克隆植物的寿命:为什么它很重要以及如何衡量它。
Longevity of clonal plants: why it matters and how to measure it.
机构信息
Section of Plant Ecology, Institute of Botany, University of Basel, Schönbeinstrasse 6, 4056 Basel, Switzerland.
出版信息
Ann Bot. 2010 Dec;106(6):859-70. doi: 10.1093/aob/mcq191. Epub 2010 Sep 29.
BACKGROUND
Species' life-history and population dynamics are strongly shaped by the longevity of individuals, but life span is one of the least accessible demographic traits, particularly in clonal plants. Continuous vegetative reproduction of genets enables persistence despite low or no sexual reproduction, affecting genet turnover rates and population stability. Therefore, the longevity of clonal plants is of considerable biological interest, but remains relatively poorly known.
SCOPE
Here, we critically review the present knowledge on the longevity of clonal plants and discuss its importance for population persistence. Direct life-span measurements such as growth-ring analysis in woody plants are relatively easy to take, although, for many clonal plants, these methods are not adequate due to the variable growth pattern of ramets and difficult genet identification. Recently, indirect methods have been introduced in which genet size and annual shoot increments are used to estimate genet age. These methods, often based on molecular techniques, allow the investigation of genet size and age structure of whole populations, a crucial issue for understanding their viability and persistence. However, indirect estimates of clonal longevity are impeded because the process of ageing in clonal plants is still poorly understood and because their size and age are not always well correlated. Alternative estimators for genet life span such as somatic mutations have recently been suggested.
CONCLUSIONS
Empirical knowledge on the longevity of clonal species has increased considerably in the last few years. Maximum age estimates are an indicator of population persistence, but are not sufficient to evaluate turnover rates and the ability of long-lived clonal plants to enhance community stability and ecosystem resilience. In order to understand the dynamics of populations it will be necessary to measure genet size and age structure, not only life spans of single individuals, and to use such data for modelling of genet dynamics.
背景
物种的生活史和种群动态受个体寿命的强烈影响,但寿命是最难以获取的种群特征之一,尤其是在克隆植物中。由于遗传个体的连续营养繁殖,即使在低或无有性繁殖的情况下,也能维持生存,这会影响遗传个体的更替率和种群稳定性。因此,克隆植物的寿命具有相当大的生物学意义,但仍然相对知之甚少。
范围
在这里,我们批判性地回顾了关于克隆植物寿命的现有知识,并讨论了其对种群持续存在的重要性。直接的寿命测量,如木质植物中的生长环分析,相对容易进行,尽管对于许多克隆植物来说,由于营养体的可变生长模式和遗传个体的难以识别,这些方法并不充分。最近,引入了间接方法,其中利用遗传个体大小和年生长增量来估计遗传个体的年龄。这些方法通常基于分子技术,可以调查整个种群的遗传个体大小和年龄结构,这是理解其生存力和持久性的关键问题。然而,克隆植物衰老过程的了解仍然有限,并且它们的大小和年龄并不总是很好地相关,因此克隆植物的寿命的间接估计受到阻碍。最近还提出了替代遗传个体寿命估计器,如体细胞突变。
结论
近年来,关于克隆物种寿命的经验知识有了相当大的增长。最大年龄估计是种群持续存在的指标,但不足以评估更替率和长寿命克隆植物增强群落稳定性和生态系统恢复力的能力。为了理解种群动态,有必要测量遗传个体的大小和年龄结构,而不仅仅是单个个体的寿命,并使用这些数据对遗传个体动态进行建模。
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