angptl4 gene expression as a marker of adaptive homeostatic response to social isolation across the lifespan in zebrafish.

Social isolation has detrimental health effects, but the underlying mechanisms are unclear. Here, we investigated the impact of 2 weeks of isolation on behavior and gene expression in the central nervous system at different life stages of zebrafish. Results showed that socially deprived young adult zebrafish experienced increased anxiety, accompanied by changes in gene expression. Most gene expression patterns returned to normal within 24 hours of reintroduction to a social environment, except angptl4, which was upregulated after reintroduction, suggesting an adaptive mechanism. Similarly, aging zebrafish displayed heightened anxiety and increased central nervous system expression of angptl4 during isolation, but effects were reversed upon reintroduction to a social group. The findings imply that angptl4 plays a homeostatic role in response to social isolation, which varies across the lifespan. The study emphasizes the importance of social interactions for psychological well-being and highlights the negative consequences of isolation, especially in older individuals. Further research may unravel how social isolation affects angptl4 expression and its developmental and aging effects.

Zebrafish as a Model of Neurodevelopmental Disorders.

Neurodevelopmental disorders (NDDs) caused by aberrant brain growth and development are life-long, debilitating illnesses that markedly impair the quality of life. Animal models are a valuable tool for studying NDD pathobiology and therapies. Mounting evidence suggests the zebrafish (Danio rerio) as a useful model organism to study NDDs, possessing both high physiological homology to humans and sensitivity to pharmacological and genetic manipulations. Here, we summarize experimental models of NDDs in zebrafish and highlight the growing translational significance of zebrafish NDD-related phenotypes. We also emphasize the need in further development of zebrafish models of NDDs to improve our understanding of their pathogenesis and therapeutic treatments.

Different effects of caffeine on behavioral neurophenotypes of two zebrafish populations.

Caffeine is a substance present in several foods and drinks of common western diet. Although high caffeine concentrations induce anxiogenic properties in various species, the influence of the different baselines of anxiety levels on caffeine-mediated responses is poorly understood. The short-fin wild-type (WT) and leopard (leo) zebrafish populations present significant behavioral differences, in which leo shows exacerbated anxiety-like responses. Since behavioral neurophenotyping may be easily assessed in adult zebrafish by associating temporal and spatial three-dimensional reconstructions of locomotion, we investigated the effects of caffeine on exploration and anxiety-like behavior of WT and leo zebrafish. Moreover, the whole-body cortisol content was assessed in the absence and presence of caffeine. For this purpose, animals were acutely exposed to caffeine (25, 50, 100 and 200mg/L) for 15min and further tested in the novel tank. Endpoint data and 3D reconstruction plots revealed that caffeine was anxiogenic in both WT and leo populations by altering vertical swimming, freezing, and erratic movements depending on the concentration. Prominent anxiogenic effects during habituation to novelty were observed in WT, suggesting a fundamental role of the phenotype in caffeine-mediated neurobehavioral responses. Although untreated leo showed higher baseline cortisol levels than control WT, caffeine increased whole-body cortisol in both populations. Moreover, caffeine induced aberrant swimming profiles in WT and leo following 200mg/L exposure, which could reflect nonspecific toxicity and/or seizure-like behaviors. Collectively, our novel findings show that caffeine effects in zebrafish differ in a population-dependent manner.