Wayne J. Bowers

Region-specific reductions of intracranial self-stimulation after uncontrollable stress: Possible effects on reward processes

Rates of responding for intracranial self-stimulation from the medial forebrain bundle, nucleus accumbens and substantia nigra were evaluated in mice that had been exposed to either escapable shock, yoked inescapable shock or no shock treatment. Whereas performance was unaffected by escapable shock, marked reductions of responding from the medial forebrain bundle and nucleus accumbens were evident following the uncontrollable shock treatment. Responding from the substantia nigra was unaffected by the stress treatment. Uncontrollable shock is thought to reduce the rewarding value of responding for electrical brain stimulation from those brain regions in which stressors are known to influence dopamine activity.

A Retrospective Performance Assessment of the Developmental Neurotoxicity Study in Support of OECD Test Guideline 426

Objective We conducted a review of the history and performance of developmental neurotoxicity (DNT) testing in support of the finalization and implementation of Organisation of Economic Co-operation and Development (OECD) DNT test guideline 426 (TG 426). Information sources and analysis In this review we summarize extensive scientific efforts that form the foundation for this testing paradigm, including basic neurotoxicology research, interlaboratory collaborative studies, expert workshops, and validation studies, and we address the relevance, applicability, and use of the DNT study in risk assessment. Conclusions The OECD DNT guideline represents the best available science for assessing the potential for DNT in human health risk assessment, and data generated with this protocol are relevant and reliable for the assessment of these end points. The test methods used have been subjected to an extensive history of international validation, peer review, and evaluation, which is contained in the public record. The reproducibility, reliability, and sensitivity of these methods have been demonstrated, using a wide variety of test substances, in accordance with OECD guidance on the validation and international acceptance of new or updated test methods for hazard characterization. Multiple independent, expert scientific peer reviews affirm these conclusions.

Effects of mixtures of polychlorinated biphenyls, methylmercury, and organochlorine pesticides on hepatic DNA methylation in prepubertal female Sprague-Dawley rats.

DNA methylation is one of the epigenetic mechanisms that regulates gene expression, chromosome structure, and stability. Our objective was to determine whether the DNA methylation system could be a target following in utero and postnatal exposure to human blood contaminants. Pregnant rats were dosed daily from gestation day 1 until postnatal day 21 with 2 dose levels of either organochlorine pesticides (OCP; 0.019 or 1.9 mg/kg/day), methylmercury chloride (MeHg; 0.02 or 2 mg/kg/day), polychlorinated biphenyls (PCBs; 0.011 or 1.1 mg/kg/day), or a mixture (Mix; 0.05, or 5 mg/kg/day) including all 3 groups of chemicals. Livers from 1 female offspring per litter were collected at postnatal day 29. Hepatic analysis revealed that the mRNA abundance for DNA methyltransferase (DNMT)-1, -3a, and -3b were significantly reduced by the high dose of PCB, that the high dose of MeHg also reduced mRNA levels for DNMT-1, and -3b, but that OCP had no significant effects compared with control. The high dose of PCB and Mix reduced the abundance of the universal methyl donor S-adenosylmethionine, and Mix also reduced global genome DNA methylation (5-methyl-deoxycytidine/5-methyl-deoxycytidine + deoxycytidine). The latter is consistent with pyrosequencing methylation analysis, revealing that the high-dose groups (except OCP) generally decreased the methylation of CpG sites (position -63 to -29) in the promoter of the tumor suppressor gene p16INK4a. Overall, these hepatic results suggest that the DNA methylation system can be affected by exposure to high doses of blood contaminants, and that OCP is the least potent chemical group from the investigated mixtures.

Prevention of stressor-induced disturbances of self-stimulation by desmethylimipramine

Following exposure to uncontrollable footshock mice displayed a pronounced reduction of responding for electrical brain stimulation from the nucleus accumbens. In mice that received repeated treatment with the tricyclic antidepressant, desmethylimipramine, the shock induced reduction of responding was attenuated. It was suggested that, among other things, uncontrollable stressors result in disturbances of motivational/reward processes, which are antagonized by repeated treatment with desmethylimipramine.

Responding for brain stimulation: Stress and desmethylimipramine

Stressors influence the activity of biogenic amines and provoke a variety of behavioral disturbances which have been considered as models of human depression. To evaluate the effects of stressors on reward processes, responding for electrical brain stimulation was assessed after acute or chronic shock, and the modification of performance by desmethylimipramine was determined. While escapable shock did not affect performance, inescapable shock reduced responding from the nucleus accumbens and medial forebrain bundle, but not from the substantia nigra. These deficits were were antagonized by repeated stressor application or by desmethylimipramine. Uncontrollable stressors may influence motivational processes subserved by some brain regions, and may thus influence affective state. Chronic stress or desmethylimipramine may induce adaptive neurochemical changes, thereby preventing the behavioral disturbances otherwise produced by stressors.

Evaluation of stressor effects on intracranial self-stimulation from the nucleus accumbens and the substantia nigra in a current intensity paradigm

The effect of uncontrollable footshock was evaluated in animals responding for intracranial self-stimulation from the nucleus accumbens and the substantia nigra (pars compacta) in a descending current intensity paradigm. Responding for brain stimulation from the nucleus accumbens was found to be affected by the stressor at the upper end of the rate-intensity curve. In contrast, responding for brain stimulation from the substantia nigra was unaffected by the stressor at any of the current intensities employed. The variations of responding for self-stimulation from the nucleus accumbens were unrelated to alterations of locomotor activity or rearing. It is suggested that stressor-provoked reductions of responding for intracranial self-stimulation are not a result of the brain stimulation taking on aversive properties, but rather reflect a reduction in the reinforcing or motivational value associated with the stimulation.

