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XB-ART-18014
J Neurobiol 1996 Jul 01;303:425-37. doi: 10.1002/(SICI)1097-4695(199607)30:3<425::AID-NEU10>3.0.CO;2-G.
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Lectins implicate specific carbohydrate domains in electric field stimulated nerve growth and guidance.

Stewart R , Allan DW , McCaig CD .


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Both endogenous lectins and DC electric fields may control aspects of early nerve growth and nerve guidance. To test whether such endogenous cues interact, lectins of varying sugar affinity and valency were studied for effects on electric field induced growth and reorientation of cultured Xenopus neurites. Concanavalin A (Con A), succinylated concanavalin A (S-Con A), and wheat germ agglutinin all completely inhibited field-induced cathodal reorientation. Lentil and pea lectins, which share the same sugar affinity as Con A/S-Con A, were only partially effective in inhibiting reorientation. Because S-Con A does not alter lateral mobility of membrane receptors, the previously accepted notion that Con A inhibited field-induced reorientation by preventing receptors from translocating and becoming redistributed asymmetrically in the membrane may be oversimplified. There are likely to be additional steric interactions that Con A and S-Con A share that inactivate asymmetrically redistributed receptors and prevent reorientation. Additionally, nerves growing in an applied field branch more commonly toward the cathode. Con A and S-Con A alone prevented this development of asymmetric branching. All the lectins tested prevented the normal field-induced increase in nerve growth rate, while all, except peanut agglutinin, prevented the usual faster growth cathodally than anodally. We suggest that lectin interactions with electric field effects in vitro may involve modulation of neuronal nicotinic acetylcholine receptors, neurotrophin receptors, or voltage-dependent calcium channels. Similar interactions between endogenous lectins and endogenous electric fields are to be expected.

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???displayArticle.link??? J Neurobiol
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