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BACKGROUND

Wine grapes are important economically in many countries around the world. Defining the optimum time for grape harvest is a major challenge to the grower and winemaker. Berry skins are an important source of flavor, color and other quality traits in the ripening stage. Senescent-like processes such as chloroplast disorganization and cell death characterize the late ripening stage.

RESULTS

To better understand the molecular and physiological processes involved in the late stages of berry ripening, RNA-seq analysis of the skins of seven wine grape cultivars (Cabernet Franc, Cabernet Sauvignon, Merlot, Pinot Noir, Chardonnay, Sauvignon Blanc and Semillon) was performed. RNA-seq analysis identified approximately 2000 common differentially expressed genes for all seven cultivars across four different berry sugar levels (20 to 26 °Brix). Network analyses, both a posteriori (standard) and a priori (gene co-expression network analysis), were used to elucidate transcriptional subnetworks and hub genes associated with traits in the berry skins of the late stages of berry ripening. These independent approaches revealed genes involved in photosynthesis, catabolism, and nucleotide metabolism. The transcript abundance of most photosynthetic genes declined with increasing sugar levels in the berries. The transcript abundance of other processes increased such as nucleic acid metabolism, chromosome organization and lipid catabolism. Weighted gene co-expression network analysis (WGCNA) identified 64 gene modules that were organized into 12 subnetworks of three modules or more and six higher order gene subnetworks. Some gene subnetworks were highly correlated with sugar levels and some subnetworks were highly enriched in the chloroplast and nucleus. The petal R package was utilized independently to construct a true small-world and scale-free complex gene co-expression network model. A subnetwork of 216 genes with the highest connectivity was elucidated, consistent with the module results from WGCNA. Hub genes in these subnetworks were identified including numerous members of the core circadian clock, RNA splicing, proteolysis and chromosome organization. An integrated model was constructed linking light sensing with alternative splicing, chromosome remodeling and the circadian clock.

CONCLUSIONS

A common set of differentially expressed genes and gene subnetworks from seven different cultivars were examined in the skin of the late stages of grapevine berry ripening. A densely connected gene subnetwork was elucidated involving a complex interaction of berry senescent processes (autophagy), catabolism, the circadian clock, RNA splicing, proteolysis and epigenetic regulation. Hypotheses were induced from these data sets involving sugar accumulation, light, autophagy, epigenetic regulation, and fruit development. This work provides a better understanding of berry development and the transcriptional processes involved in the late stages of ripening.

BACKGROUND

RESULTS

CONCLUSIONS

背景

酿酒葡萄在世界许多国家具有重要的经济价值。确定葡萄的最佳采收时间是种植者和酿酒师面临的一项重大挑战。浆果表皮是成熟阶段风味、颜色和其他品质特征的重要来源。衰老样过程，如叶绿体解体和细胞死亡，是成熟后期的特征。

结果

为了更好地了解浆果成熟后期所涉及的分子和生理过程，对七个酿酒葡萄品种（品丽珠、赤霞珠、梅洛、黑皮诺、霞多丽、长相思和赛美蓉）的表皮进行了RNA测序分析。RNA测序分析在四个不同的浆果糖分水平（20至26°Brix）下，为所有七个品种鉴定出约2000个共同的差异表达基因。采用事后（标准）和事前（基因共表达网络分析）网络分析方法，以阐明与浆果成熟后期表皮性状相关的转录子网络和枢纽基因。这些独立的方法揭示了参与光合作用、分解代谢和核苷酸代谢的基因。随着浆果中糖分水平的增加，大多数光合基因的转录丰度下降。其他过程的转录丰度增加，如核酸代谢、染色体组织和脂质分解代谢。加权基因共表达网络分析（WGCNA）确定了64个基因模块，这些模块被组织成12个由三个或更多模块组成的子网络和六个高阶基因子网络。一些基因子网络与糖分水平高度相关，一些子网络在叶绿体和细胞核中高度富集。独立使用花瓣R包构建了一个真正的小世界和无标度复杂基因共表达网络模型。阐明了一个具有最高连通性的216个基因的子网络，与WGCNA的模块结果一致。确定了这些子网络中的枢纽基因，包括核心生物钟、RNA剪接、蛋白水解和染色体组织的众多成员。构建了一个将光感知与可变剪接、染色体重塑和生物钟联系起来的综合模型。

结论

研究了葡萄浆果成熟后期七个不同品种表皮中一组共同的差异表达基因和基因子网络。阐明了一个紧密连接的基因子网络，涉及浆果衰老过程（自噬）、分解代谢、生物钟、RNA剪接、蛋白水解和表观遗传调控的复杂相互作用。从这些数据集中得出了关于糖分积累、光照、自噬、表观遗传调控和果实发育的假设。这项工作有助于更好地理解浆果发育以及成熟后期所涉及的转录过程。