Adolescent Stress–Induced Epigenetic Control of Dopaminergic Neurons via Glucocorticoids

Defeat, Distress, and Glucocorticoids Understanding how individuals control emotions and cope with stressful events is a major clinical concern and of importance for the treatment of psychiatric illnesses (see the Perspective by McEwen). Barik et al. (p. 332) discovered that aggressive defeat stress in mice caused glucocortioid release and increased activity in the dopamine system. Deleting the glucocorticoid receptors in dopaminoceptive neurons completely prevented the social avoidance that usually follows aggressive defeat. How the combination of genetic factors and environmental stressors during adolescence determines adult behavior and how their disturbance results in neuropsychiatric disorders is poorly understood. Niwa et al. (p. 335) found that isolation stress during adolescence, which does not cause any long-lasting changes in wild-type mice, induced significant neurochemical and behavioral alterations in mutant mice expressing a dominant-negative variant of the disrupted in schizophrenia 1 gene under the control of the prion protein promoter. These deficits could be reversed by a glucocorticoid receptor antagonist. Genetically susceptible mice isolated during adolescence can subsequently present schizophrenia-like symptoms. [Also see Perspective by McEwen] Environmental stressors during childhood and adolescence influence postnatal brain maturation and human behavioral patterns in adulthood. Accordingly, excess stressors result in adult-onset neuropsychiatric disorders. We describe an underlying mechanism in which glucocorticoids link adolescent stressors to epigenetic controls in neurons. In a mouse model of this phenomenon, a mild isolation stress affects the mesocortical projection of dopaminergic neurons in which DNA hypermethylation of the tyrosine hydroxylase gene is elicited, but only when combined with a relevant genetic risk for neuropsychiatric disorders. These molecular changes are associated with several neurochemical and behavioral deficits that occur in this mouse model, all of which are blocked by a glucocorticoid receptor antagonist. The biology and phenotypes of the mouse models resemble those of psychotic depression, a common and debilitating psychiatric disease.

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