Altered pre-pulse inhibition in adult rats treated neonatally with domoic acid.

Altered functioning of the glutamate system during critical periods of development is believed to play a role in various neurodevelopmental disorders, such as schizophrenia. Prepulse inhibition (PPI) of the acoustic startle response is deficient in people with schizophrenia. This study investigated the theory that neonatal treatment with domoic acid (DOM), a glutamate agonist, leads to deficient PPI. Results indicate that neonatal treatment with DOM leads to lowered PPI in adult males and an increased startle response in adult females.

Low dose domoic acid in neonatal rats abolishes nicotine induced conditioned place preference during late adolescence.

In this study, neonatal rats were chronically exposed to low, non-convulsive doses of the kainate receptor agonist domoic acid (DOM), or saline. Later, as adolescents, all animals were tested in a nicotine-induced conditioned place preference (CPP) paradigm. As expected, a nicotine-induced CPP was evident in the adolescent control rats, but surprisingly, not in the DOM animals. This study demonstrates the importance of KA receptors in the development of normal adolescent behaviors manifested in response to the rewarding properties of nicotine.

Gender-based changes in cognition and emotionality in a new rat model of epilepsy.

Epilepsy research relies heavily on animal models that mimic some, or all, of the clinical symptoms observed. We have previously described a new developmental rat model of epilepsy that demonstrates both behavioural seizures and changes in hippocampal morphology. In the current study we investigated whether these rats also show changes in cognitive performance as measured using the Morris water maze task, and emotionality as measured using the Elevated plus maze task. In the water maze, significant differences between male and female rats were found in several performance variables regardless of treatment. In addition, female but not male rats, treated neonatally with domoic acid had significant impairments in learning new platform locations in the water maze. In the elevated plus maze, a significant proportion of female rats spent more time in the open arm of the maze following prior exposure to the maze whereas this effect was not seen in male rats. We conclude that perinatal treatment with low doses of domoic acid results in significant gender-based changes in cognition and emotionality in adult rats.

NMDA receptor involvement in the effects of low dose domoic acid in neonatal rats.

We have previously reported that neonatal rats display enhanced sensitivity to domoic acid relative to adults, and that perinatal injections of low doses of domoic acid alter early associational learning in the newborn rat. The current study was designed to further investigate the effects of low dose domoic acid on neonatal odour conditioning and to determine if the observed effects are due in part to an action on NMDA receptors. Groups of rat pups were conditioned to a novel odour on postnatal day (PND) 8, injected with 20 microg/kg domoic acid either alone, or in combination with the NMDA antagonist CPP (or appropriate controls), daily from day 8-14, re-exposed to the conditioning odour or a novel odour on day 9, and tested for odour preference on day 13 using a standard 3-choice paradigm. Results indicated that rats treated with domoic acid spent significantly more time over the conditioning odour than did saline-treated rats when tested on PND 13. This effect was antagonized by concomitant injection of CPP, indicating an involvement of NMDA receptors in the actions of DOM in this paradigm. Rats injected with either saline or CPP alone showed the opposite effect, i.e. a preference for the alternate odour. The results indicate that a very low dose of DOM produces a conditioned odour preference in neonatal rats and that this effect is due in part to NMDA receptor involvement, thereby emphasizing a role for both kainate and NMDA glutamate receptors in implicit memory.

Low doses of domoic acid during postnatal development produce permanent changes in rat behaviour and hippocampal morphology.

It is well established that the developing brain is a highly dynamic environment that is susceptible to toxicity produced by a number of pharmacological, chemical and environmental insults. We report herein on permanent behavioural and morphological changes produced by exposing newborn rats to very low (subconvulsive) doses of kainate receptor agonists during a critical window of brain development. Daily treatment of SD rat pups with either 5 or 20 microg/kg of domoic acid (DOM) from postnatal day 8-14 resulted in a permanent and reproducible seizure-like syndrome when animals were exposed to different tests of spatial cognition as adults. Similar results were obtained when animals were treated with equi-efficacious doses of kainic acid (KA; 25 or 100 microg/kg). Treated rats had significant increases in hippocampal mossy fiber staining and reductions in hippocampal cell counts consistent with effects seen in adult rats following acute injections of high doses of kainic acid. In situ hybridization also revealed an elevation in hippocampal brain derived neurotrophic factor (BDNF) mRNA in region CA1 without a corresponding increase in neuropeptide Y (NPY) mRNA. These results provide evidence of long-lasting behavioural and histochemical consequences arising from relatively subtle changes in glutamatergic activity during development, that may be relevant to understanding the aetiology of seizure disorders and other forms of neurological disease.

