支撑不住,植株解体。评“长穗偃麦草小穗轴中独特的离层形成可能是由于 Btr1 和 Btr2 的空间共表达”一文。
The rachis cannot hold, plants fall apart. A commentary on: 'The unique disarticulation layer formed in the rachis of Aegilops longissima likely results from the spatial co-expression of Btr1 and Btr2'.
机构信息
Donald Danforth Plant Science Center, St Louis, MO, USA.
出版信息
Ann Bot. 2021 Feb 9;127(3):vi-vii. doi: 10.1093/aob/mcaa194.
Abstract
This article comments on: Xiaoxue Zeng, Gang Chen, Lei Wang, Akemi Tagiri, Shinji Kikuchi, Hidenori Sassa and Takao Komatsuda, The unique disarticulation layer formed in the rachis of probably results from the spatial co-expression of and , Annals of Botany, Volume 127, Issue 3, 16 February 2021, Pages 297–304, https://doi.org/10.1093/aob/mcaa147
摘要
本文评论了
曾晓雪、陈刚、王雷、贯井明美、菊池伸二、笹原秀典和小松高太郎,可能是由于 和 的空间共表达,导致 羽轴中形成了独特的离层,《植物学年鉴》,2021 年 2 月 16 日,第 127 卷,第 3 期,第 297-304 页,doi:10.1093/aob/mcaa147
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The rachis cannot hold, plants fall apart. A commentary on: 'The unique disarticulation layer formed in the rachis of Aegilops longissima likely results from the spatial co-expression of Btr1 and Btr2'.支撑不住,植株解体。评“长穗偃麦草小穗轴中独特的离层形成可能是由于 Btr1 和 Btr2 的空间共表达”一文。
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