Oxidative stress and neuronal changes associated with prenatal ethanol exposure in human and monkey brains

Basalah, Duaa Ali

06 April 2015

Background: Prenatal ethanol exposure (PNEE) causes irreversible intellectual and behavioral disabilities, clinically known as fetal alcohol spectrum disorder. Few neuropathologic studies of human brain exist. Hypotheses: First, markers of oxidative stress persist following PNEE. Second, PNEE is associated with inhibitory and excitatory neuron changes. Methods: Human brain autopsies (153) with known PNEE were reviewed; 18 cases (fetus to adult) and controls were selected. Oxidative stress and neuronal differentiation markers were used for immunohistochemistry. Results: There were no obvious differences between control and PNEE brains using oxidative stress markers. In human PNEE brains, glutamatergic neurons were reduced 15.96 % and 18.03% in dentate gyrus and temporal cortex, respectively. GABAergic neurons reactive for parvalbumin were reduced in all hippocampal regions (CA1= 57.86%, CA3= 65.15%, and DG= 53.39%) and temporal cortex (44.13%) in all age groups. Conclusion: GABAergic neuron reduction in human following PNEE could explain motor and behavior distractibility in FASD individuals.

Prenatal Ethanol Exposure

Fetal Alcohol Spectrum Disorders

Role of testosterone in mediating prenatel ethanol effects on hypothalamic-pituitary-adrenal activity in male rats

Lan, Ni

05 1900

Prenatal ethanol (E) exposure has marked effects on development of the hypothalamic-pituitary-adrenal (HPA) and -gonadal (HPG) axes. E rats show HPA hyperresponsiveness to stressors and altered reproductive function in adulthood. Importantly, prenatal ethanol differentially alters stress responsiveness in adult males and females, raising the possibility that gonadal hormones play a role in mediating ethanol effects on HPA function. To address this possibility, two studies were conducted to test the hypothesis that the differential alterations in HPA activity observed in E compared to control males are mediated, at least in part, by ethanol-induced changes in HPG effects on HPA regulation. The first study compared the effects of gonadectomy (GDX) on HPA and HPG activity in adult male offspring from prenatal E, pair-fed (PF) and ad libitum-fed control (C) dams. There were no differences among groups in basal testosterone levels under intact conditions. However, E males showed increased adrenocorticotropin but blunted testosterone and luteinizing hormone (LH) responses to restraint stress compared to PF and/or C rats, and no stress-induced elevation in arginine vasopressin (AVP) mRNA levels. GDX eliminated these differences among groups. The second study explored dose-related effects of testosterone on HPA regulation. Testosterone had less of an inhibitory effect on stress-induced CORT and LH increases in E than in PF and C males. Furthermore, testosterone had a reduced effect on central corticotropin-releasing hormone pathways, but an increased effect on central AVP pathways in E compared to PF and/or C males. Importantly, reduced androgen receptor (AR) mRNA levels, possibly reflecting downregulation of AR in key brain areas, may counteract the increased inhibitory AVP signals upstream from the paraventricular nucleus, and thus contribute to the HPA hyperresponsiveness seen in E males. Together these findings suggest that central regulation of both the HPA and HPG axes are altered by prenatal ethanol exposure. The capacity of testosterone to regulate HPA activity is altered in E males, with some effects mediated by the nutritional effects of ethanol. These changes would impair the ability to maintain homeostasis in E animals and have implications for the development of secondary disabilities in children with Fetal Alcohol Spectrum Disorder.

