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Publication : Non-enzymatic developmental functions of acetylcholinesterase--the question of redundancy.

First Author  Johnson G Year  2008
Journal  FEBS J Volume  275
Issue  20 Pages  5129-38
PubMed ID  18785927 Mgi Jnum  J:143115
Mgi Id  MGI:3822945 Doi  10.1111/j.1742-4658.2008.06644.x
Citation  Johnson G, et al. (2008) Non-enzymatic developmental functions of acetylcholinesterase--the question of redundancy. FEBS J 275(20):5129-38
abstractText  Despite in vitro demonstrations of non-enzymatic morphogenetic functions in acetylcholinesterase (AChE), the AChE knockout phenotype is milder than might be expected, casting doubt upon the relevance of such functions in vivo. Functional redundancy is a possible explanation. Using in vitro findings that AChE is able to bind to laminin-111, together with detailed information about the interaction sites, as well as an epitope analysis of adhesion-inhibiting anti-AChE mAbs, we have used molecular docking and bioinformatics techniques to explore this idea, investigating structurally similar molecules that have a comparable spatiotemporal expression pattern in the embryonic nervous system. On this basis, molecules with which AChE could be redundant are the syndecans, glypicans, perlecan, the receptor tyrosine kinase Mer, and the low-density lipoprotein receptor. It is also highly likely that AChE may be redundant with the homologous neuroligins, although there is no evidence that the latter are expressed before synaptogenesis. AChE was observed to dock with Gas6, the ligand for Mer, as well as with apolipoprotein E3 (but not apolipoprotein E4), both at the same site as the laminin interaction. These findings suggest that AChE may show direct functional redundancy with one or more of these molecules; it is also possible that it may itself have a unique function in the stabilization of the basement membrane. As basement membrane molecules are characterized by multiple molecular interactions, each contributing cumulatively to the construction and stability of the network, this may account for AChE's apparently promiscuous interactions, and also for the survival of the knockout.
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