Sands Chester J, Convey Peter, Linse Katrin, McInnes Sandra J
British Antarctic Survey, Natural Environment Research Council, High Cross, Madingley Road, Cambridge, CB3 0ET, UK.
BMC Ecol. 2008 Apr 30;8:7. doi: 10.1186/1472-6785-8-7.
Meiofauna - multicellular animals captured between sieve size 45 mum and 1000 mum - are a fundamental component of terrestrial, and marine benthic ecosystems, forming an integral element of food webs, and playing a critical roll in nutrient recycling. Most phyla have meiofaunal representatives and studies of these taxa impact on a wide variety of sub-disciplines as well as having social and economic implications. However, studies of variation in meiofauna are presented with several important challenges. Isolating individuals from a sample substrate is a time consuming process, and identification requires increasingly scarce taxonomic expertise. Finding suitable morphological characters in many of these organisms is often difficult even for experts. Molecular markers are extremely useful for identifying variation in morphologically conserved organisms. However, for many species markers need to be developed de novo, while DNA can often only be extracted from pooled samples in order to obtain sufficient quantity and quality. Importantly, multiple independent markers are required to reconcile gene evolution with species evolution. In this primarily methodological paper we provide a proof of principle of a novel and effective protocol for the isolation of meiofauna from an environmental sample. We also go on to illustrate examples of the implications arising from subsequent screening for genetic variation at the level of the individual using ribosomal, mitochondrial and single copy nuclear markers.
To isolate individual tardigrades from their habitat substrate we used a non-toxic density gradient media that did not interfere with downstream biochemical processes. Using a simple DNA release technique and nested polymerase chain reaction with universal primers we were able amplify multi-copy and, to some extent, single copy genes from individual tardigrades. Maximum likelihood trees from ribosomal 18S, mitochondrial cytochrome oxidase subunit 1, and the single copy nuclear gene Wingless support a recent study indicating that the family Hypsibiidae is a non-monophyletic group. From these sequences we were able to detect variation between individuals at each locus that allowed us to identify the presence of cryptic taxa that would otherwise have been overlooked.
Molecular results obtained from individuals, rather than pooled samples, are a prerequisite to enable levels of variation to be placed into context. In this study we have provided a proof of principle of this approach for meiofaunal tardigrades, an important group of soil biota previously not considered amenable to such studies, thereby paving the way for more comprehensive phylogenetic studies using multiple nuclear markers, and population genetic studies.
小型底栖动物——捕获于45微米至1000微米筛孔之间的多细胞动物——是陆地和海洋底栖生态系统的基本组成部分,构成食物网的一个不可或缺的元素,并在养分循环中发挥关键作用。大多数动物门类都有小型底栖动物代表,对这些分类群的研究影响着广泛的子学科领域,同时也具有社会和经济意义。然而,小型底栖动物变异研究面临若干重大挑战。从样本基质中分离个体是一个耗时的过程,而且鉴定需要日益稀缺的分类学专业知识。即使对于专家而言,在许多这类生物中找到合适的形态学特征往往也很困难。分子标记对于识别形态学上保守的生物的变异极为有用。然而,对于许多物种而言,标记需要从头开发,而且DNA通常只能从混合样本中提取,以便获得足够的数量和质量。重要的是,需要多个独立标记来使基因进化与物种进化相协调。在这篇主要关于方法学的论文中,我们提供了一种从环境样本中分离小型底栖动物的新颖且有效方案的原理证明。我们还继续举例说明,使用核糖体、线粒体和单拷贝核标记在个体水平上对遗传变异进行后续筛选所产生的影响。
为了从其栖息基质中分离单个缓步动物,我们使用了一种无毒密度梯度介质,该介质不会干扰下游生化过程。通过一种简单的DNA释放技术以及使用通用引物的巢式聚合酶链反应,我们能够从单个缓步动物中扩增多拷贝基因,并在一定程度上扩增单拷贝基因。核糖体18S、线粒体细胞色素氧化酶亚基1以及单拷贝核基因无翅基因的最大似然树支持了最近一项研究,该研究表明高生熊虫科是一个非单系类群。从这些序列中,我们能够检测每个位点个体之间的变异,这使我们能够识别出原本会被忽视的隐存分类群的存在。
从个体而非混合样本获得的分子结果是能够将变异水平置于背景中的先决条件。在本研究中,我们为小型底栖动物缓步动物提供了这种方法的原理证明,缓步动物是土壤生物区系中的一个重要类群,此前被认为不适合此类研究,从而为使用多个核标记进行更全面的系统发育研究以及种群遗传学研究铺平了道路。
