R.A. Gazzara

Gestational retinoic acid exposure: a sensitive period for effects on neonatal mortality and cerebellar development.

This is the first in a series of studies investigating the developmental stage-specific neurobehavioral effects of all-trans retinoic acid (RA) exposure. Because high doses of this compound are known to be lethal to the developing organism, we first conducted a dose-response study to identify RA doses that produce low enough levels of gestational/postnatal mortality to make a behavioral analysis possible in survivors. Secondarily, at doses found to produce sufficient survivors on PND 28, effects on body and regional brain weights were examined. Finally, at these doses, effects on somatic malformations were evaluated. Four separate exposure periods were analyzed: gestational days (GD) 8 through 10, 11 through 13, 14 through 16, or postnatal days (PND) 3 through 5. In the postnatal exposure period rat pups were injected (s.c.) with three consecutive daily doses of 0, 5, 10, or 20 mg/kg RA on PND 3 through 5. This postnatal exposure had no detectable effect on survival, body or brain weight. In contrast, there was a marked sensitivity to RA in the GD 11-13 group. Many pups from dams given 10 mg/kg RA PO on GD 11-13 were found dead in the cage on the day of birth, and all surviving pups died within 4 days of birth. Examination of milkbands revealed no evidence of effective suckling in these short-term survivors. The same 10 mg/kg dose at GD 8-10 or GD 14-16 produced much lower mortality and pups appeared to suckle normally. To produce adequate PND 28 survival in the GD 11-13 group, it was necessary to reduce dosage to 2.5 mg/kg daily. Even this lower exposure produced effects on PND 28 body and brain weight, significantly lowering weights of body (84% of control), whole brain (94%), and cerebellum (90%). Cerebellar weight was also depressed as percent of whole brain weight, suggesting an effect focused specifically on this region. RA at 10 or 12.5 mg/kg over GD 14-16 also reduced cerebellar weight (92% and 91% of control, respectively). Thus, exposure on GD 14-16 had effects similar to those seen at GD 11-13, but only at considerably higher doses. In contrast, exposure to RA on GD 8-10 did not affect whole body or brain weight, and of eight brain regions examined, only brain stem weight was reduced (91% of control). The GD 8-10 exposure also differed substantially from later exposures in that it was the only treatment to produce substantial malformations, including exencephaly, eye and skeletal defects. We conclude that gestational exposure to RA produces lethality and regional brain stunting that is dose and developmental stage specific, with a pronounced sensitive period on GD 11-13. In contrast, the GD 8-10 period is most sensitive for production of malformations, albeit at somewhat higher doses.

Behavioral effects of low-dose gestational day 11–13 retinoic acid exposure

In a comparison article we report that maternal PO exposure to 2.5 mg/kg all-trans retinoic acid (RA) daily for 3 consecutive days over gestational days (GD) 11-13 produces a 10% reduction in weight of cerebellum at 4 weeks of age, not accompanied by other malformations. Here we report the results of a preliminary behavioral analysis of offspring exposed gestationally to RA as above. Exposed dams were allowed to deliver normally, and litters were culled to eight pups (4 +/- 1 of each sex) at birth. Both male and female offspring were tested prior to weaning on GD 21. Thereafter females were killed on postnatal day (PND) 28 for verification of RA effects on regional brain weight, and all subsequent behavioral testing was conducted on males. Preweaning tests were restricted to negative geotaxis (PND 8-9) and open field activity (PND 22). Postweaning tests included open field activity (PND 43), auditory startle response (three times, on PNDs 22, 43, and 84), 2-week activity in residential running wheels (PNDs 62-76), complex maze performance for 5 consecutive days (PND 83-87), emergence latency (PND 106), and assessment of the behavioral response to an amphetamine challenge (PND 107). Males were then killed on PND 108 for verification of RA effects on regional brain weights. In this study, RA reduced weight of cerebellum but not striatum. Cerebellar weight was 92% of control values in PND 28 females, and this weight difference had diminished to 95% of control weight by PND 108 in males. There were no treatment effects on negative geotaxis, activity in a small open field, auditory startle amplitude, or latency to enter an illuminated alley from a dark chamber. Maze learning occurred at levels equal to or slightly better than controls. Running wheel activity was enhanced by RA exposure, whereas activity in response to an amphetamine challenge was reduced by such exposure. We conclude that RA doses low enough to produce mild weight reductions in cerebellum, without attendant malformations, can alter behavior. The precise nature of these alterations remains to be elucidated, but the findings reported here suggest that effects may be more pronounced on activity than on learning.

