Transcriptome analysis reveals genes associated with the bitter-sweet trait of apricot kernels.

Forestry research Pub Date : 2024-02-29 eCollection Date: 2024-01-01 DOI:10.48130/forres-0024-0004
Yu Zhang, Wenquan Bao, Ta-Na Wuyun, Mengzhen Huang, Chen Chen, Dun Ao, Rong Yang, Haiguang Huang, Lin Wang
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Abstract

Prunasin and amygdalin are important factors that influence the kernel taste of apricots, however, the regulatory mechanisms underlying this are unclear. In this study, we analyzed the phenotype and transcriptome of kernels during development in Prunus sibirica (bitter kernels) and Prunus armeniaca × Prunus sibirica (kernel consumption apricot, sweet kernels). Prunasin and amygdalin content was significantly higher in bitter kernels compared with that in sweet kernels. Prunasin content exhibited a decreasing trend in both bitter and sweet kernels. The fastest decline was observed in bitter and sweet kernels during S3-S4 (82.21%) and S2-S3 (59.65%), respectively. The amygdalin content in the bitter kernels exhibited the fastest increase between 45-60 d after flowering, and reached a peak at 6.22% on 60 d after flowering. In contrast, the peak in sweet kernels occurred at 60 d after flowering, with a much lower content of 0.18%. Transcriptome analysis revealed 6,942 differentially expressed genes (DEGs), with a subset of 38 DEGs specifically enriched in the cyanoamino acid metabolic pathway. Among these, the ten candidate genes, including CYP79, CYP71, UGT1, AH, and PH, were identified as crucial in regulating prunasin and amygdalin metabolism. Furthermore, a weighted gene co-expression network analysis (WGCNA) unveiled two modules that exhibited significant correlation with prunasin and amygdalin content. Five DEGs were located at the center of the co-expression network, and were identified as hub genes, with four positively regulating prunasin content and one negatively regulating amygdalin content. Our results provide novel insights into the molecular-level regulation of the apricot kernel taste.

转录组分析揭示了与杏核苦甜性状相关的基因。
樱桃苷和杏仁苷是影响杏核口味的重要因子,然而其背后的调控机制尚不清楚。在这项研究中,我们分析了西伯利亚杏(苦核)和杏×西伯利亚杏(食用杏、甜核)核仁发育过程中的表型和转录组。与甜核相比,苦核中的樱桃苷和杏仁苷含量明显较高。苦杏仁和甜杏仁中的樱桃苷含量均呈下降趋势。在 S3-S4 期(82.21%)和 S2-S3 期(59.65%),苦核和甜核中的苦杏仁苷含量下降最快。苦核中的杏仁苷含量在花后 45-60 d 之间增长最快,在花后 60 d 达到峰值 6.22%。相比之下,甜核中的峰值出现在花后 60 d,含量低得多,仅为 0.18%。转录组分析发现了 6942 个差异表达基因(DEGs),其中 38 个 DEGs 子集特别富集在氰基氨基酸代谢途径中。其中,包括 CYP79、CYP71、UGT1、AH 和 PH 在内的 10 个候选基因被确定为调控梅花苷和杏仁苷代谢的关键基因。此外,加权基因共表达网络分析(WGCNA)揭示了两个与杨梅素和苦杏仁苷含量显著相关的模块。有五个 DEGs 位于共表达网络的中心,并被确定为枢纽基因,其中四个正向调控杨梅素含量,一个负向调控杏仁苷含量。我们的研究结果为杏核味道的分子水平调控提供了新的见解。
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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