A functional genetic variation of SLC6A2 repressor hsa-miR-579-3p upregulates sympathetic noradrenergic processes of fear and anxiety

Increased sympathetic noradrenergic signaling is crucially involved in fear and anxiety as defensive states. MicroRNAs regulate dynamic gene expression during synaptic plasticity and genetic variation of microRNAs modulating noradrenaline transporter gene (SLC6A2) expression may thus lead to altered central and peripheral processing of fear and anxiety. In silico prediction of microRNA regulation of SLC6A2 was confirmed by luciferase reporter assays and identified hsa-miR-579-3p as a regulating microRNA. The minor (T)-allele of rs2910931 (MAF(cases) = 0.431, MAF(controls) = 0.368) upstream of MIR579 was associated with panic disorder in patients (p(allelic) = 0.004, n(cases) = 506, n(controls) = 506) and with higher trait anxiety in healthy individuals (p(ASI) = 0.029, p(ACQ) = 0.047, n = 3112). Compared to the major (A)allele, increased promoter activity was observed in luciferase reporter assays in vitro suggesting more effective MIR579 expression and SLC6A2 repression in vivo (p = 0.041). Healthy individuals carrying at least one (T)-allele showed a brain activation pattern suggesting increased defensive responding and sympathetic noradrenergic activation in midbrain and limbic areas during the extinction of conditioned fear. Panic disorder patients carrying two (T)-alleles showed elevated heart rates in an anxiety-provoking behavioral avoidance test (F(2, 270) = 5.47, p = 0.005). Fine-tuning of noradrenaline homeostasis by a MIR579 genetic variation modulated central and peripheral sympathetic noradrenergic activation during fear processing and anxiety. This study opens new perspectives on the role of microRNAs in the etiopathogenesis of anxiety disorders, particularly their cardiovascular symptoms and comorbidities

Increased fear learning, spatial learning as well as neophobia in Rgs2(-/-) mice

Anxiety disorders result from a complex interplay of genetic and environmental factors such as stress. On the level of cellular signaling, regulator of G protein signaling 2 (Rgs2) has been implicated in human and rodent anxiety. However, there is limited knowledge about the role of Rgs2 in fear learning and reactivity to stress. In the present study, Rgs2(-/-) mice showed increased fear learning, male mice displayed increased contextual and cued fear learning, while females showed selectively enhanced cued fear learning. Male Rgs2(-/-) mice displayed increased long-term-contextual fear memory, but increased cued fear extinction. Learning in spatial non-aversive paradigms was also increased in Rgs2(-/-) mice. Female, but not male mice show increased spatial learning in the Barnes maze, while male mice showed enhanced place preference in the IntelliCage, rendering enhanced cognitive function non-specific for aversive stimuli. Consistent with previous results, Rgs2 deletion resulted in increased innate anxiety, including neophobic behavior expressed as hypo-locomotion, in three different tests based on the approach-avoidance conflict. Acute electric foot shock stress provoked hypo-locomotion in several exploration-based tests, suggesting fear generalization in both genotypes. Rgs2 deletion was associated with reduced monoaminergic neurotransmitter levels in the hippocampus and prefrontal cortex and disturbed corresponding GPCR expression of the adrenergic, serotonergic, dopaminergic and neuropeptide Y system. Taken together, Rgs2 deletion promotes improved cognitive function as well as increased anxiety-like behavior, but has no effect on acute stress reactivity. These effects may be related to the observed disruption of the monoaminergic systems