Steroid receptors in the developing and the adult rabbit endocervix and in endocervical epithelial cells isolated by flow cytometry.

Immunocytochemistry with monoclonal antibodies H222 and JZB39 was used to study nuclear estrogen (ER) and progesterone (PgR) receptors, respectively, in the cervix during differentiation and in the adult rabbit. The undifferentiated state of the cervix of 2-week-old rabbits correlates with a paucity of immunoreactive nuclear ER, while the epithelium of most of these animals showed moderate immunostaining for the nuclear PgR. The cervical epithelium, stroma and muscle cells of 1-month-old rabbits, showed weak immunostaining for the ER, while staining for PgR remained comparable to that of 2-week-old rabbits. For 2-4-month old rabbits the epithelium was characterized by moderate immunostaining for the nuclear ER and strong immunostaining for the PgR. Strong, heterogeneous immunostaining for nuclear ER and PgR receptors in endocervical epithelial cells from 6-month-old (adult), estrous rabbits suggested there are subpopulations of cells that express differential sensitivity to steroid hormones. In order to characterize such subpopulations, live endocervical epithelial cells were sorted with a flow cytometer on the basis of forward angle light scatter (FSC) and side scatter (SSC) signals which correlated with cell size and secretory granule content, respectively. Secretory cells, as verified by ultrastructural analysis and histochemical staining, expressed the highest FSC and SSC signals and were designated fraction "a". Changes in the hormonal status of the animals altered the intrinsic light scatter properties of fraction "a" cells as follows: maximum FSC and SSC signals were reported for cells from estrous animals; ovariectomy or progesterone-dominance decreased cell size (FCS) and secretory granule content (SSC), while treatment of ovariectomized rabbits with estradiol increased both parameters. When fraction "a" cells from estrous rabbits were incubated with the monoclonal antibodies, two distinct subpopulations of secretory cells were identified by intensity and pattern of nuclear staining for the ER and PgR. Changes in the hormonal status of the animals produced changes in the intensity of nuclear immunostaining, however both cell types remained distinguishable on the basis of immunostain pattern reflecting either permanent or transitory differences in them, and differential hormone sensitivity. The presence of nuclear ER and PgR proteins in these cells confirms their function is bireceptor-mediated.

Tyrosine influence on amphetamine self-administration and brain catecholamines in the rat.

Earlier work had shown that L-tyrosine administration, precursor to both dopamine (DA) and norepinephrine (NE), could increase brain DA metabolite concentrations after amphetamine treatment and restore amphetamine-induced decreases in whole brain NE. Both monoamines have been suggested to participate in some aspects of continued drug abuse. Rats trained to self-administer IV d-amphetamine were treated with IP tyrosine during test sessions to examine the behavioral and neurochemical response. In animals with less than 35 days of amphetamine exposure, L-tyrosine treatments did not alter amphetamine self-administration. Experiments using a computer-controlled injection apparatus which administered IV amphetamine to naive rats in patterns mimicking those of self-administration animals indicated tyrosine could antagonize amphetamine-induced NE depletions. The increases in DA metabolite dihydroxyphenylacetic acid (DOPAC) were found limited to the striatum, an area not involved in the positive reinforcing effects of amphetamine. Concentrations of DOPAC in nucleus accumbens septi were unchanged by the amphetamine or the amphetamine-tyrosine regimen. In rats with 4-6 months of chronic amphetamine exposure, however, L-tyrosine administration significantly reduced daily drug self-injection. While neurochemical responses to tyrosine could not be performed, it is speculated that chronic long-term amphetamine abuse might alter the tyrosine-induced changes in DA and/or NE synthesis and release compared to that in the acute or short-term amphetamine abuse animals. These data suggest that the success or failure of an experimental pharmacologic treatment strategy in psychomotor stimulant abusers might be dependent on the subjects history of drug abuse.

Comparison of two methods of administration of amphetamine on the dynamics of dopaminergic neurons in the rat.

Dopamine (DA) and its metabolite dihydroxyphenylacetic acid (DOPAC) in brain were examined in the striatum and nucleus accumbens septi after the administration of amphetamine by two different methods. A computer-controlled device was constructed to deliver intravenous injections of amphetamine in patterns mimicking those of animals in a self-administration paradigm, i.e. a total of 65 injections of 0.125 mg/kg/injection over 8 hr [total; 8.13 mg/kg (22.05 mumoles/kg)]. The second method was the intraperitoneal injection of 8.13 mg/kg as a single bolus. Control animals were intravenously or intraperitoneally administered saline. The effects of the two injection methods on the concentrations of DA and DOPAC were quite distinct at early times. This may in part be due to differences in the peak concentrations of amphetamine in brain achieved by the two regimens. Differences still persisted 48 hr after injection, particularly in the striatum. Increased levels of DA and DOPAC were observed at this time after the computer-controlled injections, while significantly decreased DA in the striatum is found after intraperitoneal bolus injections. These data strongly suggest that the method of administration of amphetamine can substantially alter the effects and possible toxicity of the drug on dopaminergic systems.

Effects of L-tyrosine on brain monoamines in rats given intravenous amphetamine.

A computer-controlled device was used to deliver intravenous injections of saline or d-amphetamine, in patterns resembling those of animals trained to self-administer the drug via lever pressing. Amphetamine, administered in this manner (over the course of an 8 hr test session), induced a 27% decrease in brain norepinephrine. The injection of the amino acid precursor L-tyrosine (100 mg/kg) prior to sacrifice abolished the decrements in brain norepinephrine. In animals administered i.v. saline, L-tyrosine treatment did not alter brain norepinephrine concentrations. Earlier clinical studies have suggested that the norepinephrine reuptake inhibitor desipramine is useful in controlling psychomotor stimulant abuse (the rationale being that this agent compensates for reduced levels of the amine). If this hypothesis is correct, L-tyrosine may be a safer method to replenish cerebral norepinephrine pools.