A fully phased, chromosome-scale genome of sugar beet line FC309 enables the discovery of Fusarium yellows resistance QTL.

IF 3.9 2区生物学 Q1 GENETICS & HEREDITY

DNA Research Pub Date : 2024-11-26 DOI:10.1093/dnares/dsae032

Olivia E Todd, Sheron Simpson, Brian Scheffler, Kevin M Dorn

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引用次数: 0

Abstract

Sugar beet (Beta vulgaris L.) is a global source for table sugar and animal fodder. Here we report a highly contiguous, haplotype phased genome assembly and annotation for sugar beet line FC309. Both assembled haplomes for FC309 represent the largest and most contiguous assembled beet genomes reported to date, as well as gene annotations sets that capture over 1500 additional protein-coding loci compared to prior beet genome annotations. These new genomic resources were used to identify novel quantitative trait loci (QTL) for Fusarium yellows resistance from the FC309 genetic background using an F2 mapping-by-sequencing approach. The highest QTL signals were detected on Chromosome 3, spanning approximately 10Mbp in both haplomes. A parallel transcriptome profiling experiment identified candidate genes within the Chromosome 3 QTL with plausible roles in disease response, including NBS-LRR genes with expression trends supporting a role in resistance. Investigation of genetic variants in these candidate genes found one major disease resistance protein containing high effect variants of interest. Collectively, the genomic resources for FC309 presented here be foundational tool for comparative genomics, mapping other traits in the FC309 background, and as a reference genome for other beet studies due to its contiguity, completeness, and high-quality gene annotations.

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甜菜品系 FC309 的全分期染色体级基因组有助于发现抗黄萎病镰刀菌的 QTL。

甜菜（Beta vulgaris L.）是全球食糖和动物饲料的来源。在此，我们报告了甜菜品系 FC309 的高度连续、单体型分期的基因组组装和注释。为 FC309 组装的两个单倍组代表了迄今为止报道的最大和最连续的组装甜菜基因组，以及基因注释集，与之前的甜菜基因组注释相比，该基因组捕获了超过 1500 个额外的蛋白质编码位点。利用这些新的基因组资源，采用 F2 测序作图方法从 FC309 遗传背景中鉴定出了新的抗镰刀菌黄萎病的数量性状位点（QTL）。在 3 号染色体上检测到了最高的 QTL 信号，在两个单体中的跨度约为 10Mbp。一项平行的转录组分析实验确定了 3 号染色体 QTL 上的候选基因，这些基因在疾病反应中具有可信的作用，包括 NBS-LRR 基因，其表达趋势支持其在抗性中的作用。对这些候选基因中的遗传变异进行调查后发现，一个主要的抗病蛋白含有相关的高效应变异。总之，本文介绍的 FC309 基因组资源将成为比较基因组学、绘制 FC309 背景下其他性状图谱的基础工具，并因其连续性、完整性和高质量的基因注释而成为其他甜菜研究的参考基因组。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

DNA Research 生物-遗传学

CiteScore

6.00

自引率

4.90%

发文量

审稿时长

4.5 months

期刊介绍： DNA Research is an internationally peer-reviewed journal which aims at publishing papers of highest quality in broad aspects of DNA and genome-related research. Emphasis will be made on the following subjects: 1) Sequencing and characterization of genomes/important genomic regions, 2) Comprehensive analysis of the functions of genes, gene families and genomes, 3) Techniques and equipments useful for structural and functional analysis of genes, gene families and genomes, 4) Computer algorithms and/or their applications relevant to structural and functional analysis of genes and genomes. The journal also welcomes novel findings in other scientific disciplines related to genomes.