A Behavioral and Neuroanatomical Investigation of the Lethality Caused by Gestational Day 11-13 Retinoic Acid Exposure

In a companion article, we report that there is a sensitive period for all-trans retinoic acid (RA) lethality on gestational days (GD) 11-13. When dams were given 10 mg/kg RA daily for 3 consecutive days on GD 11-13, a number of pups were found dead in the home cage on the day of birth, and the remainder inevitably died due to an apparent inability to nurse. Here we report a set of experiments further investigating these effects. Dams were exposed PO to 10 mg/kg RA or oil vehicle on GD 11-13. Fetuses were removed by Cesarean section on the afternoon of GD 21, culled, and fostered to non-treated dams that had given normal vaginal delivery a day earlier. Maternal behavior was observed for the first 6 h after fostering. The next morning all surviving pups were given a brief behavioral evaluation, including the ability to attach to the nipple of anesthetized foster dams. At the time of C-section, culls were killed and brains were quickly removed and placed in fixative. A series of paraffin-embedded, cresyl-violet-stained serial sections of a representative brain stem from each litter was prepared. RA exposure did not increase fetal mortality. Treated litters were as large as controls, and virtually all treated fetuses were alive in utero. However, unlike controls, some treated fetuses appeared to have difficulty in initiating spontaneous breathing when delivered by C-section, and considerable physical stimulation was required before normal breathing began. As in the previous report, RA-exposed pups did not have milk in their stomachs after 18 h on the foster dam; further, they did not attach to the maternal nipple, and they had greater difficulty than controls in maintaining an upright posture. Examination of serial sections of the medulla indicated that the hypoglossal nucleus appeared grossly normal in the RA-exposed pups. In contrast, the inferior olive and the area postrema were affected by RA exposure. Both nuclei were normally located, but exhibited reduced cell density and/or intensity of staining. In the inferior olive the dorsal and principal nuclei were primarily affected, to the degree that about one quarter of treated brains had no identifiable principal nucleus. We conclude that RA exposure on GD 11-13 causes abnormal development of cell-dense regions of the medial medulla, and these abnormalities may account for the difficulty these animals experience in beginning spontaneous breathing and in nursing. These breathing and nursing problems in turn almost certainly account for the high mortality seen during natural birth and for the subsequent failure to thrive, respectively.

Minimal Behavioral Effects from Moderate Postnatal Lead Treatment in Rats

Developmental lead exposure continues to be a worldwide problem. This study investigated the behavioral effects resulting from developmental lead treatment in rats with corresponding physiological measures of lead exposure. Sprague-Dawley rats were treated with 350 ppm lead acetate from birth to weaning via the dams drinking water. Behavioral measures assessed in the offspring included residential activity tests, complex maze performance, acoustic startle response, emergence behavior (light/dark preference), prepulse inhibition, and ethological assessments of play, dominance, and burrowing. Pb blood levels averaged 53 microg/dl in the dam at the time of offspring weaning and 46 microg/dl in weanling female offspring. Pb levels averaged 277 ng/g and 32 microg/g in the brain and bone, respectively, of female offspring at weaning. No behavioral assessment indicated any lead-related functional alterations nor were there any statistically significant differences when the lead-treated group was restricted to rats in those litters that were above the median Pb blood lead level at weaning. These results indicate that any lead-related functional alterations at this dose may be subtle and require a sufficient demand on the system for detection.

Declines in stimulated striatal dopamine release over the first 32 h following microdialysis probe insertion: generalization across releasing mechanisms

In a recent paper [R.R. Holson, J.F. Bowyer, P. Clausing, B. Gough, Methamphetamine-stimulated striatal dopamine release declines rapidly over time following microdialysis probe insertion, Brain Res. 739 (1996) 301-307] we reported that methamphetamine-stimulated striatal dopamine release declined rapidly over the first eight hours following microdialysis probe insertion. This decline was strictly a function of time post-probe implantation, and not due to tolerance or desensitization. To further examine this phenomenon, we subjected rats to three brief pulses of several DA-releasing compounds at 2, 4 and 6 h post-probe insertion, and compared these results to those caused by a single pulse 6 h post-insertion, or in some cases to pulses given more than 24 h post-insertion. We found that when buproprion, a dopamine reuptake blocker, was infused briefly into the striatum via the microdialysis probe, there was a pronounced drop in the amount of dopamine released at 6 h vs. 2 h post-insertion; this drop was not due to repeated exposure, since dopamine release at 6 h post-insertion was the same for a single pulse, or when preceded by two earlier pulses. Twenty-four hours later, buproprion-stimulated dopamine release was still lower, but did not appear to drop further thereafter. Potassium-stimulated dopamine release, on the other hand, dropped rapidly over the first 8 h post-insertion, and this decline continued throughout the 24-32 h interval post-insertion. Similarly, a single i.p. injection of 0.5 mg/kg haloperidol released three times as much dopamine when given two compared to six hours post-implantation. Both bupropion- and potassium-stimulated dopamine release were accompanied by declines in extracellular DOPAC concentrations, and these declines were the same 2 or 26 h post-insertion. In contrast, haloperidol exposure increased extracellular DOPAC, and this haloperidol-stimulated DOPAC increase was also greatly attenuated at 6 compared to 2 h post-insertion. We conclude that there is a general decline over time post-probe implantation in the ability of the striatal dopamine system to release dopamine, and perhaps to increase dopamine synthesis, in response to pharmacological challenges.