Genetic differentiation and diversity do not explain variation in heterosis or inbreeding depression: empirical evidence from a long-lived iteroparous plant

IF 2 3区 环境科学与生态学 Q2 BIODIVERSITY CONSERVATION Conservation Genetics Pub Date : 2024-09-17 DOI:10.1007/s10592-024-01641-7
Linus Söderquist, Sophie Karrenberg, Nina Sletvold
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Abstract

Assisted gene flow can restore genetic diversity when genetic drift has driven deleterious alleles to high frequencies in small, isolated populations. Previous crosses among 20 populations of Gymnadenia conopsea documented the strongest heterosis and the weakest inbreeding depression in sparse and small populations, consistent with fixation of mildly deleterious alleles by genetic drift. We genotyped the populations used for crosses, and used 1200–1728 SNPs to test the following predictions: (1) heterosis increases with genetic differentiation (FST) to donor populations and decreases with genetic diversity in the recipient population, (2) inbreeding depression increases with genetic diversity, and (3) genetic diversity increases, and mean FST to other populations decreases, with population size and density. Pairwise FST ranged from very low to moderate (0.005–0.20) and genetic diversity varied moderately among populations (proportion of polymorphic loci = 0.52–0.75). However, neither FST between populations, nor genetic diversity in the recipient population, were related to the strength of heterosis. There was also no association between genetic diversity and the strength of inbreeding depression. Genetic diversity increased and mean FST decreased with population size, consistent with reduced diversity and increased differentiation of small populations by genetic drift. The results indicate that the loci conferring heterosis are not mirrored by overall population differentiation, and limited additional information on potential source populations for genetic rescue is gained by the genetic data. Instead, the use of controlled crosses can directly reveal positive effects of introducing new genetic material, and is a simple method with high potential in conservation.

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遗传分化和多样性不能解释异质性或近交抑郁的变化:一种长寿迭代植物的经验证据
当遗传漂变导致有害等位基因在孤立的小种群中出现高频率时,辅助基因流可以恢复遗传多样性。之前在 20 个裸冠花(Gymnadenia conopsea)种群间进行的杂交结果表明,在稀疏的小种群中,异质性最强,近交抑郁最弱,这与遗传漂变导致的轻度有害等位基因的固定是一致的。我们对用于杂交的种群进行了基因分型,并利用 1200-1728 个 SNPs 检验了以下预测:(1)异质性随对供体种群的遗传分化(FST)而增加,随受体种群的遗传多样性而减少;(2)近交抑郁随遗传多样性而增加;(3)遗传多样性随种群大小和密度而增加,对其他种群的平均 FST 则随之减少。配对 FST 从很低到中等(0.005-0.20)不等,种群间的遗传多样性变化中等(多态位点比例 = 0.52-0.75)。然而,种群间的 FST 和受体种群的遗传多样性都与异质性的强弱无关。遗传多样性与近交抑郁的强度也没有关系。遗传多样性随着种群规模的扩大而增加,平均 FST 则随着种群规模的扩大而降低,这与遗传漂变导致的多样性降低和小种群分化加剧是一致的。结果表明,赋予异质性的基因位点并不反映总体种群的分化,遗传数据只能获得遗传拯救潜在来源种群的有限额外信息。相反,利用受控杂交可以直接揭示引入新遗传物质的积极影响,是一种在保护方面极具潜力的简单方法。
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来源期刊
Conservation Genetics
Conservation Genetics 环境科学-生物多样性保护
CiteScore
3.80
自引率
4.50%
发文量
58
审稿时长
1 months
期刊介绍: Conservation Genetics promotes the conservation of biodiversity by providing a forum for data and ideas, aiding the further development of this area of study. Contributions include work from the disciplines of population genetics, molecular ecology, molecular biology, evolutionary biology, systematics, forensics, and others. The focus is on genetic and evolutionary applications to problems of conservation, reflecting the diversity of concerns relevant to conservation biology. Studies are based on up-to-date technologies, including genomic methodologies. The journal publishes original research papers, short communications, review papers and perspectives.
期刊最新文献
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