Comparison of the in vitro and in vivo neurotoxicity of three new sources of kainic acid.

Historically, all commercially available kainic acid has been derived from a single biological source using a consistent method of extraction and purification. That source became unavailable in 1995. Recently, three new commercial suppliers of kainic acid have made the product available, but the source of the material and the purification processes used differ. Our objective was to systematically compare the response produced by each of these new sources of kainic acid using three established neurobiological techniques: neuronal cell culture, hippocampal slice electrophysiology, and whole animal behavioural toxicity. Results in all three systems indicated no overall differences between the three formulations, although studies in both cerebellar neuron cultures and whole animal toxicity testing in mice, revealed some significant differences that may imply subtle differences in receptor selectivity and/or potency. We conclude that all three sources of kainic acid are viable alternatives to traditional kainate but they may not be identical. Until further information becomes available researchers may want to avoid using the three formulations interchangeably, and take note of the source of kainic acid when evaluating literature describing results from other laboratories.

Comparative behavioural toxicity of domoic acid and kainic acid in neonatal rats.

Cumulative behavioural toxicity was measured in groups of male and female rat pups (n=6/sex) at different stages of postnatal development. Dose-response curves (DRCs) for toxicity produced by domoic acid (DOM) were generated using animals on postnatal days (PND) 0, 5, 14, and 22, using a behavioural rating scale. In a subsequent experiment, DRCs for toxicity generated by either DOM or kainic acid were produced in rats at PND 8 and 14 for comparison between the two toxins. DOM was found to be a very potent neurotoxin in newborn rats and the potency of DOM progressively decreased with increasing age (interpolated ED(50)=0.12, 0.15, 0.30, and 1.06 mg/kg at PND 0, 5, 14, and 22, respectively). In addition, the patterns of behavioural expression were found to differ with age. Comparisons between DOM and kainic acid revealed that DOM was approximately six-fold more potent than kainate at both PND 8 and PND 14 and that both toxins were approximately two-fold less potent in PND 14 rats, compared to PND 8. This implies that the mechanism(s) responsible for reduced potency is/are similar between the two compounds. Consistent with previous reports, however, there were both similarities and differences in the observed patterns of behavioural toxicity produced by the two toxins at both ages.

Use of osmotic minipumps for sustained drug delivery in rat pups: effects on physical and neurobehavioural development.

Osmotic minipumps are often used as an alternative to repetitive injections for prolonged drug delivery in adult rats. The appropriateness of using this technology for sustained drug delivery in newborn rats, however, has not been validated. Our objective was to determine if implantation of osmotic minipumps, and the associated surgical stress, during a critical developmental period, affects early development and subsequent behaviour. SD rat pups were assigned to control, minipump, or sham surgery treatment conditions (n=12/group). On P8, pups were briefly anaesthetised with isoflurane in oxygen, and Alzet 1007D osmotic minipumps, loaded with normal saline, were aseptically implanted (removed on P17). Sham-treated rats received identical treatment (with the exception of pump placement), while control pups were left undisturbed. Development was examined daily using a standard test battery (P9-P21), and learning and memory in pups was assessed in a T-maze (P15, P17 and P19). Weight (P27 and P72), open-field (P25, P26 and P27) and novel water maze performance (P60-P72) were examined in the resulting adult. With the exception of a transient decrease in weight gain, pump-treated animals did not differ from either sham or control rats, on any pre- or postweaning assessment. Based on these results we conclude that the use of osmotic minipumps in rat pups is a viable alternative to repeated injections for sustained drug delivery.