Prenatal ethanol

Testosterone

Stress

Pituitary-adrenal

Pituitary-gonadal

Role of testosterone in mediating prenatel ethanol effects on hypothalamic-pituitary-adrenal activity in male rats

Lan, Ni

05 1900

Prenatal ethanol (E) exposure has marked effects on development of the hypothalamic-pituitary-adrenal (HPA) and -gonadal (HPG) axes. E rats show HPA hyperresponsiveness to stressors and altered reproductive function in adulthood. Importantly, prenatal ethanol differentially alters stress responsiveness in adult males and females, raising the possibility that gonadal hormones play a role in mediating ethanol effects on HPA function. To address this possibility, two studies were conducted to test the hypothesis that the differential alterations in HPA activity observed in E compared to control males are mediated, at least in part, by ethanol-induced changes in HPG effects on HPA regulation. The first study compared the effects of gonadectomy (GDX) on HPA and HPG activity in adult male offspring from prenatal E, pair-fed (PF) and ad libitum-fed control (C) dams. There were no differences among groups in basal testosterone levels under intact conditions. However, E males showed increased adrenocorticotropin but blunted testosterone and luteinizing hormone (LH) responses to restraint stress compared to PF and/or C rats, and no stress-induced elevation in arginine vasopressin (AVP) mRNA levels. GDX eliminated these differences among groups. The second study explored dose-related effects of testosterone on HPA regulation. Testosterone had less of an inhibitory effect on stress-induced CORT and LH increases in E than in PF and C males. Furthermore, testosterone had a reduced effect on central corticotropin-releasing hormone pathways, but an increased effect on central AVP pathways in E compared to PF and/or C males. Importantly, reduced androgen receptor (AR) mRNA levels, possibly reflecting downregulation of AR in key brain areas, may counteract the increased inhibitory AVP signals upstream from the paraventricular nucleus, and thus contribute to the HPA hyperresponsiveness seen in E males. Together these findings suggest that central regulation of both the HPA and HPG axes are altered by prenatal ethanol exposure. The capacity of testosterone to regulate HPA activity is altered in E males, with some effects mediated by the nutritional effects of ethanol. These changes would impair the ability to maintain homeostasis in E animals and have implications for the development of secondary disabilities in children with Fetal Alcohol Spectrum Disorder.

Prenatal ethanol

Testosterone

Stress

Pituitary-adrenal

Pituitary-gonadal

Role of testosterone in mediating prenatel ethanol effects on hypothalamic-pituitary-adrenal activity in male rats

Lan, Ni

05 1900

Prenatal ethanol (E) exposure has marked effects on development of the hypothalamic-pituitary-adrenal (HPA) and -gonadal (HPG) axes. E rats show HPA hyperresponsiveness to stressors and altered reproductive function in adulthood. Importantly, prenatal ethanol differentially alters stress responsiveness in adult males and females, raising the possibility that gonadal hormones play a role in mediating ethanol effects on HPA function. To address this possibility, two studies were conducted to test the hypothesis that the differential alterations in HPA activity observed in E compared to control males are mediated, at least in part, by ethanol-induced changes in HPG effects on HPA regulation. The first study compared the effects of gonadectomy (GDX) on HPA and HPG activity in adult male offspring from prenatal E, pair-fed (PF) and ad libitum-fed control (C) dams. There were no differences among groups in basal testosterone levels under intact conditions. However, E males showed increased adrenocorticotropin but blunted testosterone and luteinizing hormone (LH) responses to restraint stress compared to PF and/or C rats, and no stress-induced elevation in arginine vasopressin (AVP) mRNA levels. GDX eliminated these differences among groups. The second study explored dose-related effects of testosterone on HPA regulation. Testosterone had less of an inhibitory effect on stress-induced CORT and LH increases in E than in PF and C males. Furthermore, testosterone had a reduced effect on central corticotropin-releasing hormone pathways, but an increased effect on central AVP pathways in E compared to PF and/or C males. Importantly, reduced androgen receptor (AR) mRNA levels, possibly reflecting downregulation of AR in key brain areas, may counteract the increased inhibitory AVP signals upstream from the paraventricular nucleus, and thus contribute to the HPA hyperresponsiveness seen in E males. Together these findings suggest that central regulation of both the HPA and HPG axes are altered by prenatal ethanol exposure. The capacity of testosterone to regulate HPA activity is altered in E males, with some effects mediated by the nutritional effects of ethanol. These changes would impair the ability to maintain homeostasis in E animals and have implications for the development of secondary disabilities in children with Fetal Alcohol Spectrum Disorder. / Medicine, Faculty of / Graduate

