Kavli Affiliate: Menno Witter, Asgeir Kobro-Flatmoen
| Authors: Katrine Sjaastad Hanssen, Menno P. Witter, Axel Sandvig, Ioanna Sandvig and Asgeir Kobro-Flatmoen
| Summary:
Abstract Background Primary neuronal cultures enable cell-biological studies of Alzheimer’s disease (AD), albeit typically non-neuron-specific. The first cortical neurons affected in AD reside in layer II of the lateralmost part of the entorhinal cortex, and they undergo early accumulation of intracellular amyloid-β, form subsequent tau pathology, and start degenerating pre-symptomatically. These vulnerable entorhinal neurons uniquely express the glycoprotein reelin and provide selective inputs to the hippocampal memory system. Gaining a more direct access to study these neurons is therefore highly relevant. New method We demonstrate a methodological approach for microdissection and long-term culturing of adult lateral entorhinal layer II-neurons from AD-model mice. Results We maintain adult microdissected lateralmost entorhinal layer II-neurons beyond two months in culture. We show that they express neuronal markers, and that they are electrophysiologically active by 15 days in vitro and continuing beyond 2 months. Comparison with existing methods Primary neurons are typically harvested from embryonic or early postnatal brains because such neurons are easier to culture compared to adult neurons. Methods to culture adult primary neurons have been reported, however, to our knowledge, culturing of adult entorhinal subregion-specific primary neurons from AD-model animals has not been reported. Conclusions Our methodological approach offers a window to study initial pathological changes in the AD disease-cascade. This includes the study of proteinopathy, single-neuron changes, and network-level dysfunction. Highlights We microdissect and culture neurons from layer II of the lateralmost part of the entorhinal cortex from adult AD model mice and littermate controls These entorhinal neurons self-organize into networks, express reelin, NeuN and intracellular amyloid-β. The neurons are electrophysiologically active by day 15 in culture and remain viable beyond two months. Competing Interest Statement The authors have declared no competing interest.