| Literature DB >> 28283883 |
Wenqing Yan1,2, Wenwen Liu1,2, Jieyu Qi3,4,5, Qiaojun Fang3,4,5, Zhaomin Fan1,2, Gaoying Sun1,2, Yuechen Han1,2, Daogong Zhang1,2, Lei Xu1,2, Mingming Wang1,2, Jianfeng Li1,2, Fangyi Chen6, Dong Liu7, Renjie Chai8,9,10, Haibo Wang11,12.
Abstract
In vitro culture of spiral ganglion neurons (SGNs) is a useful approach to investigate numerous aspects of neuronal behavior and to identify potential therapeutic targets for SGN protection and regeneration. However, the isolation of SGNs and the long-term maintenance of their structure and function in vitro remain challenging. In this study, we isolated SGNs from Bhlhb5-cre and Rosa26-tdTomato mice with fluorescence-activated cell sorting and determined the cell purity. We then encapsulated the pure SGNs in matrigel and cultured the SGNs in vitro. We found that the three-dimensional (3D)-matrigel culture environment significantly suppressed apoptosis and improved SGN survival in vitro, which enabled the long-term culture of SGNs for up to 6 months. The 3D-matrigel system also significantly promoted neurite outgrowth of the SGNs, increased the cells' polarity, promoted the area of growth cones, and significantly increased the synapse density of the SGNs. More importantly, the 3D-matrigel system helped to maintain and promote the electrophysiological properties of the SGNs. In conclusion, the 3D-matrigel culture system promoted the survival of purified SGNs in vitro and maintained their morphological structure and function and thus could be a useful tool for studying the physiology and pathophysiology of purified SGNs in long-term culture.Entities:
Keywords: Mutant mice; Patch clamp; Spiral ganglion neurons; Three-dimensional culture
Mesh:
Substances:
Year: 2017 PMID: 28283883 DOI: 10.1007/s12035-017-0471-0
Source DB: PubMed Journal: Mol Neurobiol ISSN: 0893-7648 Impact factor: 5.590