Browsing by Author "Glazer, Lilah"
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Item Open Access Adult exposure to insecticides causes persistent behavioral and neurochemical alterations in zebrafish.(Neurotoxicology and teratology, 2020-03) Hawkey, Andrew B; Glazer, Lilah; Dean, Cassandra; Wells, Corinne N; Odamah, Kathryn-Ann; Slotkin, Theodore A; Seidler, Frederic J; Levin, Edward DFarmers are often chronically exposed to insecticides, which may present health risks including increased risk of neurobehavioral impairment during adulthood and across aging. Experimental animal studies complement epidemiological studies to help determine the cause-and-effect relationship between chronic adult insecticide exposure and behavioral dysfunction. With the zebrafish model, we examined short and long-term neurobehavioral effects of exposure to either an organochlorine insecticide, dichlorodiphenyltrichloroethane (DDT) or an organophosphate insecticide chlorpyrifos (CPF). Adult fish were exposed continuously for either two or 5 weeks (10-30 nM DDT, 0.3-3 μM CPF), with short- and long-term effects assessed at 1-week post-exposure and at 14 months of age respectively. The behavioral test battery included tests of locomotor activity, tap startle, social behavior, anxiety, predator avoidance and learning. Long-term effects on neurochemical indices of cholinergic function were also assessed. Two weeks of DDT exposure had only slight effects on locomotor activity, while a longer five-week exposure led to hypoactivity and increased anxiety-like diving responses and predator avoidance at 1-week post-exposure. When tested at 14 months of age, these fish showed hypoactivity and increased startle responses. Cholinergic function was not found to be significantly altered by DDT. The two-week CPF exposure led to reductions in anxiety-like diving and increases in shoaling responses at the 1-week time point, but these effects did not persist through 14 months of age. Nevertheless, there were persistent decrements in cholinergic presynaptic activity. A five-week CPF exposure led to long-term effects including locomotor hyperactivity and impaired predator avoidance at 14 months of age, although no effects were apparent at the 1-week time point. These studies documented neurobehavioral effects of adult exposure to chronic doses of either organochlorine or organophosphate pesticides that can be characterized in zebrafish. Zebrafish provide a low-cost model that has a variety of advantages for mechanistic studies and may be used to expand our understanding of neurobehavioral toxicity in adulthood, including the potential for such toxicity to influence behavior and development during aging.Item Open Access Developmental exposure of zebrafish to vitamin D receptor acting drugs and environmental toxicants disrupts behavioral function.(Neurotoxicology and teratology, 2020-09) Oliveri, Anthony N; Glazer, Lilah; Mahapatra, Debabrata; Kullman, Seth W; Levin, Edward DVitamin D receptor (VDR) signaling is important for optimal neurobehavioral development. Disruption of VDR signaling by environmental toxicants during early development might contribute to the etiology of behavioral dysfunction. In the current set of studies, we examined ten compounds known to affect VDR function in vitro for neurobehavioral effects in vivo in zebrafish. Zebrafish embryos were exposed to concentrations of the compounds in their water during the first 5 days post-fertilization. On day 5, the embryos were tested in an alternating light-dark locomotor assay using a computerized video tracking system. We found that most of the compounds produced significant changes in locomotor behavior in exposed zebrafish larvae, although the direction of the effect (i.e., hypo- or hyperactivity) and the sensitivity of the effect to changes in illumination condition varied across the compounds. The nature of the behavioral effects generally corresponded to the effects these compounds have been shown to exert on VDR. These studies lay a foundation for further investigation to determine whether behavioral dysfunction persists into adulthood and if so which behavioral functions are affected. Zebrafish can be useful for screening compounds identified in high throughput in vitro assays to provide an initial test for how those compounds would affect construction and behavioral function of a complex nervous system, helping to bridge the gap between in vitro neurotoxicity assays and mammalian models for risk assessment in humans.Item Open Access Developmental Exposure to Low Concentrations of Organophosphate Flame Retardants Causes Life-Long Behavioral Alterations in Zebrafish.(Toxicological sciences : an official journal of the Society of Toxicology, 2018-10) Glazer, Lilah; Hawkey, Andrew B; Wells, Corinne N; Drastal, Meghan; Odamah, Kathryn-Ann; Behl, Mamta; Levin, Edward DAs the older class of brominated flame retardants (BFRs) are phased out of commercial use because of findings of neurotoxicity with developmental exposure, a newer class of flame retardants have been introduced, the organophosphate flame retardants (OPFRs). Presently, little is known about the potential for developmental neurotoxicity or the behavioral consequences of OPFR exposure. Our aim was to characterize the life-long neurobehavioral effects of 4 widely used OPFRs using the zebrafish model. Zebrafish embryos were exposed to 0.1% DMSO (vehicle control); or one of the following treatments; isopropylated phenyl phosphate (IPP) (0.01, 0.03, 0.1, 0.3 µM); butylphenyl diphenyl phosphate (BPDP) (0.003, 0.03, 0.3, 3 µM); 2-ethylhexyl diphenyl phosphate (EHDP) (0.03, 0.3, 1 µM); isodecyl diphenyl phosphate (IDDP) (0.1, 0.3, 1, 10 µM) from 0- to 5-days postfertilization. On Day 6, the larvae were tested for motility under alternating dark and light conditions. Finally, at 5-7 months of age the exposed fish and controls were tested on a battery of behavioral tests to assess emotional function, sensorimotor response, social interaction and predator evasion. These tests showed chemical-specific short-term effects of altered motility in larvae in all of the tested compounds, and long-term impairment of anxiety-related behavior in adults following IPP, BPDP, or EHDP exposures. Our results show that OPFRs may not be a safe alternative to the phased-out BFRs and may cause behavioral impacts throughout the lifespan. Further research should evaluate the risk to mammalian experimental models and humans.Item Open Access Zebrafish show long-term behavioral impairments resulting from developmental vitamin D deficiency.(Physiology & behavior, 2020-10) Oliveri, Anthony N; Knuth, Megan; Glazer, Lilah; Bailey, Jordan; Kullman, Seth W; Levin, Edward DVitamin D has been shown in a wide variety of species to play critical roles in neurodevelopment. Vitamin D deficiency disrupts development of the brain and can cause lasting behavioral dysfunction. Zebrafish have become an important model for the study of development in general and neurodevelopment in particular. Zebrafish were used in the current study to characterize the effects of developmental vitamin D deficiency on behavioral function. Adult zebrafish that had been chronically fed a vitamin D deficient or replete diets were bred and the offspring were continued on those diets. The offspring were behaviorally tested as adults. In the novel tank diving test the vitamin D deficient diet significantly lowered the vertical position of fish indicative of more anxiety-like behavior. In the novel tank diving test swimming activity was also significantly decreased by vitamin D deficiency. Startle response was increased by developmental vitamin D deficiency during the early part of the test. No significant effects of vitamin D deficiency were seen with social affiliation and predatory stimulus avoidance tests. These results indicate a phenotype of vitamin D deficiency characterized by more anxiety-like behavior. This result was relatively specific inasmuch as few or no behavioral effects were seen in other behavioral tests.