转录组分析为陆地棉（G. hirsutum L.）腋芽的稳态调控提供了新见解。

Transcriptome analyses provide insights into the homeostatic regulation of axillary buds in upland cotton (G. hirsutum L.).

机构信息

State Key Laboratory of Cotton Biology, Institute of Cotton Research of Chinese Academy of Agricultural Sciences, NO. 38, Huanghe Road, Anyang City, 455000, Henan Province, China.

出版信息

BMC Plant Biol. 2020 May 24;20(1):228. doi: 10.1186/s12870-020-02436-x.

DOI:10.1186/s12870-020-02436-x

PMID:32448205

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7245931/

Abstract

BACKGROUND

The axillary bud is an important index of cotton plant-type traits, and the molecular mechanism of axillary bud development in upland cotton has not yet been reported. We obtained a mutant (designated mZ571) with a high-budding phenotype in axillary bud development from the low-budding phenotype variety G. hirsutum Z571 (CCRI 9A02), which provided ideal materials for the study of complex regulatory networks of axillary bud development. In this study, RNA sequencing was carried out to detect gene expression levels during three stages of axillary buds in Z571 (LB, low budding) and mZ571 mutant (HB, high budding).

RESULTS

A total of 7162 DEGs were identified in the three groups (HB-E vs. LB-E, HB-G1 vs. LB-G1, HB-G2 vs. LB-G2), including 4014 downregulated and 3184 upregulated DEGs. Additionally, 221 DEGs were commonly identified in all three groups, accounting for approximately 3.09% of the total DEGs. These DEGs were identified, annotated and classified. A significant number of DEGs were related to hormone metabolism, hormone signal transduction, and starch and sucrose metabolism. In addition, 45, 22 and 9 DEGs involved in hormone metabolic pathways and 67, 22 and 19 DEGs involved in hormone signal transduction pathwayspathway were identified in HB-E vs. LB-E, HB-G1 vs. LB-G1, and HB-G2 vs. LB-G2, respectively, suggesting that endogenous hormones are the primary factors influencing cotton axillary bud growth. Hormone and soluble sugar content measurements revealed that mZ571 exhibited higher concentrations of zeatin, gibberellins and soluble sugar in all three stages, which confirmed that these hormone metabolism-, hormone signal transduction- and starch metabolism-related genes showed interaction effects contributing to the divergence of axillary bud growth between mZ571 and Z571.

CONCLUSIONS

Our results confirmed the importance of endogenous hormones and sugars in the development of axillary buds, and we found that mZ571 plants, with a high-budding phenotype of axillary buds, exhibited higher endogenous hormone and sugar concentrations. Overall, we present a model for the emergence and development of cotton axillary buds that provides insights into the complexity and dynamic nature of the regulatory network during axillary bud emergence and development.

摘要

背景

腋芽是棉花株型性状的一个重要指标，但其在陆地棉中的发育分子机制尚未见报道。我们从低芽型品种 G. hirsutum Z571（CCRI 9A02）中获得了一个腋芽高芽型突变体（命名为 mZ571），为研究腋芽发育的复杂调控网络提供了理想的材料。本研究采用 RNA 测序技术，检测了 Z571（LB，低芽）和 mZ571 突变体（HB，高芽）三个腋芽发育阶段的基因表达水平。

结果

在三个组（HB-E vs. LB-E、HB-G1 vs. LB-G1、HB-G2 vs. LB-G2）中共鉴定到 7162 个差异表达基因（DEGs），包括 4014 个下调和 3184 个上调 DEGs。此外，在所有三个组中共同鉴定到 221 个 DEGs，约占总 DEGs 的 3.09%。对这些 DEGs 进行了注释和分类，发现大量 DEGs 与激素代谢、激素信号转导以及淀粉和蔗糖代谢有关。另外，在 HB-E vs. LB-E、HB-G1 vs. LB-G1、HB-G2 vs. LB-G2 中分别鉴定到 45、22 和 9 个参与激素代谢途径的 DEGs 和 67、22 和 19 个参与激素信号转导途径的 DEGs，表明内源激素是影响棉花腋芽生长的主要因素。激素和可溶性糖含量测定表明，mZ571 在三个阶段的玉米素、赤霉素和可溶性糖浓度均较高，进一步证实这些与激素代谢、激素信号转导和淀粉代谢相关的基因存在互作效应，导致 mZ571 和 Z571 之间的腋芽生长出现差异。

结论

本研究证实了内源激素和糖在腋芽发育中的重要性，发现具有高芽型腋芽表型的 mZ571 植株具有较高的内源激素和糖浓度。总之，我们提出了一个棉花腋芽发生和发育的模型，为理解腋芽发生和发育过程中调控网络的复杂性和动态性提供了新的见解。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a443/7245931/90659e16ca45/12870_2020_2436_Fig1_HTML.jpg

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转录组分析为陆地棉（G. hirsutum L.）腋芽的稳态调控提供了新见解。

Transcriptome analyses provide insights into the homeostatic regulation of axillary buds in upland cotton (G. hirsutum L.).

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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