玉米和拟南芥之间保守的共功能网络有助于鉴定玉米中种子缺陷基因。

Conserved co-functional network between maize and Arabidopsis aid in the identification of seed defective genes in maize.

机构信息

Guangdong Sugarcane Genetic Improvement Engineering Center, Institute of Bioengineering, Guangdong Academy of Sciences, Guangzhou, 510316, China.

Sciences Rice and Sorghum Institude, Sichuan Academy of Agricultural, Deyang, 618000, China.

出版信息

Genes Genomics. 2021 May;43(5):433-446. doi: 10.1007/s13258-021-01067-2. Epub 2021 Mar 2.

DOI:10.1007/s13258-021-01067-2

PMID:33651300

Abstract

BACKGROUND

The biological pathways related to Arabidopsis seed development have been well studied and functional genes involved in it have been discovered. However, functional studies about maize seed development were more limited compared to Arabidopsis.

OBJECTIVE

Therefore, transferring knowledge from Arabidopsis into maize would facilitate functional studies about maize seed development.

METHOD

In this study, public transcriptome data of the two species related to seed development were obtained. Co-expression network in each species was compared by integrating orthology information.

RESULTS

This conserved co-functional network contained 4510 maize and 4808 Arabidopsis genes, respectively. Most of these genes were expressed in throughout embryo, early or later endosperm/seed. These conserved co-functional genes were significantly enriched for members of PPR protein family, which was consistent with that PPR proteins play an important role in maize seed development. Spatial-temporally co-functional genes were discovered in the seed coat and embryo. Furthermore, 66 well-studied genes involved in Arabidopsis seed development were co-functional with 319 maize genes and one maize gene (GRMZM2G036050) was further confirmed using an EMS-induced seed defective mutant by bulked segregating RNA sequencing (BSR) analysis.

CONCLUSIONS

Altogether, these results showed the potential of this approach to support functional studies in maize seed development by transferring knowledge from Arabidopsis.

摘要

背景

拟南芥种子发育相关的生物学途径已经得到了很好的研究，并且已经发现了涉及其中的功能基因。然而，与拟南芥相比，玉米种子发育的功能研究更为有限。

目的

因此，将知识从拟南芥转移到玉米中将有助于玉米种子发育的功能研究。

方法

在这项研究中，获得了与种子发育相关的两个物种的公共转录组数据。通过整合同源信息，比较了每个物种中的共表达网络。

结果

这个保守的共功能网络包含了 4510 个玉米和 4808 个拟南芥基因，分别。这些基因大多在整个胚胎、早期或晚期胚乳/种子中表达。这些保守的共功能基因显著富集了 PPR 蛋白家族的成员，这与 PPR 蛋白在玉米种子发育中发挥重要作用是一致的。在种皮和胚胎中发现了时空共功能基因。此外，通过 bulked segregating RNA sequencing (BSR) 分析，对 66 个参与拟南芥种子发育的研究充分的基因与 319 个玉米基因和一个玉米基因（GRMZM2G036050）进行了共功能验证。

结论

总之，这些结果表明，通过从拟南芥转移知识，这种方法有可能支持玉米种子发育的功能研究。

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玉米和拟南芥之间保守的共功能网络有助于鉴定玉米中种子缺陷基因。

Conserved co-functional network between maize and Arabidopsis aid in the identification of seed defective genes in maize.

机构信息

出版信息

BACKGROUND

OBJECTIVE

METHOD

RESULTS

CONCLUSIONS

背景

目的

方法

结果

结论

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