番茄从野生祖先到现代育种材料的基因组变异

Genomic variation in tomato, from wild ancestors to contemporary breeding accessions.

作者信息

Blanca José, Montero-Pau Javier, Sauvage Christopher, Bauchet Guillaume, Illa Eudald, Díez María José, Francis David, Causse Mathilde, van der Knaap Esther, Cañizares Joaquín

机构信息

Institute for the Conservation and Improvement of Agricultural Biodiversity (COMAV), Polytechnic University of Valencia, Camino de Vera 8E, 46022, Valencia, Spain.

INRA, UR 1052 Unité de Génétique et Amélioration des Fruits et Légumes, Domaine Saint-Maurice, 67 Allée des Chênes CS60094, 84143, Montfavet Cedex, France.

出版信息

BMC Genomics. 2015 Apr 1;16(1):257. doi: 10.1186/s12864-015-1444-1.

DOI:10.1186/s12864-015-1444-1

PMID:25880392

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4404671/

Abstract

BACKGROUND

Domestication modifies the genomic variation of species. Quantifying this variation provides insights into the domestication process, facilitates the management of resources used by breeders and germplasm centers, and enables the design of experiments to associate traits with genes. We described and analyzed the genetic diversity of 1,008 tomato accessions including Solanum lycopersicum var. lycopersicum (SLL), S. lycopersicum var. cerasiforme (SLC), and S. pimpinellifolium (SP) that were genotyped using 7,720 SNPs. Additionally, we explored the allelic frequency of six loci affecting fruit weight and shape to infer patterns of selection.

RESULTS

Our results revealed a pattern of variation that strongly supported a two-step domestication process, occasional hybridization in the wild, and differentiation through human selection. These interpretations were consistent with the observed allele frequencies for the six loci affecting fruit weight and shape. Fruit weight was strongly selected in SLC in the Andean region of Ecuador and Northern Peru prior to the domestication of tomato in Mesoamerica. Alleles affecting fruit shape were differentially selected among SLL genetic subgroups. Our results also clarified the biological status of SLC. True SLC was phylogenetically positioned between SP and SLL and its fruit morphology was diverse. SLC and "cherry tomato" are not synonymous terms. The morphologically-based term "cherry tomato" included some SLC, contemporary varieties, as well as many admixtures between SP and SLL. Contemporary SLL showed a moderate increase in nucleotide diversity, when compared with vintage groups.

CONCLUSIONS

This study presents a broad and detailed representation of the genomic variation in tomato. Tomato domestication seems to have followed a two step-process; a first domestication in South America and a second step in Mesoamerica. The distribution of fruit weight and shape alleles supports that domestication of SLC occurred in the Andean region. Our results also clarify the biological status of SLC as true phylogenetic group within tomato. We detect Ecuadorian and Peruvian accessions that may represent a pool of unexplored variation that could be of interest for crop improvement.

摘要

背景

驯化会改变物种的基因组变异。对这种变异进行量化有助于深入了解驯化过程，便于育种者和种质中心对资源进行管理，并能够设计将性状与基因关联起来的实验。我们描述并分析了1008份番茄种质的遗传多样性，这些种质包括普通番茄（Solanum lycopersicum var. lycopersicum，SLL）、醋栗番茄（S. lycopersicum var. cerasiforme，SLC）和潘那利番茄（S. pimpinellifolium，SP），利用7720个单核苷酸多态性（SNP）进行基因分型。此外，我们探究了影响果实重量和形状的6个位点的等位基因频率，以推断选择模式。

结果

我们的结果揭示了一种变异模式，有力地支持了两步驯化过程、野生环境中的偶然杂交以及通过人工选择实现分化。这些解释与影响果实重量和形状的6个位点观察到的等位基因频率一致。在中美洲番茄驯化之前，厄瓜多尔安第斯地区和秘鲁北部的SLC中果实重量受到强烈选择。影响果实形状的等位基因在SLL遗传亚组中被差异选择。我们的结果还阐明了SLC的生物学地位。真正的SLC在系统发育上位于SP和SLL之间，其果实形态多样。SLC和“樱桃番茄”并非同义词。基于形态学的术语“樱桃番茄”包括一些SLC、现代品种，以及许多SP和SLL之间的杂交种。与古老群体相比，现代SLL的核苷酸多样性适度增加。

结论

本研究全面而详细地展示了番茄的基因组变异。番茄驯化似乎经历了两个步骤：第一步在南美洲，第二步在中美洲。果实重量和形状等位基因的分布支持SLC的驯化发生在安第斯地区。我们的结果还阐明了SLC作为番茄中真正系统发育群体的生物学地位。我们检测到厄瓜多尔和秘鲁的种质可能代表了未被探索的变异库，这可能对作物改良具有重要意义。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3057/4404671/ceb8c0cc3aab/12864_2015_1444_Fig1_HTML.jpg

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番茄从野生祖先到现代育种材料的基因组变异

Genomic variation in tomato, from wild ancestors to contemporary breeding accessions.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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