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人工种植与野生草莓树的三条形码系统发育比较及土壤微生物群落研究

Comparative Three-Barcode Phylogenetics and Soil Microbiomes of Planted and Wild Strawberry Trees.

作者信息

McLamb Flannery, Vazquez Armando, Olander Natalie, Vasquez Miguel F, Feng Zuying, Malhotra Niharika, Bozinovic Liisa, Najera Ruiz Karen, O'Connell Katherine, Stagg Joseph, Bozinovic Goran

机构信息

Boz Life Science Research and Teaching Institute La Jolla California USA.

Division of Extended Studies University of California San Diego La Jolla California USA.

出版信息

Plant Direct. 2025 May 8;9(5):e70078. doi: 10.1002/pld3.70078. eCollection 2025 May.

DOI:10.1002/pld3.70078
PMID:40343328
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12059276/
Abstract

Taxonomic identification of closely related plants can be challenging due to convergent evolution, hybridization, and overlapping geographic distribution. To derive taxonomic relationships among planted and wild plants across a large geographic range, we complemented three standard plastid barcodes , , and with soil and fruit chemistry, soil microbiome, and plant morphology analyses. Soil and plant sampling included planted from manicured sites in Southern California, USA, wild plants from Southern and Northern California, and wild populations from Mediterranean island of Hvar, Croatia. We hypothesized that phenotypic variation within and between sites correlates with plants' genotype and geographic distribution. Similar fruit chemistry corresponds to geographical proximity and morphological resemblance, while bulk soil bacterial content defines three distinct clusters distinguishing planted versus wild trees and continent of origin. The soil microbiome of wild California was characterized by an abundance of , while the presence of was high in wild Hvar samples and most planted samples, but low in all wild California samples. Although all three barcodes resolved four main groups, the position of samples varies across barcodes. The phylogram is relatively unbalanced, suggesting slower diversification among wild California populations and exhibiting greater resolution than other barcodes among planted individuals. While our data demonstrate an overall agreement among standard plant barcodes relative to geo-distribution and plant morphology, sustained efforts on cost-effective global plant DNA barcode library standardization for closely related and geographically overlapping plants is recommended.

摘要

由于趋同进化、杂交和地理分布重叠,对亲缘关系密切的植物进行分类鉴定可能具有挑战性。为了推导大范围地理区域内种植植物和野生植物之间的分类关系,我们用土壤和果实化学分析、土壤微生物组分析以及植物形态分析对三个标准质体条形码(matK、rbcL和trnH-psbA)进行了补充。土壤和植物样本采集包括来自美国南加州人工修剪场地的种植的[植物名称未明确]、来自南加州和北加州的野生植物,以及来自克罗地亚赫瓦尔岛的地中海野生种群。我们假设不同地点内部和之间的表型变异与植物的基因型和地理分布相关。相似的果实化学特征对应着地理上的接近和形态上的相似,而土壤中细菌的总量则定义了三个不同的聚类,区分了种植树木和野生树木以及起源大陆。加利福尼亚野生[植物名称未明确]的土壤微生物组以大量的[微生物名称未明确]为特征,而[微生物名称未明确]在赫瓦尔岛野生样本和大多数种植样本中含量较高,但在所有加利福尼亚野生样本中含量较低。虽然所有三个条形码都解析出了四个主要类群,但样本的位置在不同条形码之间有所不同。matK系统发育树相对不均衡,这表明加利福尼亚野生种群之间的多样化速度较慢,并且在种植个体中比其他条形码具有更高的分辨率。虽然我们的数据表明标准植物条形码在地理分布和植物形态方面总体上是一致的,但建议继续努力,为亲缘关系密切且地理分布重叠的植物建立具有成本效益的全球植物DNA条形码库标准。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c103/12059276/153ac9216f00/PLD3-9-e70078-g007.jpg
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