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乌克兰克里米亚一年生苜蓿(苜蓿属物种)种质资源的遗传多样性、群体结构及分类学确认

Genetic diversity, population structure, and taxonomic confirmation in annual medic ( spp.) collections from Crimea, Ukraine.

作者信息

Zhao Dongyan, Sapkota Manoj, Lin Meng, Beil Craig, Sheehan Moira, Greene Stephanie, Irish Brian M

机构信息

Breeding Insight, Cornell University, Ithaca, NY, United States.

Agricultural Genetic Resources Preservation Research Unit, United States Department of Agriculture (USDA), Agricultural Research Service (ARS), Prosser, WA, United States.

出版信息

Front Plant Sci. 2024 Apr 3;15:1339298. doi: 10.3389/fpls.2024.1339298. eCollection 2024.

DOI:10.3389/fpls.2024.1339298
PMID:38633467
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11021755/
Abstract

Annual medic ( spp.) germplasm was collected from the Crimean Peninsula of Ukraine in 2008 to fill gaps in geographic coverage in the United States department of Agriculture, Agricultural Research Service, National Plant Germplasm System (NPGS) temperate-adapted forage legume collection. A total of 102 accessions across 10 species were collected. To assess genetic diversity, population structure, and to confirm taxonomic identities, the collections were phenotypically and genetically characterized. Phenotyping included the use of 24 descriptor traits while genetic characterization was accomplished using a 3K Diversity Array Technologies (DArTag) panel developed for alfalfa ( L.). For both field and molecular characterizations, a reference set of 92 geographically diverse and species-representative accessions were obtained from the NPGS collection. Phenotypic descriptors showed consistency among replicated plants within accessions, some variation across accessions within species, and evident distinctions between species. Because the DArTag panel was developed for cultivated alfalfa, the transferability of markers to the species being evaluated was limited, resulting in an average of ~1,500 marker loci detected per species. From these loci, 448 markers were present in 95% of the samples. Principal component and phylogenetic analysis based on a larger set of 2,396 selected markers clustered accessions by species and predicted evolutionary relationships among species. Additionally, the markers aided in the taxonomic identity of a few accessions that were likely mislabeled. The genotyping results also showed that sampling individual plants for these mostly self-pollinating species is sufficient due to high reproducibility between single (n=3) and pooled (n=7) biological replicate leaf samples. The phenotyping and the 2,396 Single Nucleotide Polymorphism (SNP) marker set were useful in estimating population structure in the Crimean and reference accessions, highlighting novel and unique genetic diversity captured in the Crimean accessions. This research not only demonstrated the utility of the DArTag marker panel in evaluating the Crimean germplasm but also highlighted its broader application in assessing genetic resources within the genus. Furthermore, we anticipate that our findings will underscore the importance of leveraging genetic resources and advanced genotyping tools for sustainable crop improvement and biodiversity conservation in annual medic species.

摘要

2008年从乌克兰克里米亚半岛收集了一年生苜蓿(苜蓿属物种)种质资源,以填补美国农业部农业研究局国家植物种质系统(NPGS)中温带适应型豆科牧草收集在地理覆盖范围上的空白。总共收集了10个物种的102份种质资源。为了评估遗传多样性、种群结构并确认分类学身份,对这些收集物进行了表型和遗传特征分析。表型分析包括使用24个描述性状,而遗传特征分析则使用为紫花苜蓿(Medicago sativa L.)开发的3K多样性阵列技术(DArTag)面板完成。对于田间和分子特征分析,从NPGS收集物中获得了一组92份地理上不同且具有物种代表性的种质资源作为参考集。表型描述符显示种质资源内重复植株之间具有一致性,物种内不同种质资源之间存在一些变异,并且物种之间有明显区别。由于DArTag面板是为栽培紫花苜蓿开发的,标记对所评估物种的可转移性有限,导致每个物种平均检测到约1500个标记位点。在这些位点中,448个标记存在于95%的样本中。基于一组更大的2396个选定标记进行的主成分分析和系统发育分析,按物种对种质资源进行了聚类,并预测了物种之间的进化关系。此外,这些标记有助于确定一些可能被错误标记的种质资源的分类学身份。基因分型结果还表明,由于单个(n = 3)和混合(n = 7)生物重复叶片样本之间具有高度可重复性,对于这些主要自花授粉的物种,对单株进行采样就足够了。表型分析和2396个单核苷酸多态性(SNP)标记集有助于估计克里米亚种质资源和参考种质资源的种群结构,突出了克里米亚种质资源中捕获的新的和独特的遗传多样性。这项研究不仅证明了DArTag标记面板在评估克里米亚种质资源方面的实用性,还突出了其在评估苜蓿属内遗传资源方面的更广泛应用。此外,我们预计我们的研究结果将强调利用遗传资源和先进的基因分型工具对一年生苜蓿物种进行可持续作物改良和生物多样性保护的重要性。

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