Fasciculin 2 (FAS), an acetylcholinesterase (AChE) peripheral site ligand that inhibits mammalian AChE in the picomolar range and chicken AChE only at micromolar concentrations, was used in chick retinal cell cultures to evaluate the influence of AChE on neuronal development. The effects of other AChE inhibitors that bind the active and/or the peripheral site of the enzyme [paraoxon, eserine, or 1,5-bis(4-allyldimethylammoniumphenyl) pentan-3-one dibromide (BW284c51)] were also studied. Morphological changes of cultured neurons were observed with the drugs used and in the different cell culture systems studied. Cell aggregates size decreased by more than 35% in diameter after 9 days of FAS treatment, mainly due to reduction in the presumptive plexiform area of the aggregates. Eserine showed no effect on the morphology of the aggregates, although it fully inhibited the activity of AChE. In dense stationary cell culture, cluster formation increased after 3 days and 6 days of FAS treatment. However, FAS, at concentrations in which changes of morphological parameters were observed, did not inhibit the AChE activity as measured histochemically. In contrast, paraoxon treatment produced a slight morphological alteration of the cultures, while a strong inhibition of enzyme activity caused by this agent was observed. BW284c51 showed a harmful, probably toxic effect, also causing a slight AChE inhibition. It is suggested that the effect of an anticholinesterase agent on the morphological modifications of cultured neurons is not necessarily associated with the intensity of the AChE inhibition, especially in the case of FAS. Moreover, most of the effects of AChE on culture morphology appear to be independent of the cholinolytic activity of the enzyme. The results obtained demonstrate that FAS is not toxic for the cells and suggest that regions of the AChE molecule related to the enzyme peripheral site are likely to be involved with the nonclassical role of AChE.
Epidemiological studies have shown that flavonoid-rich plants induce beneficial health effects that are likely beyond their potent antioxidant capacity. Thus, the mechanisms by which Achyrocline satureioides (AS), a popular South American medicinal plant, protects cells and neurons in culture, are still unclear. In this sense, a recently described trophic capacity for flavonoids, similar to that evoked by growth factors, could be one of the mechanisms involved in AS cellular protection. Since this trophic activity causes differentiation of PC12 cells, the cell differentiation capacity of AS and some of its flavonoids were evaluated. PC12 cells were treated with AS infusion (10 or 20 microg/mL of total polyphenols), quercetin (Q) (12.5 or 25 microm), luteolin (L) (25 microm), Q + L (12.5 microm each one) or nerve growth factor (NGF) for 3 days. Four morphological parameters (percentage of cells with neurites longer than one cell body diameter, percentage of cells with neurites, average number of neurites per cell and percentage of fusiform cells) were explored. The AS infusion showed differentiation capacity on all parameters with similar potency when compared with NGF. Besides, AS was more potent than some of its constituent flavonoids: Q, L or their combination.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.