茎尖分生组织与植物体结构：一项跨物种比较研究。

Shoot apical meristem and plant body organization: a cross-species comparative study.

作者信息

Schnablová Renáta, Herben Tomáš, Klimešová Jitka

机构信息

Institute of Botany, Czech Academy of Sciences, CZ-252 43 Pruhonice, Czech Republic.

Institute of Botany, Czech Academy of Sciences, CZ-252 43 Průhonice, Czech Republic.

出版信息

Ann Bot. 2017 Nov 10;120(5):833-843. doi: 10.1093/aob/mcx116.

DOI:10.1093/aob/mcx116

PMID:29136411

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5737494/

Abstract

BACKGROUND AND AIMS

The shoot apical meristem (SAM) is the key organizing element in the plant body and is responsible for the core of plant body organization and shape. Surprisingly, there are almost no comparative data that would show links between parameters of the SAM and whole-plant traits as drivers of the plant's response to the environment.

METHODS

Interspecific differences in SAM anatomy were examined in 104 perennial herbaceous angiosperms.

KEY RESULTS

There were differences in SAM parameters among individual species, their phylogenetic patterns, and how their variation is linked to variation in plant above-ground organs and hence species' environmental niches. SAM parameters were correlated with the size-related traits of leaf area, seed mass and stem diameter. Of the two key SAM parameters (cell size and number), variation in all organ traits was linked more strongly to cell number, with cell size being important only for seed mass. Some of these correlations were due to shared phylogenetic history (e.g. SAM diameter versus stem diameter), whereas others were due to parallel evolution (e.g. SAM cell size and seed mass).

CONCLUSION

These findings show that SAM parameters provide a functional link among sizes and numbers of plant organs, constituting species' environmental responses.

摘要

背景与目的

茎尖分生组织（SAM）是植物体内的关键组织元件，负责植物体的组织和形态构建的核心。令人惊讶的是，几乎没有比较数据能表明SAM的参数与作为植物对环境响应驱动因素的全株性状之间的联系。

方法

在104种多年生草本被子植物中研究了SAM解剖结构的种间差异。

关键结果

不同物种之间的SAM参数、它们的系统发育模式，以及它们的变异如何与植物地上器官的变异相关联，进而与物种的环境生态位存在差异。SAM参数与叶面积、种子质量和茎直径等与大小相关的性状相关。在两个关键的SAM参数（细胞大小和数量）中，所有器官性状的变异与细胞数量的联系更为紧密，细胞大小仅对种子质量有重要影响。其中一些相关性是由于共同的系统发育历史（例如SAM直径与茎直径），而其他一些则是由于平行进化（例如SAM细胞大小和种子质量）。

结论

这些发现表明，SAM参数在植物器官的大小和数量之间提供了功能联系，构成了物种对环境的响应。

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