Horticulture Section, School of Integrative Plant Science, Cornell University, Cornell Agritech, Geneva, New York, USA.
Boyce Thompson Institute, Ithaca, New York, USA.
Plant J. 2022 Sep;111(6):1609-1625. doi: 10.1111/tpj.15911. Epub 2022 Aug 11.
Somatic mutations may alter important traits in tree fruits, such as fruit color, size and maturation date. Autumn Gala (AGala), a somatic mutation from apple cultivar Gala, matures 4 weeks later than Gala. To understand the mechanisms underlying the delayed maturation, RNA-seq analyses were conducted with fruit sampled at 13 (Gala) and 16 (AGala) time-points during their growth and development. Weighted gene co-expression network analysis (WGCNA) of 23 372 differentially expressed genes resulted in 25 WGCNA modules. Of these, modules 1 (r = -0.98, P = 2E-21) and 2 (r = -0.52, P = 0.004), which were suppressed in AGala, were correlated with fruit maturation date. Surprisingly, 77 of the 152 member genes in module 1 were harbored in a 2.8-Mb genomic region on chromosome 6 that was deleted and replaced by a 10.7-kb gypsy-like retrotransposon (Gy-36) from chromosome 7 in AGala. Among the 77 member genes, MdACT7 was the most suppressed (by 10.5-fold) in AGala due to a disruptive 2.5-kb insertion in coding sequence. Moreover, MdACT7 is the exclusive apple counterpart of Arabidopsis ACT7 known of essential roles in plant development, and the functional allele MdACT7, which was lost to the deletion in AGala, was associated with early fruit maturation in 268 apple accessions. Overexpressing alleles MdACT7 and Mdact7 in an Arabidopsis act7 line showed that MdACT7 largely rescued its stunted growth and delayed initial flowering while Mdact7 did not. Therefore, the 2.8-Mb hemizygous deletion is largely genetically causal for fruit maturation delay in AGala, and the total loss of MdACT7 might have contributed to the phenotype.
体细胞突变可能会改变果树的重要特征,例如果实颜色、大小和成熟日期。红元帅(Gala)的体细胞突变体 Autumn Gala(AGala)比 Gala 晚成熟 4 周。为了了解成熟延迟的机制,对其生长发育过程中 13 个(Gala)和 16 个(AGala)时间点采集的果实进行了 RNA-seq 分析。对 23372 个差异表达基因进行加权基因共表达网络分析(WGCNA),得到 25 个 WGCNA 模块。其中,在 AGala 中受抑制的模块 1(r=-0.98,P=2E-21)和模块 2(r=-0.52,P=0.004)与果实成熟日期相关。令人惊讶的是,模块 1 中 152 个成员基因中有 77 个位于 AGala 中 6 号染色体上的 2.8-Mb 基因组区域,该区域缺失并被 7 号染色体上的 10.7-kb gypsy-like 反转录转座子(Gy-36)取代。在这 77 个成员基因中,MdACT7 受抑制程度最高(下调 10.5 倍),这是由于编码序列中发生了 2.5-kb 的破坏插入。此外,MdACT7 是拟南芥 ACT7 的苹果特有同源物,后者在植物发育中起重要作用,而在 AGala 中因缺失而丢失的功能等位基因 MdACT7 与 268 个苹果品种的早期果实成熟有关。在拟南芥 act7 系中过表达等位基因 MdACT7 和 Mdact7 表明,MdACT7 很大程度上挽救了其生长迟缓和初始开花延迟,而 Mdact7 则没有。因此,2.8-Mb 半合子缺失在很大程度上是 AGala 果实成熟延迟的遗传原因,而 MdACT7 的完全缺失可能导致了该表型。
