Genetic Diversity of New Almond Accessions from Central Asian and Cold-adapted North American Germplasm

IF 1.2 4区农林科学 Q3 HORTICULTURE

Journal of the American Society for Horticultural Science Pub Date : 2023-09-01 DOI:10.21273/jashs05292-23

Per McCord, Vishal Singh, Amita Kaundal, Teryl Roper

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Abstract

We evaluated the genetic diversity of a newly available collection of 94 almond [ Prunus dulcis (Mill.) D.A. Webb] accessions from the former Improving Perennial Plants for Food and Bioenergy (IPPFBE) Foundation. Most of the collection (87 accessions) were collected as seeds from trees growing in the central Asian nations of Kyrgyzstan, Tajikistan, and Uzbekistan, and included several examples of Prunus bucharica (Korsh.) Hand.-Mazz, and related wild species. Of the remaining accessions, six were sourced from a nursery in northern Utah in the United States, and one was a seedling of ‘Nonpareil’, a major commercial cultivar. DNA fingerprints were generated from 10 simple sequence repeat markers. To evaluate the comparative diversity of these new accessions, 66 accessions from the US Department of Agriculture, National Plant Germplasm System (NPGS) almond germplasm collection near Davis, CA, USA, were also included. These NPGS accessions were chosen to represent those collected in similar regions of Central Asia and the Caucasus. The fingerprints were analyzed via hierarchical clustering, principal components analysis (PCA), and discriminant analysis of principal components (DAPC). Hierarchical clustering suggested that half of the Utah-sourced accessions are closely related to each other and to the ‘Nonpareil’ seedling. Additional close relationships were detected (including at least one duplication or mislabeling), and two P. bucharica accessions from the IPPFBE collection were separated from the rest of the collection. A plot of the first two principal components clearly separated wild almond relatives ( P. bucharica and Prunus fenzliana Fritsch) from the remaining accessions. PCA after removal of the wild species separated the ‘Nonpareil’ seedling, the Utah-sourced accessions, and many of the IPPFBE accessions (mostly from Uzbekistan) from nearly all other individuals. The third principal component identified an additional population structure that separated groups of predominantly IPPFBE or NPGS accessions. DAPC showed a considerable admixture of accessions from Azerbaijan, and a little to no admixture of accessions from Georgia and Tajikistan. These results suggest that central Asian/Caucasian almond germplasm is generally distinct from ‘Nonpareil’ and its relatives, and that although there is overlap between the NPGS and IPPFBE collections from this region, the IPPFBE collection does enhance the diversity of available almond germplasm.

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中亚和北美冷适应杏仁新种质的遗传多样性

我们对新获得的94份杏仁[Prunus dulcis (Mill.)]的遗传多样性进行了评估。来自前粮食和生物能源改良多年生植物(IPPFBE)基金会的资料。大部分藏品(87份)是从吉尔吉斯斯坦、塔吉克斯坦和乌兹别克斯坦等中亚国家生长的树木上收集的种子，其中包括一些樱(Korsh)的例子。的手。-蜜蜂及相关野生物种。在剩余的品种中，有6种来自美国犹他州北部的一个苗圃，1种是主要商业品种“Nonpareil”的幼苗。从10个简单序列重复标记生成DNA指纹图谱。为了评价这些新种质的比较多样性，我们还纳入了美国农业部国家植物种质系统(NPGS)在美国加利福尼亚州戴维斯附近收集的66份杏仁种质。这些国家地质调查局的选录代表了在中亚和高加索类似地区收集的资料。采用层次聚类、主成分分析(PCA)和主成分判别分析(DAPC)对指纹图谱进行分析。分层聚类表明，一半的犹他源材料彼此密切相关，并与“非平行”幼苗密切相关。检测到更多的密切关系(包括至少一个重复或错误标记)，并且从IPPFBE收集的两个P. bucharica条目与其他收集分离。前两个主成分的样地明显地将野生杏仁近缘种(P. bucharica和Prunus fenzliana Fritsch)与其他材料区分开来。移除野生物种后，PCA将“Nonpareil”幼苗、犹他州来源的材料和许多IPPFBE材料(主要来自乌兹别克斯坦)从几乎所有其他个体中分离出来。第三个主要成分确定了一个额外的种群结构，该结构将主要为IPPFBE或NPGS的种群分开。DAPC显示来自阿塞拜疆的相当大的混合，格鲁吉亚和塔吉克斯坦的加入很少或没有混合。这些结果表明，中亚/高加索杏仁种质资源总体上与“Nonpareil”及其亲缘品种不同，尽管该地区的NPGS和IPPFBE种质资源存在重叠，但IPPFBE种质资源确实增强了可利用杏仁种质资源的多样性。

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来源期刊

Journal of the American Society for Horticultural Science 农林科学-园艺

CiteScore

3.80

自引率

0.00%

发文量

审稿时长

2 months

期刊介绍： The Journal of the American Society for Horticultural Science publishes papers on the results of original research on horticultural plants and their products or directly related research areas. Its prime function is to communicate mission-oriented, fundamental research to other researchers. The journal includes detailed reports of original research results on various aspects of horticultural science and directly related subjects such as: - Biotechnology - Developmental Physiology - Environmental Stress Physiology - Genetics and Breeding - Photosynthesis, Sources-Sink Physiology - Postharvest Biology - Seed Physiology - Postharvest Biology - Seed Physiology - Soil-Plant-Water Relationships - Statistics