AMPA receptor subunit GluR1 downstream of D-1 dopamine receptor stimulation in nucleus accumbens shell mediates increased drug reward magnitude in food-restricted rats.

Previous findings suggest that neuroadaptations downstream of D-1 dopamine (DA) receptor stimulation in nucleus accumbens (NAc) are involved in the enhancement of drug reward by chronic food restriction (FR). Given the high co-expression of D-1 and GluR1 AMPA receptors in NAc, and the regulation of GluR1 channel conductance and trafficking by D-1-linked intracellular signaling cascades, the present study examined effects of the D-1 agonist, SKF-82958, on NAc GluR1 phosphorylation, intracranial electrical self-stimulation reward (ICSS), and reversibility of reward effects by a polyamine GluR1 antagonist, 1-NA-spermine, in ad libitum fed (AL) and FR rats. Systemically administered SKF-82958, or brief ingestion of a 10% sucrose solution, increased NAc GluR1 phosphorylation on Ser845, but not Ser831, with a greater effect in FR than AL rats. Microinjection of SKF-82958 in NAc shell produced a reward-potentiating effect that was greater in FR than AL rats, and was reversed by co-injection of 1-NA-spermine. GluR1 abundance in whole cell and synaptosomal fractions of NAc did not differ between feeding groups, and microinjection of AMPA, while affecting ICSS, did not exert greater effects in FR than AL rats. These results suggest a role of NAc GluR1 in the reward-potentiating effect of D-1 DA receptor stimulation and its enhancement by FR. Moreover, GluR1 involvement appears to occur downstream of D-1 DA receptor stimulation rather than reflecting a basal increase in GluR1 expression or function. Based on evidence that phosphorylation of GluR1 on Ser845 primes synaptic strengthening, the present results may reflect a mechanism via which FR normally facilitates reward-related learning to re-align instrumental behavior with environmental contingencies under the pressure of negative energy balance.

The p16 and p18 tumor suppressor genes in neuroblastoma: implications for drug resistance.

The cyclin dependent kinase inhibitors p16 and p18 were investigated in neuroblastoma. Only one of 19 neuroblastoma cell lines, an adriamycin-resistant variant, and none of 5 primary neuroblastoma, was deleted for p16 while its parental drug sensitive cell line is p16 intact. The region of deletion minimally extended centromeric to include p15, and telomeric to interferon-beta. This is the first report of a p16 gene alteration in neuroblastoma. No p16 gene hypermethylation or mutations were found. No homozygous deletions of p18 in these samples were found, although several instances of loss of heterozygosity are suspected. No p18 point mutations were detected. We conclude that (1) neither p16 nor p18 are likely involved in the pathogenesis of neuroblastoma; and (2) the role of p16, or another 9p21 gene, in the development of drug resistance warrants further investigation.

Influence of glucose (in vivo or in vitro) on duration of narcotic analgesics and on the kinetics of drug metabolism.

The duration of analgesia of the narcotics, methadone, morphine and codeine was prolonged by glucose treatment. This prolongation was associated with a decrease in in vitro metabolism of the narcotics. Chlorpromazine metabolism was not significantly inhibited by glucose treatment, indicating that glucose exerts some selectivity in the extent to which it inhibits various oxidative metabolic pathways. Michaelis-Menten type kinetics showed a mixed type of competitive and noncompetitive inhibition of methadone metabolism upon oral administration of glucose or in vitro addition of glucose to an enzyme system prepared from mouse liver. Other factors may be involved, such as the possibility that glucose might increase the permeability of the brain to barbiturate. However, in glucose-treated mice decreased metabolism of the barbiturate and narcotics seemed to be the major factor in the prolongation of their duration of action.