The first dynamic map of early neuronal and sensory progenitors in the whole otic vesicle reveals how progenitor domains remodel upon morphogenesis.

Otic epithelial Fibroblast Growth Factors control the number of cochlear sensory progenitor cells through an FGF responsive periotic mesenchyme.

The elucidation of the cellular composition of the crista and the genes expressed in each cell type is a critical step toward understanding inner ear development, function, and vestibulopathies.

Early postembryonic bodily movement sends neural feedback through dorsal root ganglia to the forebrain in order to regulate the rate of neurogenesis and subsequent brain growth.

Sister projection neurons in the mammalian olfactory system do not share sensory synaptic input indicating that lineage-independent mechanisms regulate their synaptic connectivity with the olfactory sensory neurons.

Single-cell transcriptomic analysis defines hair cell and supporting cell types in the zebrafish inner ear, and reveals homologies with cells in the mammalian ear.

Timing of neural precursor cells division controls the order of development of sensory neurons, which in turn determines their axon terminal pattern and ultimately fly behaviour.

Olfactory sensory neurons have centrioles that are amplified in number and that migrate from the cell body to the end of the dendrite relatively slowly and in groups, becoming mature only after they reach their destination.

Schwann cell induced quiescence of mechanosensory progenitor cells is mediated by inhibition of Wnt/β-catenin signaling.

Single-cell transcriptomics correlated with in situ gene expression analysis provide an overview of the diversity and molecular features of cell types in the squid Loligo vulgaris.