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分子系统地理学和物种分布模型证据表明,在生物多样性热点地区, along the oceanic-continental gradient 存在海洋性适应的中华猕猴桃,这是一个避难所。

Molecular phylogeography and species distribution modelling evidence of 'oceanic' adaptation for Actinidia eriantha with a refugium along the oceanic-continental gradient in a biodiversity hotspot.

机构信息

CAS Key Laboratory of Plant Germplasm Enhancement and Specialty Agriculture, Wuhan Botanical Garden, The Chinese Academy of Sciences, Wuhan, 430074, Hubei, China.

Center of Conservation Biology, Core Botanical Gardens, The Chinese Academy of Sciences, Wuhan, 430074, Hubei, China.

出版信息

BMC Plant Biol. 2022 Feb 28;22(1):89. doi: 10.1186/s12870-022-03464-5.

DOI:10.1186/s12870-022-03464-5
PMID:35227218
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8883688/
Abstract

BACKGROUND

Refugia is considered to be critical for maintaining biodiversity; while discerning the type and pattern of refugia is pivotal for our understanding of evolutionary processes in the context of conservation. Interglacial and glacial refugia have been studied throughout subtropical China. However, studies on refugia along the oceanic-continental gradient have largely been ignored. We used a liana Actinidia eriantha, which occurs across the eastern moist evergreen broad-leaved forests of subtropical China, as a case study to test hypotheses of refugia along the oceanic-continental gradient and 'oceanic' adaptation.

RESULTS

The phylogeographic pattern of A. eriantha was explored using a combination of three cpDNA markers and 38 nuclear microsatellite loci, Species distribution modelling and dispersal corridors analysis. Our data showed intermediate levels of genetic diversity [haplotype diversity (h) = 0.498; unbiased expected heterozygosity (UH) = 0.510] both at the species and population level. Microsatellite loci revealed five clusters largely corresponding to geographic regions. Coalescent time of cpDNA lineages was dated to the middle Pliocene (ca. 4.03 Ma). Both geographic distance and climate difference have important roles for intraspecific divergence of the species. The Zhejiang-Fujian Hilly Region was demonstrated to be a refugium along the oceanic-continental gradient of the species and fit the 'refugia in refugia' pattern. Species distribution modelling analysis indicated that Precipitation of Coldest Quarter (importance of 44%), Temperature Seasonality (29%) and Mean Temperature of Wettest Quarter (25%) contributed the most to model development. By checking the isolines in the three climate layers, we found that A. eriantha prefer higher precipitation during the coldest quarter, lower seasonal temperature difference and lower mean temperature during the wettest quarter, which correspond to 'oceanic' adaptation. Actinidia eriantha expanded to its western distribution range along the dispersal corridor repeatedly during the glacial periods.

CONCLUSIONS

Overall, our results provide integrated evidence demonstrating that the Zhejiang-Fujian Hilly Region is a refugium along the oceanic-continental gradient of Actinidia eriantha in subtropical China and that speciation is attributed to 'oceanic' adaptation. This study gives a deeper understanding of the refugia in subtropical China and will contribute to the conservation and utilization of kiwifruit wild resources in the context of climate change.

摘要

背景

避难所被认为对维持生物多样性至关重要;而辨别避难所的类型和模式对于我们理解保护背景下的进化过程至关重要。亚热带中国的间冰期和冰期避难所已经得到了研究。然而,沿海洋-大陆梯度的避难所研究在很大程度上被忽视了。我们使用了一种在亚热带中国东部湿润常绿阔叶林分布的木质藤本猕猴桃属猕猴桃(Actinidia eriantha)作为案例研究,以检验海洋-大陆梯度和“海洋”适应的避难所假说。

结果

我们使用三种叶绿体 DNA 标记和 38 个核微卫星标记,结合物种分布模型和扩散走廊分析,研究了 A. eriantha 的系统地理格局。我们的数据表明,该物种在种和种群水平上均具有中等水平的遗传多样性[单倍型多样性(h)=0.498;无偏期望杂合度(UH)=0.510]。微卫星标记揭示了五个主要与地理区域相对应的聚类。叶绿体 DNA 谱系的合并时间可追溯到中新世中期(约 4.03Ma)。地理距离和气候差异对物种的种内分化都有重要作用。浙江-福建丘陵地区被证明是该物种海洋-大陆梯度上的一个避难所,符合“避难所中的避难所”模式。物种分布模型分析表明,最冷月降水量(重要性为 44%)、温度季节性(29%)和最湿季度平均温度(25%)对模型发展贡献最大。通过检查三个气候层中的等雨量线,我们发现 A. eriantha 在最寒冷的季度更喜欢较高的降水量,较低的季节性温度差异和较低的最湿季度平均温度,这与“海洋”适应相对应。猕猴桃属在冰期期间通过扩散走廊反复向其西部分布范围扩张。

结论

总的来说,我们的结果提供了综合证据,证明浙江-福建丘陵地区是亚热带中国猕猴桃属猕猴桃的海洋-大陆梯度避难所,物种形成归因于“海洋”适应。本研究加深了对亚热带中国避难所的理解,并将有助于在气候变化背景下保护和利用猕猴桃野生资源。

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本文引用的文献

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2
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3
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4
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5
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10
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