J. L. Reyes-Ortiz, P. Octavio-Aguilar, L. López-Mata, A. Sánchez‐González
{"title":"Diversity and Genetic Structure of Dicksonia navarrensis (Dicksoniaceae) Populations in the Mexican Sierra Madre Oriental","authors":"J. L. Reyes-Ortiz, P. Octavio-Aguilar, L. López-Mata, A. Sánchez‐González","doi":"10.1177/19400829221128539","DOIUrl":null,"url":null,"abstract":"Background and Research Aims Dicksonia navarrensis is a species of tree fern at risk of extinction, distributed in the montane cloud forest (MCF) of the Americas from the central region of Mexico to Ecuador. In Mexico, populations of this species grow in primary vegetation of the MCF, in a matrix with a high degree of fragmentation and under threat of disappearance. Methods In the present study, the diversity and genetic structure of seven populations of D. navarrensis that are distributed in the cloud forest of the Sierra Madre Oriental were evaluated, with both standard laboratory and statistical analysis techniques, using 11 microsatellites developed for the genus Dicksonia. Results A total of 33 alleles were found. Genetic diversity differed between populations, and some presented low heterozygosity. Using assignment tests, three genetic groups were identified, associated with the geographical distribution of the populations; those from the north maintain connectivity with each other but diverge highly from the populations in the south, probably due to processes of isolation by distance (local environment), genetic drift, and natural selection. Conclusion The northernmost population, which is more isolated from the rest, has a broader genetic reservoir, which can be useful for maintaining the genetic diversity of the species. In the other populations, with less genetic diversity, the introduction of individuals and/or the dispersion of spores is important, to maintain and increase the genetic variability that they still possess, but which could disappear in a short time if their habitat continues to deteriorate at a high degree. Implications for Conservation The results obtained provide basic information that can be used in management and conservation plans, because the populations with the greatest genetic diversity and the possible processes that are influencing the genetic structure of the species were identified.","PeriodicalId":49118,"journal":{"name":"Tropical Conservation Science","volume":" ","pages":""},"PeriodicalIF":1.7000,"publicationDate":"2022-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Tropical Conservation Science","FirstCategoryId":"93","ListUrlMain":"https://doi.org/10.1177/19400829221128539","RegionNum":4,"RegionCategory":"环境科学与生态学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"BIODIVERSITY CONSERVATION","Score":null,"Total":0}
引用次数: 0
Abstract
Background and Research Aims Dicksonia navarrensis is a species of tree fern at risk of extinction, distributed in the montane cloud forest (MCF) of the Americas from the central region of Mexico to Ecuador. In Mexico, populations of this species grow in primary vegetation of the MCF, in a matrix with a high degree of fragmentation and under threat of disappearance. Methods In the present study, the diversity and genetic structure of seven populations of D. navarrensis that are distributed in the cloud forest of the Sierra Madre Oriental were evaluated, with both standard laboratory and statistical analysis techniques, using 11 microsatellites developed for the genus Dicksonia. Results A total of 33 alleles were found. Genetic diversity differed between populations, and some presented low heterozygosity. Using assignment tests, three genetic groups were identified, associated with the geographical distribution of the populations; those from the north maintain connectivity with each other but diverge highly from the populations in the south, probably due to processes of isolation by distance (local environment), genetic drift, and natural selection. Conclusion The northernmost population, which is more isolated from the rest, has a broader genetic reservoir, which can be useful for maintaining the genetic diversity of the species. In the other populations, with less genetic diversity, the introduction of individuals and/or the dispersion of spores is important, to maintain and increase the genetic variability that they still possess, but which could disappear in a short time if their habitat continues to deteriorate at a high degree. Implications for Conservation The results obtained provide basic information that can be used in management and conservation plans, because the populations with the greatest genetic diversity and the possible processes that are influencing the genetic structure of the species were identified.
背景与研究目的纳氏Dicksonia navarrensis是一种濒临灭绝的树蕨,分布于从墨西哥中部到厄瓜多尔的美洲山地云雾林中。在墨西哥,该物种的种群生长在MCF的原始植被中,生长在高度破碎的基质中,并面临消失的威胁。方法采用标准实验室和统计分析技术,利用为Dicksonia属开发的11颗微卫星,对分布在Sierra Madre Oriental云林中的7个纳瓦尔D.navarensis种群的多样性和遗传结构进行了评价。结果共发现33个等位基因。不同群体的遗传多样性不同,有些表现为低杂合性。通过分配测试,确定了与种群地理分布相关的三个遗传群;来自北方的种群保持着相互联系,但与南方的种群差异很大,这可能是由于距离隔离(当地环境)、基因漂移和自然选择的过程。结论最北端种群与其他种群更为隔离,具有更广泛的遗传库,这有助于维持物种的遗传多样性。在遗传多样性较低的其他种群中,引入个体和/或孢子传播对于保持和增加它们仍然拥有的遗传变异性很重要,但如果它们的栖息地继续高度恶化,这种变异性可能会在短时间内消失。对保护的影响所获得的结果提供了可用于管理和保护计划的基本信息,因为已经确定了具有最大遗传多样性的种群以及影响物种遗传结构的可能过程。
期刊介绍:
Tropical Conservation Science is a peer-reviewed, open access journal that publishes original research papers and state-of-the-art reviews of broad interest to the field of conservation of tropical forests and of other tropical ecosystems.