Genomes & islands & evolution: Oh my!

The International Compositae Alliance Pub Date : 2023-09-01 DOI:10.53875/capitulum.03.1.04

M. R. Bellinger

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Abstract

A central question in evolutionary biology is how lineages quickly diversify to occupy different ecological niches, along with determining genomic factors that facilitate evolutionary change. Isolated, oceanic archipelagos are famous for adaptive radiations characterized by endemic, species-rich clades with substantial ecological variation, yet genome resources key to determining eco-evo processes are generally lacking. Here I present a comparison of the number of genome reference assemblies available (as of May 31, 2023) for three major eukaryotic lineages, briefly describe genome sequencing and benchmarking strategies, and highlight as a case study a genome assembly project for Bidens hawaiensis (Koʻokoʻolau, Asteraceae or Compositae; Coreopsidae), a member of a hexaploid Hawaiian plant adaptive radiation. The total number of plant genome references (1,394) was found to substantially lag the total number of genome references for animal (6,003) and fungi (4,400). Improvements to the quality of de novo assembled genomes are fueled by second-and third-generation long-read sequencing advancements, among other sequencing approaches. In conjunction, strategies to improve genome contiguity include optical maps, Hi-C chromatin capture, or trio binning. Continual improvements to genome sequencing and assembly algorithms have brought within reach telomere-to-telomere genome assemblies, albeit this level of sequencing has to date only been achieved in a few cases. With improvements in sequencing techniques and per-base pair costs that continue to trend downward, the number of high-quality genomes is anticipated to continue to increase, leading to the filling in of taxonomic gaps and sampling of groups of taxa from under sampled geographic areas. Increasing the number of plant genome resources available for the study of island endemism could help to shed light on genome-phenome relationships and genome characteristics that have produced the stunning biological diversity that we now observe across the globe.

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基因组、岛屿和进化:天哪!

进化生物学的一个核心问题是谱系如何迅速多样化以占据不同的生态位，以及决定促进进化变化的基因组因素。孤立的海洋群岛以其特有的适应性辐射而闻名，物种丰富的进化枝具有大量的生态变异，但通常缺乏决定生态进化过程的关键基因组资源。本文比较了三个主要真核生物谱系的基因组参考组合数量(截至2023年5月31日)，简要描述了基因组测序和基准策略，并重点介绍了夏威夷Bidens (Ko wai oko wai olau, Asteraceae或Compositae;夏威夷六倍体植物适应性辐射的一个成员。研究发现，植物基因组参考总数(1,394)大大落后于动物基因组参考总数(6,003)和真菌基因组参考总数(4,400)。在其他测序方法中，第二代和第三代长读测序技术的进步推动了从头组装基因组质量的提高。同时，提高基因组邻近性的策略包括光学图谱，Hi-C染色质捕获或三人分组。基因组测序和组装算法的不断改进使端粒到端粒基因组组装成为可能，尽管这种水平的测序迄今仅在少数情况下实现。随着测序技术的进步和每碱基对成本的持续下降，高质量基因组的数量预计将继续增加，从而填补分类空白，并从采样不足的地理区域取样类群。增加可用于岛屿地方性研究的植物基因组资源的数量可能有助于阐明基因组-表型关系和基因组特征，这些关系和特征产生了我们现在在全球范围内观察到的惊人的生物多样性。

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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The International Compositae Alliance

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