204 research outputs found

    Obsessive compulsive disorders

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    Obsessive-compulsive disorder (OCD) is a common and debilitating psychiatric condition. Relatively little, however, is understood about the etiology and brain basis of OCD despite decades of research. Although neuroimaging findings in OCD frequently report abnormalities of the orbitofrontal cortex, anterior cingulate cortex, and caudate nucleus, new insights into the disorder are urgently needed. In this chapter, we review the current state of this evidence, including neuroimaging studies, genetics, neurochemical investigations, and insights from animal models.</p

    Segregation of Axial Motor and Sensory Pathways via Heterotypic Trans-Axonal Signaling

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    Execution of motor behaviors relies on circuitries effectively integrating immediate sensory feedback to efferent pathways controlling muscle activity. It remains unclear how, during neuromuscular circuit assembly, sensory and motor projections become incorporated into tightly coordinated, yet functionally separate pathways. We report that, within axial nerves, establishment of discrete afferent and efferent pathways depends on coordinate signaling between coextending sensory and motor projections. These heterotypic axon-axon interactions require motor axonal EphA3/EphA4 receptor tyrosine kinases activated by cognate sensory axonal ephrin-A ligands. Genetic elimination of trans-axonal ephrin-A -> EphA signaling in mice triggers drastic motor-sensory miswiring, culminating in functional efferents within proximal afferent pathways. Effective assembly of a key circuit underlying motor behaviors thus critically depends on trans-axonal signaling interactions resolving motor and sensory projections into discrete pathways

    Identification of a microRNA that activates gene expression by repressing nonsense-mediated RNA decay

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    Nonsense-mediated decay (NMD) degrades both normal and aberrant transcripts harboring stop codons in particular contexts. Mutations that perturb NMD cause neurological disorders in humans, suggesting that NMD has roles in the brain. Here, we identify a brain-specific microRNA—miR-128—that represses NMD and thereby controls batteries of transcripts in neural cells. miR-128 represses NMD by targeting the RNA helicase UPF1 and the exon-junction complex core component MLN51. The ability of miR-128 to regulate NMD is a conserved response occurring in frogs, chickens, and mammals. miR-128 levels are dramatically increased in differentiating neuronal cells and during brain development, leading to repressed NMD and upregulation of mRNAs normally targeted for decay by NMD; overrepresented are those encoding proteins controlling neuron development and function. Together, these results suggest the existence of a conserved RNA circuit linking the microRNA and NMD pathways that induces cell type-specific transcripts during development.Ivone G. Bruno, Rachid Karam, Lulu Huang, Anjana Bhardwaj, Chih H. Lou, Eleen Y. Shum, Hye-Won Song, Mark A. Corbett, Wesley D. Gifford, Jozef Gecz, Samuel L. Pfaff, and Miles F. Wilkinso
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