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MIDA9/PP2C.D1、PP2C.D2和PP2C.D5的顺序作用对于在黑暗中萌发后形成并维持钩状体是必需的。

The Sequential Action of MIDA9/PP2C.D1, PP2C.D2, and PP2C.D5 Is Necessary to Form and Maintain the Hook After Germination in the Dark.

作者信息

Rovira Arnau, Sentandreu Maria, Nagatani Akira, Leivar Pablo, Monte Elena

机构信息

Plant Development and Signal Transduction Program, Center for Research in Agricultural Genomics (CRAG) CSIC-IRTA-UAB-UB, Barcelona, Spain.

Department of Botany, Graduate School of Science, Kyoto University, Kyoto, Japan.

出版信息

Front Plant Sci. 2021 Mar 9;12:636098. doi: 10.3389/fpls.2021.636098. eCollection 2021.

DOI:10.3389/fpls.2021.636098
PMID:33767720
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7985339/
Abstract

During seedling etiolation after germination in the dark, seedlings have closed cotyledons and form an apical hook to protect the meristem as they break through the soil to reach the surface. Once in contact with light, the hook opens and cotyledons are oriented upward and separate. Hook development in the dark after seedling emergence from the seed follows three distinctly timed and sequential phases: formation, maintenance, and eventual opening. We previously identified () as a phytochrome interacting factor (PIF)-repressed gene in the dark necessary for hook development during etiolated growth. encodes the type 2C phosphatase PP2C.D1, and mutants exhibit open hooks in the dark. Recent evidence has described that PP2C.D1 and other PP2C.D members negatively regulate SMALL AUXIN UP RNA (SAUR)-mediated cell elongation. However, the fundamental question of the timing of PP2C.D1 action (and possibly other members of the PP2C.D family) during hook development remains to be addressed. Here, we show that PP2C.D1 is required immediately after germination to form the hook. shows reduced cell expansion in the outer layer of the hook and, therefore, does not establish the differential cell growth necessary for hook formation, indicating that PP2C.D1 is necessary to promote cell elongation during this early stage. Additionally, genetic analyses of single and high order mutants in PP2C.D1, PP2C.D2, and PP2C.D5 demonstrate that the three PP2C.Ds act collectively and sequentially during etiolation: whereas PP2C.D1 dominates hook formation, PP2C.D2 is necessary during the maintenance phase, and PP2C.D5 acts to prevent opening during the third phase together with PP2C.D1 and PP2C.D2. Finally, we uncover a possible connection of PP2C.D1 levels with ethylene physiology, which could help optimize hook formation during post-germinative growth in the dark.

摘要

在黑暗中萌发后的幼苗黄化过程中,幼苗的子叶闭合,并形成一个顶端弯钩,以便在突破土壤到达地表时保护分生组织。一旦接触到光,弯钩就会打开,子叶向上定向并分开。幼苗从种子中萌出后在黑暗中弯钩的发育遵循三个明显定时且连续的阶段:形成、维持和最终打开。我们之前鉴定出()是一种在黑暗中受光敏色素互作因子(PIF)抑制的基因,在黄化生长期间弯钩发育是必需的。该基因编码2C型磷酸酶PP2C.D1,且该基因突变体在黑暗中表现出开放的弯钩。最近的证据表明,PP2C.D1和其他PP2C.D成员负向调节小生长素上调RNA(SAUR)介导的细胞伸长。然而,PP2C.D1(以及可能的PP2C.D家族其他成员)在弯钩发育过程中的作用时机这一基本问题仍有待解决。在这里,我们表明PP2C.D1在萌发后立即需要来形成弯钩。该基因在弯钩外层显示出细胞扩张减少,因此不能建立弯钩形成所需的差异细胞生长,这表明PP2C.D1在这个早期阶段促进细胞伸长是必需的。此外,对PP2C.D1、PP2C.D2和PP2C.D5的单突变体和高阶突变体的遗传分析表明,这三个PP2C.D在黄化过程中共同且顺序地起作用:虽然PP2C.D1在弯钩形成中起主导作用,但PP2C.D2在维持阶段是必需的,而PP2C.D5在第三阶段与PP2C.D1和PP2C.D2一起作用以防止弯钩打开。最后,我们揭示了PP2C.D1水平与乙烯生理之间可能的联系,这可能有助于在黑暗中萌发后的生长过程中优化弯钩形成。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5a55/7985339/e3309d32b1df/fpls-12-636098-g004.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5a55/7985339/7f6efbdfdcd5/fpls-12-636098-g001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5a55/7985339/e3309d32b1df/fpls-12-636098-g004.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5a55/7985339/7f6efbdfdcd5/fpls-12-636098-g001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5a55/7985339/e3309d32b1df/fpls-12-636098-g004.jpg

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