Identification of Alkaline Salt Tolerance Genes in L. by Transcriptome Analysis

Overview

Journal Genes (Basel)

Publisher MDPI

Date 2022 Aug 26

PMID 36011404

Authors

Yu Xu

Shunxian Tao

Yunlin Zhu

Qi Zhang

Ping Li

Han Wang

Yan Zhang

Aldiyar Bakirov

Hanming Cao

Mengfan Qin

Kai Wang

Yiji Shi

Xiang Liu

Lin Zheng

Aixia Xu

Zhen Huang

Affiliations

Soon will be listed here.

Abstract

Soil salt alkalization is one major abiotic factor reducing the productivity of crops, including rapeseed, an indispensable oil crop and vegetable. The mechanism studies of alkali salt tolerance can help breed highly resistant varieties. In the current study, rapeseed () line 2205 exhibited more tolerance to alkaline salt than line 1423 did. In line 2205, the lesser plasma membrane damage index, the accumulated osmotic solute, and higher antioxidant enzyme activities contributed to alkaline tolerance. A more integrated mesophyll-cell structure was revealed under alkali salt stress by ultrastructure observation in line 2205, which also implied a lesser injury. Transcriptome analysis showed that more genes responded to alkaline salt in line 2205. The expression of specific-response genes in line 1423 was lower than in line 2205. However, most of the specific-response genes in line 2205 had higher expression, which was mainly enriched in carbohydrate metabolism, photosynthetic processes, ROS regulating, and response to salt stress. It can be seen that the tolerance to alkaline salt is attributed to the high expression of some genes in these pathways. Based on these, twelve cross-differentially expressed genes were proposed as candidates. They provide clues for further analysis of the resistance mechanism of rapeseed.

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