Reproductive experience reduces haloperidol-induced prolactin secretion in female rats.

The present study examined possible changes in the dopaminergic regulation of prolactin (PRL) secretion which have been reported to occur in reproductively experienced female rats. In the first experiment, female rats which had raised a litter to weaning and age-matched nulliparous controls were ovariectomized and challenged sequentially 2 days apart with a low (0.2 mg/kg) and high (1.0 mg/kg) dose (intravenously) of haloperidol (HAL), a dopamine antagonist. Blood samples were collected via intra-atrial catheters, and plasma samples were assayed for PRL content by radioimmunoassay. Whereas HAL stimulated increases in plasma PRL concentrations in both nulliparous and primiparous animals, significantly higher levels of plasma PRL were present after both doses of HAL in the nulliparous rats. A second experiment investigated the role of lactation in this change in the ability of HAL to stimulate increases in circulating PRL levels. Separate sets of age-matched primiparous (pups removed on day 1 of lactation) and nulliparous rats were challenged with two doses of HAL 2 weeks after gonadectomy. In contrast to the effect of pregnancy and lactation found in the first experiment, pregnancy and parturition in the absence of lactation failed to alter the female's sensitivity to HAL. The PRL responses in the two groups were identical at the low HAL dose and similar after the high HAL dose. These findings demonstrate that a single prior pregnancy and lactation, but not pregnancy alone, significantly reduce the ability of HAL to elevate circulating plasma PRL concentrations. Decreased circulating PRL levels in reproductively experienced females, therefore, may result in part from increased endogenous dopaminergic activity/tone.

N-methyl-DL-aspartic acid lesions of the medial preoptic area disrupt ongoing parental behavior in male rats.

The effects of axon-sparing, neurotoxic lesions of the medial preoptic area (MPOA) with N-methyl-DL-aspartic acid (NMA) on previously established parental behavior in male rats were investigated. Adult, sexually-inexperienced male rats were gonadectomized and seven days later implanted sc with a single estradiol (E2)-filled Silastic capsule on treatment Day 1. Three progesterone (P4) capsules were implanted sc on treatment Day 3 and removed on Day 21, one day prior to the start of behavioral testing. Males were tested daily with foster pups in order to induce parental behavior, i.e., contacting the test pups, pup retrieval, grouping, and crouching over three foster pups. Full parental behavior appeared in these males after an average of 3 days. After testing on the third consecutive day of parental behavior, parental males were infused bilaterally with either NMA or vehicle into the MPOA. NMA infusions resulted in a significant decline in all components of parental behavior by the next test session, a deficit which persisted throughout the 5 days of post-infusion testing. In contrast, parental care continued to be displayed in animals given vehicle infusions. These findings demonstrate that the cells in the MPOA play an important role in regulating ongoing parental care in male rats and indicate that the neural substrates controlling parental behavior in male and female rats are similar.

Central lactogenic regulation of maternal behavior in rats: steroid dependence, hormone specificity, and behavioral potencies of rat prolactin and rat placental lactogen I.

