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Transcriptome Differences in Response Mechanisms to Low-Nitrogen Stress in Two Wheat Varieties

Huishu Yan, Huawei Shi, Chengmei Hu, Mingzhao Luo, Chengjie Xu, Shuguang Wang, Ning Li, Wensi Tang, Yongbin Zhou, Chunxiao Wang, Zhao‐Shi Xu, Jun Chen, You‐Zhi Ma, Daizhen Sun, Ming Chen

2021International Journal of Molecular Sciences26 citationsDOIOpen Access PDF

Abstract

Nitrogen plays a crucial role in wheat growth and development. Here, we analyzed the tolerance of wheat strains XM26 and LM23 to low-nitrogen stress using a chlorate sensitivity experiment. Subsequently, we performed transcriptome analyses of both varieties exposed to low-nitrogen (LN) and normal (CK) treatments. Compared with those under CK treatment, 3534 differentially expressed genes (DEGs) were detected in XM26 in roots and shoots under LN treatment (p < 0.05, and |log2FC| > 1). A total of 3584 DEGs were detected in LM23. A total of 3306 DEGs, including 863 DEGs in roots and 2443 DEGs in shoots, were specifically expressed in XM26 or showed huge differences between XM26 and LM23 (log2FC ratio > 3). These were selected for gene ontology and Kyoto Encyclopedia of Genes and Genomes enrichment analyses. The calcium-mediated plant–pathogen interaction, MAPK signaling, and phosphatidylinositol signaling pathways were enriched in XM26 but not in LM23. We also verified the expression of important genes involved in these pathways in the two varieties using qRT-PCR. A total of 156 transcription factors were identified among the DEGs, and their expression patterns were different between the two varieties. Our findings suggest that calcium-related pathways play different roles in the two varieties, eliciting different tolerances to low-nitrogen stress.

Topics & Concepts

TranscriptomeKEGGBiologyGeneShootGene expressionGenomeTranscription factorTranscription (linguistics)GeneticsBotanyLinguisticsPhilosophyPlant nutrient uptake and metabolismRice Cultivation and Yield ImprovementPlant Micronutrient Interactions and Effects