Measures of Anxiety in Zebrafish (Danio rerio): Dissociation of Black/White Preference and Novel Tank Test

The effects of wall color stimuli on diving, and the effects of depth stimuli on scototaxis, were assessed in zebrafish. Three groups of fish were confined to a black, a white, or a transparent tank, and tested for depth preference. Two groups of fish were confined to a deep or a shallow tank, and tested for black-white preference. As predicted, fish preferred the deep half of a split-tank over the shallow half, and preferred the black half of a black/white tank over the white half. Results indicated that the tank wall color significantly affected depth preference, with the transparent tank producing the strongest depth preference and the black tank producing the weakest preference. Tank depth, however, did not significantly affect color preference. Additionally, wall color significantly affected shuttling and immobility, while depth significantly affected shuttling and thigmotaxis. These results are consistent with previous indications that the diving response and scototaxis may reflect dissociable mechanisms of behavior. We conclude that the two tests are complementary rather than interchangeable, and that further research on the motivational systems underlying behavior in each of the two tests is needed

Zebrafish models for attention deficit hyperactivity disorder (ADHD)

Attention deficit hyperactivity disorder (ADHD) is a common, debilitating neurodevelopmental disorder associated with inattentiveness, pathological hyperactivity and impulsivity. Despite the mounting human and animal evidence, the neurological pathways underlying ADHD remain poorly understood. Novel translational model organisms, such as the zebrafish (Danio rerio), are becoming important tools to investigate genetic and pathophysiological mechanisms of various neuropsychiatric disorders. Here, we discuss ADHD etiology, existing animal models and their limitations, and emphasize the advantages of using zebrafish to model ADHD. Overall, the growing utility of zebrafish models may improve our understanding of ADHD and facilitate drug discovery to prevent or treat this disorder. © 2019 Elsevier Lt

Comparative Analyses of Zebrafish Anxiety-Like Behavior Using Conflict-Based Novelty Tests

Modeling of stress and anxiety in adult zebrafish (Danio rerio) is increasingly utilized in neuroscience research and central nervous system (CNS) drug discovery. Representing the most commonly used zebrafish anxiety models, the novel tank test (NTT) focuses on zebrafish diving in response to potentially threatening stimuli, whereas the light-dark test (LDT) is based on fish scototaxis (innate preference for dark vs. bright areas). Here, we systematically evaluate the utility of these two tests, combining meta-analyses of published literature with comparative in vivo behavioral and whole-body endocrine (cortisol) testing. Overall, the NTT and LDT behaviors demonstrate a generally good cross-test correlation in vivo, whereas meta-analyses of published literature show that both tests have similar sensitivity to zebrafish anxiety-like states. Finally, NTT evokes higher levels of cortisol, likely representing a more stressful procedure than LDT. Collectively, our study reappraises NTT and LDT for studying anxiety-like states in zebrafish, and emphasizes their developing utility for neurobehavioral research. These findings can help optimize drug screening procedures by choosing more appropriate models for testing anxiolytic or anxiogenic drugs

Modulation of the chelatable Zn pool in the brain by diethyldithiocarbamate is associated with behavioral impairment in adult zebrafish

The study of the effects of diethyldithiocarbamate (DEDTC) in some diseases is in focus for many years. However, DEDTC is a metal chelator that can present neurotoxicity as side effects. Here we investigate the effect of DEDTC on brain Zinc (Zn) content and behavior. To address this issue we used adult zebrafish exposed to different concentrations of DEDTC. The animal’s behavioral parameters were evaluated during the exposure of DEDTC (0.2, 1, 5 mM in home tank water) for 1h. At the end of exposure period, the brain levels of DEDTC were measured. The analysis of reactive Zn content in different regions of the brain and in glutamatergic neurons and radial glial cells were performed using histochemical and immunocytochemical techniques, respectively. We also measured the activity of a Zn-dependent enzyme, δ-aminolevulinate dehydratase (δ-ALA-D). We found that DEDTC exposure at 1 and 5 mM induced seizure-like behavior in the zebrafish and death at 5 mM. DEDTC in the zebrafish brain was detected with exposure of 1 and 5 mM (above 100 mg.kg⁻¹ tissue). The reactive Zn was reduced in glutamatergic neurons after 1 and 5 mM DEDTC exposure in radial glial cells after 0.2 and 5 mM. No changes in brain δ-ALA-D activity were detected. Our results showed that DEDTC exposure can accumulate in the brain, leading to impairments in neural behavior and in the homeostasis of reactive Zn in the brain.Keywords: reactive Zn, diethyldithiocarbamate, δ-aminolevulinate-dehydratase, brain, zebrafish, [delta-aminolevulinate-dehydratase]Keywords: reactive Zn, diethyldithiocarbamate, δ-aminolevulinate-dehydratase, brain, zebrafish, [delta-aminolevulinate-dehydratase

Frequency of shuttling (center-crossing).

<p>The effect of black, white, and transparent stimuli on shuttling is plotted in <b>panel a</b>; animals in transparent tanks shuttled less frequently than those in black or white tanks. The effect of deep and shallow stimuli on color preference is plotted in <b>panel b</b>; animals in shallow tanks shuttled less frequently than those in deep tanks.</p