红光抑制玉米幼苗中胚轴伸长:I. 生长素假说。
Red Light-inhibited Mesocotyl Elongation in Maize Seedlings: I. The Auxin Hypothesis.
机构信息
Department of Plant Biology, Carnegie Institution of Washington, Stanford, California 94305.
出版信息
Plant Physiol. 1978 Apr;61(4):534-7. doi: 10.1104/pp.61.4.534.
Abstract
Red light-inhibited mesocotyl elongation, which occurs in intact Zea mays L. seedlings, was studied in excised segments which included the coleoptile (or parts therefrom) and apical centimeter of the mesocotyl. Experiments took into account, first, the ability of the segments to regenerate auxin supply sites, and, second, that auxin uptake can be greatly reduced if there is no cut surface, apical to the elongating cells, to act as a port of entry. In all cases, auxin completely reversed the inhibition of elongation by light. The results support the hypothesis that light regulates mesocotyl elongation by controlling auxin supply from the coleoptile. Sucrose concentration had no effect on auxin reversal of light-inhibited elongation, but relatively high concentrations of gibberellic acid (10 mum) could substitute for auxin in this system.
摘要
红光抑制玉米中胚轴伸长,这一现象发生在完整的玉米幼苗切段中,这些切段包括胚芽鞘(或其部分)和中胚轴的顶端 1 厘米。实验首先考虑了切段重新供应生长素的能力,其次,如果没有位于伸长细胞顶端的切口作为进入点,生长素的吸收可以大大减少。在所有情况下,生长素完全逆转了光对伸长的抑制作用。结果支持了这样一种假设,即光通过控制从胚芽鞘供应的生长素来调节中胚轴伸长。蔗糖浓度对光抑制伸长的生长素逆转没有影响,但在该系统中,相对高浓度的赤霉素(10 微米)可以替代生长素。
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本文引用的文献
1
The nature of spontaneous changes in growth rate in isolated coleoptile segments.离体胚芽鞘切段生长速率自发变化的本质。
Plant Physiol. 1975 Apr;55(4):757-62. doi: 10.1104/pp.55.4.757.
2
Effect of red light on coleoptile growth.红光对胚芽鞘生长的影响。
Plant Physiol. 1974 Sep;54(3):286-8. doi: 10.1104/pp.54.3.286.
3
Effect of light on basipetal movement of indoleacetic Acid in green stem sections of coleus.光照对彩叶草绿色茎切段中吲哚乙酸向基性运动的影响。
Plant Physiol. 1972 May;49(5):866-7. doi: 10.1104/pp.49.5.866.
4
Isolation and properties of the enzyme system forming indoleacetic Acid.形成吲哚乙酸的酶系统的分离与特性
Plant Physiol. 1967 Aug;42(8):1158-60. doi: 10.1104/pp.42.8.1158.
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Transient effects of light on auxin transport in the Avena coleoptile.光对燕麦胚芽鞘中生长素运输的瞬时影响。
Plant Physiol. 1967 Feb;42(2):247-57. doi: 10.1104/pp.42.2.247.
6
Phytochrome changes correlated to mesocotyl inhibition in etiolated Avena seedlings.光敏色素变化与黄化燕麦幼苗中中胚轴抑制相关。
Plant Physiol. 1966 Jun;41(6):932-6. doi: 10.1104/pp.41.6.932.
7
Effects of Gibberellic Acid on Utilization of Auxin Precursors by Apical Segments of the Avena Coleoptile.赤霉素对燕麦胚芽鞘顶端切段生长素前体利用的影响
Plant Physiol. 1965 Mar;40(2):294-8. doi: 10.1104/pp.40.2.294.
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