Publikation: Dissociated neurons of the pupal honeybee brain in cell culture
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Primary cell cultures were prepared from specific regions of the pupal honeybee brain which are involved in proboscis extension learning. Defined areas could be dissociated purely by mechanical treatment. We show that cultured neurons regenerate new neurites and remain viable for up to three weeks in a serum-free, chemically-defined medium. Several labelling techniques were employed to identify subpopulations of cultured neurons. For example, acetylcholinesterase staining; fluorescent beads to distinguish identified cell populations of co-cultured brain areas; various markers for surface antigens such as a monoclonal antibody to olfactory projection neurons of the antennoglomerular tracts and monopolar cells of the optic lobes, as well as anti-HRP immunoreactivity and agr-bungarotoxin binding; and various antisera for detecting transmitter phenotype. The appearance of transmitter-immunoreactive cells agreed closely with that expected from their known distributionin situ. Our results suggest that cultured cells retain surface properties and transmitter phenotype of theirin vivo counterparts, despite differences in basic morphology. Thus our culture system provides the important initial step for futurein vitro investigations of the cellular and electrophysiological properties of neurons mediating proboscis extension learning.
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KREISSL, Sabine, Gerd BICKER, 1992. Dissociated neurons of the pupal honeybee brain in cell culture. In: Journal of Neurocytology. 1992, 21(8), pp. 545-556. ISSN 0300-4864. Available under: doi: 10.1007/BF01187116BibTex
@article{Kreil1992Disso-16329, year={1992}, doi={10.1007/BF01187116}, title={Dissociated neurons of the pupal honeybee brain in cell culture}, number={8}, volume={21}, issn={0300-4864}, journal={Journal of Neurocytology}, pages={545--556}, author={Kreißl, Sabine and Bicker, Gerd} }
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