PP 1665: Cognitive Performance As Result of Coordinated Neuronal Activity Within Developing Prefrontal-Hippocampal Circuits

The co-activation of prefrontal and hippocampal networks in oscillatory rhythms is critical for precise information flow in mnemonic and executive tasks, yet its role for cognitive ontogeny is still unknown. This knowledge gap is mainly due to the absence of suitable tools for interrogation of developing circuits. Within a collaborative effort of a “troika” that joins expertise in engineering and validating light-sensitive proteins with neurophysiological and analytical approaches, we elucidated during the first funding period of the Priority Program 1665 the cellular substrate of prefrontal-hippocampal communication and identified key cellular elements of oscillatory coupling. During early neonatal development discontinious theta activity in the hippocampus (HP) drives the local gamma-band synchrony in prefrontal cortex (PFC) via axonal projections. Using novel high-efficiency mutants of channelrhodopsin in combined extracellular and patch-clamp recordings in vivo and in vitro, we activated / silenced the neuronal activity. We identified prefrontal layer II/III pyramidal neurons projecting to layer V neurons as key neurons for the emergence of beta-low gamma oscillations in the neonatal brain. The present project aims at understanding the role of neuronal and network activity in neonatal prefrontal-hippocampal circuits for the maturation of mnemonic and executive abilities. For this, the previously identified key neurons will be silenced during defined developmental time windows using novel light-controlled K+ channels that will be engineered and validated by the troika. Short- and long-term consequences of this selected neuronal manipulation for the connectivity and functional communication (synchrony, spiking patterns, long-range causal interactions) within developing prefrontal-hippocampal networks will be assessed. Moreover, the adult behavioural readout of the early manipulation will be characterized to decide on the necessity of coordinated activity during development for the maturation of mnemonic and executive abilities. On the long-term, the results of these investigations will provide detailed insight into the physiological and pathophysiological principles of cognitive ontogeny.

Principal Investigators
Hegemann, Peter Prof. Dr. (Details) (Experimental Biophysics)

participating organizational facilities of the HU

Duration of Project
Start date: 10/2016
End date: 02/2019

Research Areas
Cellular Neuroscience, Molecular Neuroscience and Neurogenetics, Physiology

Last updated on 2021-15-09 at 11:52