Prenatal ethanol

Testosterone

Stress

Pituitary-adrenal

Pituitary-gonadal

Developmental ethanol exposure and its impact on behaviour and HPI axis activity of zebrafish

Baiamonte, Matteo

January 2015

Ethanol exposure during pregnancy is one of the leading causes of preventable birth defects, leading to a range of symptoms collectively known as fetal alcohol spectrum disorder (FASD). More moderate levels of prenatal ethanol exposure (PNE) lead to a range of behavioural deficits including aggression, poor social interaction, poor cognitive performance and increased likelihood of addiction in later life. Current theories suggest that adaptation in the hypothalamic-pituitaryadrenal (HPA) axis and neuroendocrine systems contributes to mood alterations underlying behavioural deficits and vulnerability to addiction. This has led to the suggestion that corticotrophin-releasing factor (CRF) antagonists and glucocorticoid (steroid) inhibitors may be potential therapeutics to address the deficits of PNE and for the treatment of addiction. The zebrafish (Danio rerio) has several advantages over mammalian models, such as low cost of maintenance, short life cycle, easy embryological manipulation and the possibility of large-scale genetic screening. By using this model, our aim is to determine whether developmental ethanol exposure provokes changes in the HPA axis (HPI axis in fish), as it does in mammalian models, therefore opening the possibilities of using zebrafish to elucidate the mechanisms involved, and to test novel therapeutics to alleviate deleterious symptoms. Thus this thesis focuses solely on the effect of developmental ethanol exposure on the functioning of the HPI axis in zebrafish. Stress-reactivity in zebrafish larvae ethanol-treated 1-9 days post 4 fertilisation (dpf) was assessed using thigmotaxis and thigmotaxis following airstress. In both tests, lower stress-related responses were obtained with ethanol treated animals, in that they spent less time at the edges of the apparatus (P<0.01, n=3). They also showed lower total body cortisol (P=0.04, n=14). Larvae also showed the same behaviour pattern two weeks after ethanol exposure, (23dpf) (P=0.04, n=3), again with reduced total cortisol (P=0.03, n=4). HPI-related gene transcription was also assessed in 9dpf ethanol treated zebrafish larvae, by qRT-PCR. Revealing up-regulation of CRH, CRHBP and CRHR2, normalized against β-Actin, Elav1 and Gap43 housekeeping genes. In situ hybridization revealed no spatial changes in CRH, CRH-BP and POMC with animals at the same stage. Behavioural stress-reactivity differences in 6-months old adults that had been exposed developmentally to ethanol were assessed using novel tank diving and thigmotaxis. Both assays indicated a decrease in stress-like behaviour due to early ethanol exposure compared to controls (P<0.05, n=5 both). Finally, cortisol levels were assayed from 9dpf larvae and 6-month-old adults that had been treated with ethanol during early development showed a significant reduction in cortisol output when air-exposed stressed compared to controls (P=0.04, n=5). Conclusion: Early ethanol exposure produced significant changes in cortisol, HPI gene mRNA expression and stress-reactive behaviour in 9dpf animals. Changes in cortisol and behaviour were still detected in 6-months old adults, developmentally treated with ethanol, indicating that early ethanol exposure has permanent effects on the HPI axis. 5 As our data contradicts the findings in mammalian literature where early ethanol exposure increases stress-like behaviour in later life, it is also possible that more permanent effects of PNE in mammals may arise through maternal-offspring interactions, during and post gestation, such as breastfeeding and maternal grooming of the offspring, which are absent in the zebrafish model.

