Molecular signatures of neural connectivity in the olfactory cortex.

The ability to target subclasses of neurons with defined connectivity is crucial for uncovering neural circuit functions. The olfactory (piriform) cortex is thought to generate odour percepts and memories, and odour information encoded in piriform is routed to target brain areas involved in multimodal sensory integration, cognition and motor control. However, it remains unknown if piriform outputs are spatially organized, and if distinct output channels are delineated by different gene expression patterns.

Massive normalization of olfactory bulb output in mice with a 'monoclonal nose'.

Perturbations in neural circuits can provide mechanistic understanding of the neural correlates of behavior. In M71 transgenic mice with a "monoclonal nose", glomerular input patterns in the olfactory bulb are massively perturbed and olfactory behaviors are altered. To gain insights into how olfactory circuits can process such degraded inputs we characterized odor-evoked responses of olfactory bulb mitral cells and interneurons.

Promotion of cortico-cerebral precursors expansion by artificial pri-miRNAs targeted against the Emx2 locus.

Emx2 encodes for a transcription factor controlling several aspects of cerebral cortex development. Its overexpression promotes self-renewal of young cortico-cerebral precursors, it promotes neuronal rather than gliogenic fates and it protects neuronal progenitors from cell death. These are all key activities for purposes of gene-promoted brain repair.

Olfactory deficits cause anxiety-like behaviors in mice.

Anxiety disorders are characterized by persistent fear in the absence of immediate threat and represent the most common psychiatric diseases, with an estimated 28% lifetime prevalence worldwide (Kessler et al., 2010). While symptoms of anxiety are typically evoked by sensory stimuli, it is unknown whether sensory deficits contribute to the development of anxiety disorders.