Pre-synaptic/post-synaptic neurons were electrically silenced by

Pre-synaptic/post-synaptic neurons were electrically silenced by Kir2.1 potassium channel overexpression. Single axon tracing showed that, after reaching the cortical innervation area, green fluorescent protein-labeled callosal axons underwent successive developmental Selleck BYL719 stages: axon growth, branching, layer-specific targeting and arbor formation

between post-natal day (P)5 and P9, and the subsequent elaboration of axon arbors between P9 and P15. Reducing pre-synaptic neuronal activity disturbed axon growth and branching before P9, as well as arbor elaboration afterwards. In contrast, silencing post-synaptic neurons disturbed axon arbor elaboration between P9 and P15. Thus, pre-synaptic neuron silencing affected significantly earlier stages of callosal projection neuron axon development than post-synaptic neuron silencing. Silencing both pre-synaptic and post-synaptic neurons impaired callosal axon projections, suggesting that certain levels of firing activity in pre-synaptic and post-synaptic neurons are required for callosal axon development. Our findings provide in-vivo evidence that pre-synaptic and post-synaptic neuronal activities play critical, and presumably differential, roles in axon growth, branching, arbor formation and elaboration during cortical axon development. “
“Bats can orient and hunt for prey in complete darkness

using echolocation. Due to the pulse-like character of call emission they receive a stroboscopic view of their environment. Vemurafenib purchase During target approach, bats adjust their emitted echolocation calls to the specific requirements of the dynamically changing environmental and behavioral context. In addition to changes of the spectro-temporal call features, the spatial focusing of the beam of the sonar emissions onto

the target is a conspicuous feature during target tracking. The neural processes underlying the complex sensory-motor interactions during target tracking are not well understood. In this study, we used a two-tone-pulse paradigm with 81 combinations of inter-aural intensity differences and six inter-pulse intervals Chlormezanone in a passive hearing task to tackle the question of how transient changes in the azimuthal position of successive sounds are encoded by neurons in the auditory cortex of the bat Phyllostomus discolor. In a population of cortical neurons (11%, 24 of 217), spatial receptive fields were focused to a small region of frontal azimuthal positions during dynamic stimulation with tone-pulse pairs at short inter-pulse intervals. The response of these neurons might be important for the behaviorally observed locking of the sonar beam onto a selected target during the later stages of target tracking. Most interestingly, the majority of these neurons (88%, 21 of 24) were located in the posterior dorsal part of the auditory cortex.

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