612.8

Replenishing what is Lost: Using Supplementation to Enhance Hippocampal Function in Fetal Alcohol Spectrum Disorders

Patten, Anna Ruth

22 April 2013

Fetal Alcohol Spectrum Disorders (FASD) are the most common cause of cognitive impairment in the United States (Sokol et al., 2003). In young school children in North America and some Western European countries, recent reports have estimated the prevalence of FASD to be as high as 2-5% (May et al., 2009). Currently there are no widely accepted treatment options for FASD, mainly due to the fact that the underlying neurological deficits that occur with prenatal ethanol exposure (PNEE) are still largely unknown. This thesis examines the long-lasting changes that occur in the hippocampus following PNEE using biochemical and electrophysiological techniques. We find that PNEE produces a reduction of the endogenous antioxidant glutathione (GSH), resulting in an increase in oxidative stress that is accompanied by long-lasting reductions in long-term potentiation (LTP) of synaptic efficacy. Interestingly, males exhibited greater deficits in synaptic plasticity than females, despite similar reductions in GSH in both sexes. By depleting GSH in control animals we determined that LTP in the DG of female animals is more resistant to changes in GSH, which may explain the sexual dichotomy observed in these studies of PNEE. Based on these findings, ethanol-exposed animals received postnatal dietary supplementation with either a precursor of GSH, N-Acetylcysteine (NAC) or Omega-3 fatty acids. These supplements helped to counteract the effects of PNEE and improved hippocampal function. The findings in this thesis support the hypothesis that increasing antioxidant capacity can enhance hippocampal function, which in turn may improve learning and memory in FASD, providing a therapeutic avenue for children suffering with these disorders. / Graduate / 0570 Nutrition / 0317 Neuroscience / anna.r.patten@gmail.com

Fetal Alcohol Spectrum Disorders

Prenatal Ethanol Exposure

Electrophysiology

Dentate gyrus

Hippocampus

Oxidative Stress

Omega-3 fatty acids

Glutathione

Replenishing what is Lost: Using Supplementation to Enhance Hippocampal Function in Fetal Alcohol Spectrum Disorders

Patten, Anna Ruth

22 April 2013

Fetal Alcohol Spectrum Disorders (FASD) are the most common cause of cognitive impairment in the United States (Sokol et al., 2003). In young school children in North America and some Western European countries, recent reports have estimated the prevalence of FASD to be as high as 2-5% (May et al., 2009). Currently there are no widely accepted treatment options for FASD, mainly due to the fact that the underlying neurological deficits that occur with prenatal ethanol exposure (PNEE) are still largely unknown. This thesis examines the long-lasting changes that occur in the hippocampus following PNEE using biochemical and electrophysiological techniques. We find that PNEE produces a reduction of the endogenous antioxidant glutathione (GSH), resulting in an increase in oxidative stress that is accompanied by long-lasting reductions in long-term potentiation (LTP) of synaptic efficacy. Interestingly, males exhibited greater deficits in synaptic plasticity than females, despite similar reductions in GSH in both sexes. By depleting GSH in control animals we determined that LTP in the DG of female animals is more resistant to changes in GSH, which may explain the sexual dichotomy observed in these studies of PNEE. Based on these findings, ethanol-exposed animals received postnatal dietary supplementation with either a precursor of GSH, N-Acetylcysteine (NAC) or Omega-3 fatty acids. These supplements helped to counteract the effects of PNEE and improved hippocampal function. The findings in this thesis support the hypothesis that increasing antioxidant capacity can enhance hippocampal function, which in turn may improve learning and memory in FASD, providing a therapeutic avenue for children suffering with these disorders. / Graduate / 0570 Nutrition / 0317 Neuroscience / anna.r.patten@gmail.com

Fetal Alcohol Spectrum Disorders

Prenatal Ethanol Exposure

Electrophysiology

Dentate gyrus

Hippocampus

Oxidative Stress

Omega-3 fatty acids

Glutathione