群体分离转录组分析揭示了与甜瓜果实橙色等位基因变异和果实β-胡萝卜素积累相关的代谢和细胞过程。

A bulk segregant transcriptome analysis reveals metabolic and cellular processes associated with Orange allelic variation and fruit β-carotene accumulation in melon fruit.

作者信息

Chayut Noam, Yuan Hui, Ohali Shachar, Meir Ayala, Yeselson Yelena, Portnoy Vitaly, Zheng Yi, Fei Zhangjun, Lewinsohn Efraim, Katzir Nurit, Schaffer Arthur A, Gepstein Shimon, Burger Joseph, Li Li, Tadmor Yaakov

机构信息

Plant Science Institute, Agricultural Research Organization, Newe Ya'ar Research Center, P.O. Box 1021, Ramat Yishay, 30095, Israel.

Faculty of Biology, Technion - Israel Institute of Technology, Haifa, 32000, Israel.

出版信息

BMC Plant Biol. 2015 Nov 9;15:274. doi: 10.1186/s12870-015-0661-8.

DOI:10.1186/s12870-015-0661-8

PMID:26553015

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4640158/

Abstract

BACKGROUND

Melon fruit flesh color is primarily controlled by the "golden" single nucleotide polymorhism of the "Orange" gene, CmOr, which dominantly triggers the accumulation of the pro-vitamin A molecule, β-carotene, in the fruit mesocarp. The mechanism by which CmOr operates is not fully understood. To identify cellular and metabolic processes associated with CmOr allelic variation, we compared the transcriptome of bulks of developing fruit of homozygous orange and green fruited F3 families derived from a cross between orange and green fruited parental lines.

RESULTS

Pooling together F3 families that share same fruit flesh color and thus the same CmOr allelic variation, normalized traits unrelated to CmOr allelic variation. RNA sequencing analysis of these bulks enabled the identification of differentially expressed genes. These genes were clustered into functional groups. The relatively enriched functional groups were those involved in photosynthesis, RNA and protein regulation, and response to stress.

CONCLUSIONS

The differentially expressed genes and the enriched processes identified here by bulk segregant RNA sequencing analysis are likely part of the regulatory network of CmOr. Our study demonstrates the resolution power of bulk segregant RNA sequencing in identifying genes related to commercially important traits and provides a useful tool for better understanding the mode of action of CmOr gene in the mediation of carotenoid accumulation.

摘要

背景

甜瓜果肉颜色主要由“橙色”基因（CmOr）的“金色”单核苷酸多态性控制，该基因在果实中果皮中主要触发维生素A原分子β-胡萝卜素的积累。CmOr发挥作用的机制尚未完全了解。为了鉴定与CmOr等位基因变异相关的细胞和代谢过程，我们比较了橙色和绿色果实亲本系杂交产生的纯合橙色和绿色果实F3家系发育中果实群体的转录组。

结果

将具有相同果肉颜色从而具有相同CmOr等位基因变异的F3家系汇集在一起，使与CmOr等位基因变异无关的性状标准化。对这些群体进行RNA测序分析能够鉴定出差异表达基因。这些基因被聚类到功能组中。相对富集的功能组是那些参与光合作用、RNA和蛋白质调控以及应激反应的功能组。

结论

通过分离群体RNA测序分析鉴定出的差异表达基因和富集过程可能是CmOr调控网络的一部分。我们的研究证明了分离群体RNA测序在鉴定与商业重要性状相关基因方面的分辨率，并为更好地理解CmOr基因在类胡萝卜素积累介导中的作用模式提供了有用的工具。

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群体分离转录组分析揭示了与甜瓜果实橙色等位基因变异和果实β-胡萝卜素积累相关的代谢和细胞过程。

A bulk segregant transcriptome analysis reveals metabolic and cellular processes associated with Orange allelic variation and fruit β-carotene accumulation in melon fruit.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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