叶解剖结构与 C3+CAM 杂交种丝兰的 CAM 功能无关。

Leaf anatomy is not correlated to CAM function in a C3+CAM hybrid species, Yucca gloriosa.

机构信息

School of Life Sciences, University of Hawai'i at Mānoa, Honolulu, HI, USA.

Department of Ecology and Evolutionary Biology, Yale University, New Haven, CT, USA.

出版信息

Ann Bot. 2021 Mar 24;127(4):437-449. doi: 10.1093/aob/mcaa036.

DOI:10.1093/aob/mcaa036

PMID:32166326

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7988526/

Abstract

BACKGROUND AND AIMS

Crassulacean acid metabolism (CAM) is often considered to be a complex trait, requiring orchestration of leaf anatomy and physiology for optimal performance. However, the observation of trait correlations is based largely on comparisons between C3 and strong CAM species, resulting in a lack of understanding as to how such traits evolve and the level of intraspecific variability for CAM and associated traits.

METHODS

To understand intraspecific variation for traits underlying CAM and how these traits might assemble over evolutionary time, we conducted detailed time course physiological screens and measured aspects of leaf anatomy in 24 genotypes of a C3+CAM hybrid species, Yucca gloriosa (Asparagaceae). Comparisons were made to Y. gloriosa's progenitor species, Y. filamentosa (C3) and Y. aloifolia (CAM).

KEY RESULTS

Based on gas exchange and measurement of leaf acids, Y. gloriosa appears to use both C3 and CAM, and varies across genotypes in the degree to which CAM can be upregulated under drought stress. While correlations between leaf anatomy and physiology exist when testing across all three Yucca species, such correlations break down at the species level in Y. gloriosa.

CONCLUSIONS

The variation in CAM upregulation in Y. gloriosa is a result of its relatively recent hybrid origin. The lack of trait correlations between anatomy and physiology within Y. gloriosa indicate that the evolution of CAM, at least initially, can proceed through a wide combination of anatomical traits, and more favourable combinations are eventually selected for in strong CAM plants.

摘要

背景与目的

景天酸代谢（CAM）通常被认为是一种复杂的特征，需要协调叶片解剖结构和生理学以达到最佳性能。然而，对特征相关性的观察主要是基于 C3 和强 CAM 物种之间的比较，导致对这些特征如何进化以及 CAM 和相关特征的种内变异性水平缺乏了解。

方法

为了了解 CAM 相关特征的种内变异以及这些特征如何在进化过程中组装，我们对 24 个 C3+CAM 杂交种（丝兰属）的 Yucca gloriosa 进行了详细的时间过程生理筛选，并测量了叶片解剖结构的各个方面。与 Y. gloriosa 的祖先物种 Y. filamentosa（C3）和 Y. aloifolia（CAM）进行了比较。

主要结果

基于气体交换和叶片酸的测量，Y. gloriosa 似乎同时使用 C3 和 CAM，并且在干旱胁迫下 CAM 上调的程度在不同基因型之间存在差异。虽然在测试所有三种丝兰属物种时，叶片解剖结构和生理学之间存在相关性，但在 Y. gloriosa 中，这种相关性在物种水平上破裂。

结论

Y. gloriosa 中 CAM 上调的变化是其相对较近的杂种起源的结果。Y. gloriosa 中解剖结构和生理学之间缺乏特征相关性表明，CAM 的进化至少可以通过广泛的解剖特征组合进行，并且在强 CAM 植物中最终会选择更有利的组合。

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