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Male sterility significantly elevates shape variation and fluctuating asymmetry of zygomorphic corolla in gynodioecious (Lamiaceae).在雌雄异株的唇形科植物中,雄性不育显著增加了两侧对称花冠的形状变异和波动不对称性。
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4
3D shape analysis of grass silica short cell phytoliths: a new method for fossil classification and analysis of shape evolution.禾本科植物硅质短细胞植硅体的三维形状分析:一种化石分类及形状演化分析的新方法。
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草类植硅体形态的系统发育、生态和个体内变异性模式。

Phylogenetic, ecological and intraindividual variability patterns in grass phytolith shape.

机构信息

Department of Botany, Faculty of Sciences, Charles University in Prague, Benátská, 2, CZ-128 01 Praha 2, Czech Republic.

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

出版信息

Ann Bot. 2022 Feb 11;129(3):303-314. doi: 10.1093/aob/mcab143.

DOI:10.1093/aob/mcab143
PMID:34849559
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8835630/
Abstract

BACKGROUND AND AIMS

Grass silica short cell (GSSC) phytoliths appear to be the most reliable source of fossil evidence for tracking the evolutionary history and paleoecology of grasses. In recent years, modern techniques that quantitatively assess phytolith shape variation have widened opportunities for the classification of grass fossil phytoliths. However, phylogenetic, ecological and intraindividual variability patterns in phytolith shape remain largely unexplored.

METHODS

The full range of intraindividual phytolith shape variation [3650 two-dimensional (2-D) outlines] from 73 extant grass species, 48 genera, 18 tribes and eight subfamilies (particularly Pooideae) was analysed using geometric morphometric analysis based on semi-landmarks spanning phytolith outlines.

KEY RESULTS

The 2-D phytolith shape is mainly driven by deep-time diversification of grass subfamilies. There is distinct phytolith shape variation in early-diverging lineages of Pooideae (Meliceae, Stipeae). The amount of intraindividual variation in phytolith shape varies among species, resulting in a remarkable pattern across grass phylogeny.

CONCLUSIONS

The phylogenetic pattern in phytolith shape was successfully revealed by applying geometric morphometrics to 2-D phytolith shape outlines, strengthening the potential of phytoliths to track the evolutionary history and paleoecology of grasses. Geometric morphometrics of 2-D phytolith shape is an excellent tool for analysis requiring large numbers of phytolith outlines, making it useful for quantitative palaeoecological reconstruction.

摘要

背景与目的

草硅质短细胞(GSSC)植硅体似乎是追踪草类进化历史和古生态学的最可靠化石证据来源。近年来,定量评估植硅体形状变化的现代技术为草类化石植硅体的分类提供了更多机会。然而,植硅体形状的系统发育、生态和个体内变异性模式在很大程度上仍未得到探索。

方法

使用基于跨越植硅体轮廓的半标志点的几何形态测量分析,分析了 73 种现生禾本科植物、48 属、18 个族和 8 个亚科(特别是 Pooidae)的个体内植硅体形状变化的全范围[3650 个二维(2-D)轮廓]。

主要结果

2-D 植硅体形状主要由禾本科亚科的深时多样化驱动。Pooidae(Meliceae、Stipeae)早期分支的植硅体形状存在明显的变化。不同物种之间的植硅体形状个体内变异量不同,导致在整个禾本科系统发育中呈现出显著的模式。

结论

通过将几何形态测量学应用于 2-D 植硅体形状轮廓,成功揭示了植硅体形状的系统发育模式,增强了植硅体追踪草类进化历史和古生态学的潜力。2-D 植硅体形状的几何形态测量学是一种分析需要大量植硅体轮廓的优秀工具,对于定量古生态重建非常有用。