant decreases in the hypothalamus and cocaine also produced a significant increase in prodynorphin gene expression in caudate putamen, regulation of prodynorphin gene expression by fluoxetine is suggested to be different from that by cocaine. Because neither a selective dopamine uptake inhibitor nor a selective serotonin uptake inhibitor produced the same effect as cocaine in the caudate putamen, this effect is likely regulated by the inhibition of norepinephrine uptake, by a combination of effects on two or three neurotransmitter transporters, or by a mechanism unrelated to transporter inhibition.

Regulation of dynorphin gene expression by κ-opioid agonist treatment

The effects of κ-opioid agonist treatment on prodynorphin mRNA expression in the rat brain were studied. Rats were treated with the selective κ-opioid agonist U-69593 or vehicle for 5 days and prodynorphin mRNA was measured on day 8 (3 days after the last injection) or 22 (17 days after the last injection). On day 8 prodynorphin mRNA was increased in the hypothalamus and decreased in the striatum, frontal cortex, and hippocampus of rats treated with U-69593. On day 22, prodynorphin mRNA was increased in the hypothalamus, frontal cortex and striatum of U-69593 treated rats. These findings suggests that κ-opioid receptor agonist treatment has long-term, continually changing effects on prodynorphin mRNA expression.

Chronic cocaine produces decreases in N/OFQ peptide levels in select rat brain regions

The interaction of opioids and stimulants is well established; however, the mechanisms that underlie the role that opioid receptors play in psychostimulant action are not. Nociceptin/orphaninFQ (N/OFQ), the endogenous agonist at NOP receptors, attenuates the behavioral effects of cocaine. The effects of cocaine on N/OFQ were examined in rats using immunoautoradiographic and RIA techniques. Chronic administration of cocaine decreased N/OFQ in medial regions of the caudate putamen, the nucleus accumbens shell, and the substantia nigra. These studies show that N/OFQ levels are altered by treatment with cocaine. Furthermore the changes in N/OFQ parallel those seen for K-opioid receptors, suggesting that the interactions between cocaine and these systems might be similar.

Depletion of serotonin decreases the effects of the kappa-opioid receptor agonist U-69593 on cocaine-stimulated activity

Treatment with a kappa-opioid receptor agonist for 5 days decreases locomotor activity and reduces activity in response to a cocaine challenge 3 days later. In addition, chronic cocaine increases kappa-opioid receptor density, striatal dynorphin, and dynorphin gene expression in the striatum. The upregulation of kappa-opioid receptors after cocaine treatment occurs predominantly in brain regions that are highly innervated by serotonin. To determine if serotonin plays a role in the effects of kappa-opioid receptor agonists on cocaine-stimulated activity, parachloroamphetamine (PCA), which depleted serotonin by 53%-66%, or saline, was given prior to a five-day treatment with U-69593 or vehicle. Three days later each rat received a single injection of cocaine and locomotor activity was measured. Treatment with PCA had no effect on the ability of U-69593 alone to decrease locomotor activity. Thus, the behavioral effects of U-69593 alone were not dependent upon serotonin. In rats pretreated with saline, U-69593 treatment significantly blocked the locomotor-activating effects of cocaine. Following PCA pretreatment, however, there were no significant differences in locomotor activity in rats challenged with an injection of cocaine after treatment with U-69593 or vehicle. Thus, serotonin depletion prevented the long-lasting blockade of the locomotor-activating effects of cocaine subsequent to repeated administration of U-69593 but did not alter the effects of cocaine in rats that were treated with vehicle. Thus, the effects of PCA on U-69593 are not due to non-specific alterations in cocaine-induced locomotor activity. These findings suggest that serotonin plays an important role in mediating the effects of kappa-opioid receptor agonists on the behavioral response to cocaine.