Phylogenomics-driven host test list selection for weed biological control

IF 3.7 2区 农林科学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Stephanie H. Chen , Ben Gooden , Michelle A. Rafter , Gavin C. Hunter , Alicia Grealy , Nunzio Knerr , Alexander N. Schmidt-Lebuhn
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引用次数: 0

Abstract

A concern in weed biological control research is the potential for candidate biocontrol agents to impact not only the target weed but also native or economically important flora. The degree of evolutionary relatedness between the target weed species and a non-target species is a key predictor of the susceptibility of the non-target to the biocontrol agent. To manage this risk, biocontrol practitioners need to understand the phylogenetic position of the host weed relative to non-target plant species. However, comprehensively sampled phylogenetic trees are often unavailable, with incomplete information scattered across multiple publications. Further, older published phylogenies based on Sanger sequence data often lack branch resolution and support, which increases uncertainty in biocontrol decision making. Decreasing sequencing cost and technological advances have led to phylogenomic approaches being more widely used to understand evolutionary relationships between species. For example, target capture sequencing methods using bait kits such as Angiosperms353 enable cost-effective and timely phylogenomic-level analysis of flowering plant groups at different scales. Here, we introduce a workflow to embed a comprehensive understanding of evolutionary relationships into the efficient development of host test lists in weed biological control. We demonstrate the effectiveness of the workflow through a case study on the major crop weed flaxleaf fleabane (Erigeron bonariensis). Phylogenomic analysis was conducted on 280 species of the tribe Astereae (family Asteraceae) occurring in Australia and New Zealand, clarifying relationships between the target species and related clades of native and non-native Astereae. We consider the phylogenetic tree in the context of a previously proposed host test list and discuss taxonomic implications, highlighting avenues of future molecular-based work to uncover the origin of Australian fleabanes. This study provides a workflow and demonstrates the practical application of target sequence capture for phylogenomic inference to support risk analysis and decision making in classical weed biological control.

系统发生组学驱动的杂草生物防治寄主试验列表选择
杂草生物防治研究中的一个问题是,候选生物控制剂不仅可能影响目标杂草,还可能影响本地或具有重要经济价值的植物区系。目标杂草物种与非目标物种之间的进化亲缘关系程度是预测非目标物种对生物控制剂敏感性的关键因素。为了控制这种风险,生物防治工作者需要了解寄主杂草相对于非目标植物物种的系统发育位置。然而,全面取样的系统发生树往往无法获得,不完整的信息散见于多种出版物中。此外,基于 Sanger 序列数据发表的较早的系统发生树往往缺乏分支分辨率和支持,这增加了生物防治决策的不确定性。测序成本的降低和技术的进步使得系统发生组学方法被更广泛地用于了解物种之间的进化关系。例如,利用诱饵试剂盒(如 Angiosperms353)进行目标捕获测序的方法,可在不同尺度上对开花植物类群进行成本效益高且及时的系统发生组分析。在这里,我们介绍了一种工作流程,将对进化关系的全面了解嵌入到杂草生物防治宿主试验列表的高效开发中。我们通过对主要农作物杂草亚麻叶飞蓬(Erigeron bonariensis)的案例研究,证明了该工作流程的有效性。我们对发生在澳大利亚和新西兰的菊科(Asteraceae)280 个物种进行了系统发生组分析,明确了目标物种与本地和非本地菊科相关支系之间的关系。我们结合之前提出的宿主测试列表考虑了系统发生树,并讨论了分类学的影响,同时强调了未来基于分子研究揭示澳大利亚飞蓬起源的途径。本研究提供了一个工作流程,并展示了目标序列捕获在系统发生组推断中的实际应用,以支持传统杂草生物防治中的风险分析和决策制定。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Biological Control
Biological Control 生物-昆虫学
CiteScore
7.40
自引率
7.10%
发文量
220
审稿时长
63 days
期刊介绍: Biological control is an environmentally sound and effective means of reducing or mitigating pests and pest effects through the use of natural enemies. The aim of Biological Control is to promote this science and technology through publication of original research articles and reviews of research and theory. The journal devotes a section to reports on biotechnologies dealing with the elucidation and use of genes or gene products for the enhancement of biological control agents. The journal encompasses biological control of viral, microbial, nematode, insect, mite, weed, and vertebrate pests in agriculture, aquatic, forest, natural resource, stored product, and urban environments. Biological control of arthropod pests of human and domestic animals is also included. Ecological, molecular, and biotechnological approaches to the understanding of biological control are welcome.
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