Summary
Allium cepa (L.) adventitious roots were treated with lead (2.5 mg of Pb2+ [from Pb(NO3)2] per dm3) for 30–72 h. The cell cycle was studied by pulse labeling with [3H]thymidine. Mitotic activity kinetics, occurrence of disturbed mitoses (c-mitoses), and level of DNA synthesis were examined. It was found that lead prolonged the cell cycle and that cells in two phases of the cycle, G2 and S, differed in their sensitivity to lead. Cells in G2 were more sensitive; lead lengthened their cycle by 216% and disturbed the course of cell division by causing c-mitoses. Cells in S phase were less sensitive. Their cell cycle was longer by 55%. They went through their G2 phase without major disturbances, mitosis in these cells was normal. During treatment ofA. cepa with lead, its destructive effects on cells were exerted only during the first few hours (around 6 h) of incubation. That is when the inhibition of mitotic activity, numerous disturbances of cell division, a decline in the number of cells synthesizing DNA, and a lower level of DNA synthesis were observed. As the incubation continued, the above processes were found to return to normal. In the discussion, data are presented supporting the hypothesis that during the initial period of exposure ofA. cepa to lead, this metal enters both the root apoplast and symplast, exerting a destructive effect on cells, while later, lead penetrates only into the root apoplast, and in this way remains harmless to cells.
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Wierzbicka, M. The effect of lead on the cell cycle in the root meristem ofAllium cepa L.. Protoplasma 207, 186–194 (1999). https://doi.org/10.1007/BF01282999
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DOI: https://doi.org/10.1007/BF01282999