Adult virgin female rats display maternal behavior when continuously exposed to foster young for 5-6 days. Central infusions of PRL or placental lactogens (PLs) together with systemic treatment of progesterone (P) and estradiol (E2) stimulate maternal behavior in 1-2 days. In the present set of studies, it was asked whether the actions of lactogenic hormones are dependent upon both E2 and P and specific to lactogenic molecules. Moreover, we wanted to know whether central infusions of rat (r) PRL and PLs were equally effective in inducing maternal behavior. In the first study, adult virgin rats were ovariectomized (ovx) and stereotaxically fitted with bilateral cannulas directed at the medial preoptic area (MPOA). Rats were then assigned to one of four groups: P plus E2, blank (B) plus E2, P plus B, and B plus B. P-filled or B capsules were implanted sc on treatment day 1 and removed on day 11, whereas E2 or B capsules were implanted on day 11. All groups were infused with rPRL (40 ng/side) five times from days 11-13 and injected with bromocriptine (CB-154) sc (days 11-17) to suppress endogenous PRL release. Behavioral testing was conducted daily from days 12-17. It was found that exposure to both P and E2 was necessary to induce a fast onset of maternal behavior in PRL-infused females; priming with P or E2 alone in PRL-treated rats failed to stimulate a fast onset of behavior relative to that in nonsteroid-treated controls. In the second experiment to determine the biochemical specificity of PRL's action, adult nulliparous rats were ovx, implanted with bilateral cannulas directed at the MPOA, treated with both P and E2, injected with CB-154, and infused centrally (five times) with 40 ng (per side) of bovine GH, ovine LH, or vehicle. Central infusions of either bovine GH or ovine LH failed to stimulate maternal behavior, suggesting that the stimulatory actions of PRL are related to its lactogenic properties. In the final study, rats were ovx, fitted with bilateral cannulas directed at the MPOA; treated with P, E2, and CB-154; and given a single set of bilateral infusions of rPL-I or rPRL (40 ng/side.infusion) on day 11, three sets of infusions of rPL-I or rPRL (days 11 and 12), or vehicle infusions. Rats given three infusions of rPL-I and rPRL responded faster than controls, although the effect was not as robust as that in animals given five infusions in the initial study. rPL-I and rPRL groups did not differ from one another. Together these studies indicate that 1) both P and E2 are required for lactogenic stimulation of maternal behavior; 2) the stimulatory actions of PRL and rPLs on maternal behavior are related to their lactogenic properties; 3) extended treatment of females with lactogenic hormones is more effective in stimulating the onset of maternal behavior; and 4) the neural potencies of rPRL and rPL-I are similar. These findings provide support for the idea that the induction of maternal behavior is stimulated by the central actions of lactogenic hormones.

Neurosteroids affect spatial/reference, working, and long-term memory of female rats.

Female rats take longer to acquire a spatial task during behavioral estrus, when GABA-active progesterone and metabolites are elevated. Whether neurosteroids and neuroactive steroids (neuro(active) steroids), which can act at GABA receptor complexes (GBRs), have activational effects on spatial/reference, working, and long-term memory was investigated. In Experiment 1, ovariectomized Long-Evans rats (N = 107) received oil vehicle or one of six neuro(active) steroids, with varying GBR efficacy (greatest to least efficacious: 5 alpha-pregnan-3 alpha-ol-20-one (THP), 5 alpha-pregnan-3 alpha-ol-11,20-dione, 4-pregnen-3,20-dione 17 alpha-hydroxyprogesterone, 5-pregnen-3 beta-ol-20-one sulfate, and 5-androstan-3 beta-ol-17-one sulfate (DHEAS). Following neuro(active) steroid (3.2 or 6.4 mg/kg) or vehicle sc, rats were tested in a Morris water maze, the following week in a Y maze, and then in an open field. Neuro(active) steroid, but not vehicle, animals had decreased distances to the hidden water maze platform. THP (3.2 and 6.4 mg/kg) animals were faster to find this platform than vehicle animals. In the Y maze, 3.2 mg/kg THP increased percentage correct, but 6.4 mg/kg THP increased latencies to the goal box. DHEAS had the opposite effect, with 3.2 mg/kg increasing latencies to the goal box, while 6.4 mg/kg increased percentage correct. In Experiment 2, N = 75 ovariectomized rats were icv implanted with one of the neuro(active)steroids or cholesterol vehicle and then tested for spatial/reference memory, working and long-term memory, and motoricity/anxiolysis as in Experiment 1. DHEAS implants decreased, while THP increased, latencies and distances to the hidden platform in the Morris water maze. In the Y maze, THP increased latencies and decreased percentage correct, but DHEAS increased the likelihood of correct choice. Open field behavior of animals administered the various neuro(active) steroids (sc or icv) was not different. Thus, of the neuro(active) steroids examined, the neurosteroids THP and DHEAS had the most pronounced activational affects on spatial/reference, working, and long-term memory, independent of motoricity.