Variations of norepinephrine concentrations following chronic stressor application

Exposure to acute uncontrollable footshock increased utilization of central norepinephrine (NE), and in some brain regions, most notably the hypothalamus, a decline in amine concentrations was induced. Utilization of NE was likewise increased in mice exposed to footshock on 14 consecutive days, but the NE reduction was not evident, suggesting that the chronic stressor provoked a compensatory increase of amine synthesis. In mice that were decapitated 24 hr after the chronic shock regimen, NE concentrations exceeded those of nonshocked animals or mice decapitated immediately after the last shock session, possibly reflecting a sustained increase of amine synthesis. The altered NE utilization and concentrations associated with chronic footshock were evident irrespective of whether the stressor was applied on a predictable schedule or on an intermittent basis, although the former treatment was somewhat more effective in increasing concentrations and utilization.

Toxicological Effects of In Utero and Lactational Exposure of Rats to a Mixture of Environmental Contaminants Detected in Canadian Arctic Human Populations

As part of the program to investigate mixture effects of environmental pollutants, this study describes clinical, biochemical, and histopathological effects in rats perinatally exposed to a mixture of persistent organochlorine pollutants and methylmercury that simulates the blood contaminant profile of humans residing in the Canadian Arctic. Groups of pregnant rats were administered orally 0, 0.05, 0.5, or 5 mg/kg body weight (bw)/d of a reconstituted mixture of organochlorine pollutants (referred to as mixture hereafter) from gestational day (GD) 1 to postnatal day (PND) 23. Positive and vehicle controls were given Aroclor 1254 (Aroclor hereafter, 15 mg/kg bw) and corn oil (vehicle), respectively. After parturition, the pups were colled to 8 per litter on PND 4, and killed on PND 35, 77, or 350, when tissues were collected for analysis. Gestational and lactational exposure of rats to mixture up to 5 mg/kg bw produced adverse effects in the offspring, including growth suppression, decreased spleen and thymic weights, increased serum cholesterol and liver microsomal enzyme activities, lower liver retinoid levels, and histological changes in the liver, thyroid, and spleen. Histological changes in the liver consisted of hepatic inflammation, vacuolation, and hypertrophy, while alterations in the thyroid were characterized by hypertrophy and hyperplasia of follicles. The hepatic and thyroidal effects were mild even at the highest dose. The spleen showed a dose-dependent atrophy in the lymphoid nodules and periarteriolar lymphatic sheath regions. Aroclor produced effects similar to those seen in the highest mixture group. In summary, this study demonstrates that exposure to the reconstituted mixture at 5 mg/kg bw produced growth suppression, changes in organ weights, and biochemical and histopathological changes in liver, thyroid, and spleen. This study also demonstrated that the blood level in rats given the 5-mg/kg dose, where most of the effects were observed, is 100-fold higher than the blood level in the 0.05-mg/kg group, which is comparable to that found in humans living in the Canadian Arctic region.

Differential effects of pimozide on response-rate and choice accuracy in a self-stimulation paradigm in mice

Intracranial self-stimulation (ICSS) from the dopamine (DA) A9 cell grouping was evaluated in mice following pimozide administration in both a one hole head dipping task and a two hole discrimination paradigm. While pimozide reliably decreased response rates, choice accuracy in the discrimination paradigm was unaffected by the drug treatment. The data were taken to suggest that neuroleptics influence response rate owing to motoric disturbances, without influencing the effectiveness of cues that previously had been associated with primary reinforcement.

Neurotoxicity may be an overlooked consequence of benzo[a]pyrene exposure that is relevant to human health risk assessment.

Benzo[a]pyrene (BaP) is a well-studied environmental compound that requires metabolic activation to have a carcinogenic effect. The neurotoxicity of BaP has received considerably less attention than its carcinogenicity. Environmental exposure to BaP correlates with impaired learning and memory in adults, and poor neurodevelopment in children. We carried out a comprehensive literature review to examine the neurotoxicity of BaP. The data were used to identify potential point of departure (POD) values for cancer and neurotoxicity endpoints using benchmark dose (BMD) modelling to compare the utility of both endpoints in the risk assessment of BaP. The POD for neurotoxicity in rodents, based on a standard behavioural test (Morris water maze), was 0.025 mg BaP/kg-bw-day compared to 0.54 mg BaP/kg-bw-day for rodent forestomach carcinogenicity, suggesting that neurotoxic endpoints are more sensitive than cancer endpoints for health risks associated with BaP exposure. Using the limited number of published studies on this topic, we propose a preliminary mode of action (MOA) to explain BaP-induced neurotoxicity in rodents. The MOA includes: (1) BaP binding to the aryl hydrocarbon receptor (AHR); (2) AHR-dependent modulation of the transcription of N-methyl-d-aspartate glutamate receptor (NMDAR) subunits; (3) NMDAR-mediated loss of neuronal activity and decreased long-term potentiation; and (4) compromised learning and memory. More data are needed to explore the proposed neurotoxic MOA. In addition, we consider alternative MOAs, including the hypothesis that BaP-mediated DNA damage may lead to either carcinogenicity or neurotoxicity, depending on the tissue. Our proposed MOA is intended to serve as a basis for hypothesis testing in future studies. We emphasise that further studies are needed to validate the proposed MOA, to evaluate its human relevance, and to explore other potential mechanisms of BaP neurotoxicity.