红光下生长的小麦幼苗绿化过程中的根茎相互作用。
Root-shoot interaction in the greening of wheat seedlings grown under red light.
作者信息
Tripathy B C, Brown C S
机构信息
National Aeronautics and Space Administration, Kennedy Space Center, Florida 32899, USA.
出版信息
Plant Physiol. 1995 Feb;107(2):407-11. doi: 10.1104/pp.107.2.407.
Abstract
Wheat seedlings grown with roots exposed to constant red light (300-500 micromoles m-2 s-1) did not accumulate chlorophyll in the leaves. In contrast, seedlings grown with their roots shielded from light accumulated chlorophylls. Chlorophyll biosynthesis could be induced in red-light-grown chlorophyll-deficient yellow plants by either reducing the red-light intensity at the root surface to 100 micromoles m-1 s-1 or supplementing with 6% blue light. The inhibition of chlorophyll biosynthesis was due to impairment of the Mg-chelatase enzyme working at the origin of the Mg-tetrapyrrole pathway. The root-perceived photomorphogenic inhibition of shoot greening demonstrates root-shoot interaction in the greening process.
摘要
让根系暴露于持续红光(300 - 500微摩尔·平方米⁻²·秒⁻¹)下生长的小麦幼苗,其叶片中不会积累叶绿素。相比之下,根系被遮光生长的幼苗会积累叶绿素。通过将根系表面的红光强度降低至100微摩尔·平方米⁻¹·秒⁻¹或补充6%的蓝光,可在红光下生长的叶绿素缺乏黄色植株中诱导叶绿素生物合成。叶绿素生物合成的抑制是由于在镁-四吡咯途径起始处起作用的镁螯合酶受到损害。根系感知到的对地上部绿化的光形态建成抑制表明了绿化过程中根与地上部的相互作用。
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