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单一 QTL 携带多个遗传变异导致苹果果肉硬度和脆度复杂的表型分离。

A single QTL harboring multiple genetic variations leads to complicated phenotypic segregation in apple flesh firmness and crispness.

机构信息

College of Horticulture, China Agricultural University, Beijing, 100193, China.

College of Horticultural Science and Technology, Hebei Normal University of Science and Technology, Qinhuangdao, 066600, China.

出版信息

Plant Cell Rep. 2022 Dec;41(12):2379-2391. doi: 10.1007/s00299-022-02929-z. Epub 2022 Oct 8.

DOI:10.1007/s00299-022-02929-z
PMID:36208306
Abstract

Within a QTL, the genetic recombination and interactions among five and two functional variations at MdbHLH25 and MdWDR5A caused much complicated phenotype segregation in apple FFR and FCR. The storability of climacteric fruit like apple is a quantitative trait. We previously identified 62 quantitative trait loci (QTLs) associating flesh firmness retainability (FFR) and flesh crispness retainability (FCR), but only a few functional genetic variations were identified and validated. The genetic variation network controlling fruit storability is far to be understood and diagnostic markers are needed for molecular breeding. We previously identified overlapped QTLs F16.1/H16.2 for FFR and FCR using an F1 population derived from 'Zisai Pearl' × 'Red Fuji'. In this study, five and two single-nucleotide polymorphisms (SNPs) were identified on the candidate genes MdbHLH25 and MdWDR5A within the QTL region. The SNP1 A allele at MdbHLH25 promoter reduced the expression and SNP2 T allele and/or SNP4/5 GT alleles at the exons attenuated the function of MdbHLH25 by downregulating the expression of the target genes MdACS1, which in turn led to a reduction in ethylene production and maintenance of higher flesh crispness. The SNPs did not alter the protein-protein interaction between MdbHLH25 and MdWDR5A. The joint effect of SNP genotype combinations by the SNPs on MdbHLH25 (SNP1, SNP2, and SNP4) and MdWDR5A (SNPi and SNPii) led to a much broad spectrum of phenotypic segregation in FFR and FCR. Together, the dissection of these genetic variations contributes to understanding the complicated effects of a QTL and provides good potential for marker development in molecular breeding.

摘要

在一个 QTL 内,MdbHLH25 和 MdWDR5A 中的五个和两个功能变异的遗传重组和相互作用导致苹果 FFR 和 FCR 中多复杂的表型分离。像苹果这样的跃变型果实的贮藏性是一个数量性状。我们之前鉴定了 62 个与果肉硬度保持力 (FFR) 和果肉脆度保持力 (FCR) 相关的数量性状位点 (QTL),但仅鉴定和验证了少数功能遗传变异。控制果实贮藏性的遗传变异网络远未被理解,需要分子育种的诊断标记。我们之前使用源自 'Zisai Pearl' × 'Red Fuji' 的 F1 群体鉴定了 FFR 和 FCR 的重叠 QTL F16.1/H16.2。在这项研究中,在候选基因 MdbHLH25 和 MdWDR5A 内的 QTL 区域中鉴定了五个和两个单核苷酸多态性 (SNP)。MdbHLH25 启动子上的 SNP1 A 等位基因降低了表达,外显子上的 SNP2 T 等位基因和/或 SNP4/5 GT 等位基因通过下调靶基因 MdACS1 的表达减弱了 MdbHLH25 的功能,进而导致乙烯生成减少和果肉脆度保持较高。SNP 不改变 MdbHLH25 和 MdWDR5A 之间的蛋白质-蛋白质相互作用。MdbHLH25 (SNP1、SNP2 和 SNP4) 和 MdWDR5A (SNPi 和 SNPii) 上 SNP 基因型组合的联合效应导致 FFR 和 FCR 中表型分离的范围更广。这些遗传变异的剖析有助于理解一个 QTL 的复杂影响,并为分子育种中的标记开发提供了很好的潜力。

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