利用改良的 NAC 和 MYB 共表达网络分析藤本植物木质素生物合成途径。

Analyzing lignin biosynthesis pathways in rattan using improved co-expression networks of NACs and MYBs.

机构信息

Institute of Gene Science and Industrialization for Bamboo and Rattan Resources, International Centre for Bamboo and Rattan, Beijing, 100102, China.

State Key Laboratory of Respiratory Disease, Guangzhou Institutes of Biomedicine and Health, Chinese Academy of Sciences, Huangpu District, Guangzhou, 510530, China.

出版信息

BMC Plant Biol. 2022 Aug 24;22(1):411. doi: 10.1186/s12870-022-03786-4.

DOI:10.1186/s12870-022-03786-4

PMID:36002818

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9400238/

Abstract

BACKGROUND

The rattan is a valuable plant resource with multiple applications in tropical forests. Calamus simplicifolius and Daemonorops jenkinsiana are the two most representative rattan species, supplying over 95% of the raw materials for the rattan industry. Hence, the wood properties of both rattans have always attracted researchers' attention.

RESULTS

We re-annotated the genomes, obtained 81 RNA-Seq datasets, and developed an improved pipeline to increase the reliability of co-expression networks of both rattans. Based on the data and pipeline, co-expression relationships were detected in 11 NACs, 49 MYBs, and 86 lignin biosynthesis genes in C. simplicifolius and four NACs, 59 MYBs, and 76 lignin biosynthesis genes in D. jenkinsiana, respectively. Among these co-expression pairs, several genes had a close relationship to the development of wood properties. Additionally, we detected the enzyme gene on the lignin biosynthesis pathway was regulated by either NAC or MYB, while LACCASES was regulated by both NAC and MYB. For D. jenkinsiana, the lignin biosynthesis regulatory network was characterized by positive regulation, and MYB possible negatively regulate non-expressed lignin biosynthesis genes in stem tissues. For C. simplicifolius, NAC may positively regulate highly expressed genes and negatively regulate non-expressed lignin biosynthesis genes in stem tissues. Furthermore, we established core regulatory networks of NAC and MYB for both rattans.

CONCLUSIONS

This work improved the accuracy of rattan gene annotation by integrating an efficient co-expression network analysis pipeline, enhancing gene coverage and accuracy of the constructed network, and facilitating an understanding of co-expression relationships among NAC, MYB, and lignin biosynthesis genes in rattan and other plants.

摘要

背景

藤本植物是热带森林中具有多种应用价值的宝贵植物资源。省藤和白藤是两种最具代表性的藤本植物，为藤本工业提供了超过 95%的原材料。因此，这两种藤本植物的木材特性一直吸引着研究人员的注意。

结果

我们重新注释了基因组，获得了 81 个 RNA-Seq 数据集，并开发了一个改进的管道来提高两种藤本植物的共表达网络的可靠性。基于这些数据和管道，在 C. simplicifolius 中检测到 11 个 NAC、49 个 MYB 和 86 个木质素生物合成基因以及在 D. jenkinsiana 中检测到 4 个 NAC、59 个 MYB 和 76 个木质素生物合成基因之间存在共表达关系。在这些共表达对中，有几个基因与木材特性的发育密切相关。此外，我们检测到木质素生物合成途径上的酶基因受 NAC 或 MYB 调节，而 LACCASES 受 NAC 和 MYB 共同调节。对于 D. jenkinsiana，木质素生物合成调控网络的特点是正调控，MYB 可能负调控茎组织中未表达的木质素生物合成基因。对于 C. simplicifolius，NAC 可能正调控高表达基因，负调控茎组织中未表达的木质素生物合成基因。此外，我们为两种藤本植物建立了 NAC 和 MYB 的核心调控网络。

结论

本研究通过整合高效的共表达网络分析管道，提高了藤本植物基因注释的准确性，增强了构建网络的基因覆盖度和准确性，有助于理解藤本植物和其他植物中 NAC、MYB 和木质素生物合成基因之间的共表达关系。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3b4d/9400238/b53af624bd2e/12870_2022_3786_Fig1_HTML.jpg

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利用改良的 NAC 和 MYB 共表达网络分析藤本植物木质素生物合成途径。

Analyzing lignin biosynthesis pathways in rattan using improved co-expression networks of NACs and MYBs.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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