The neural network undergoes remodeling in response to neural activity and interventions, such as antidepressants. Cell adhesion molecules that link pre- and post-synaptic membranes are responsible not only for the establishment of the neural circuitry, but also for the modulation of the strength of each synaptic connection. Among the various classes of synaptic cell adhesion molecules, a non-clustered protocadherin, Arcadlin/Paraxial protocadherin/Protocadherin-8 (Acad), is unique in that it is induced quickly in response to neural activity. Although the primary structure of Arcadlin implies its cell adhesion activity, it weakens the adhesion of N-cadherin. Furthermore, Arcadlin reduces the dendritic spine density in cultured hippocampal neurons. In order to gain an insight into the function of Arcadlin in the brain, we examined the dendritic morphologies of the hippocampal neurons in Acad-/- mice. Acad-/- mice showed a higher spine density than wild-type mice. Following an electroconvulsive seizure (ECS), which strongly induces Arcadlin in the hippocampus, the spine density gradually decreased for 8 h. ECS did not reduce the spine density of CA1 apical dendrites in Acad-/- mice. Daily intraperitoneal injection of the antidepressant fluoxetine (25 mg/kg/day) for 18 days resulted in the induction of Arcadlin in the hippocampus. This treatment reduced spine density in the dentate gyrus and CA1. Chronic fluoxetine treatment did not suppress spine density in Acad-/- mice, suggesting that fluoxetine-induced decrease in spine density is largely due to Arcadlin. The present findings confirm the spine-repulsing activity of Arcadlin and its involvement in the remodeling of hippocampal neurons in response to antidepressants.
Keywords: Lucifer yellow; antidepressant; electroconvulsive seizure; protocadherin; self-avoidance; synaptic plasticity.
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