Transcriptome analysis revealed that Arabidopsis model plant invokes the activation of heat shock proteins and ER stress response against cesium stress

Cesium (Cs) toxicity has deleterious effects on plant growth and development. However, the molecular mechanism of the toxic effect of Cs on plants has been poorly understood. To obtain insights into the molecular events occurring in plants under Cs stress, we performed a comparative transcriptomic a...

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Bibliographic Details
Published in:Plant biotechnology reports 2024, 18(3), , pp.385-399
Main Authors: Choi, Dasom, Ko, Dae Kwan, Kim, Dong-Hwan
Format: Article
Language:English
Subjects:
Agriculture
Arabidopsis
biochemical pathways
Biomedical and Life Sciences
Biotechnology
biotic stress
Cell Biology
Cellular stress response
Cesium
family
gene expression regulation
gene ontology
Genes
growth and development
Heat shock proteins
heat shock response
Heat stress
Heat tolerance
Hydrogen peroxide
Life Sciences
Metabolic pathways
Molecular modelling
Mutants
Original Article
Plant Biochemistry
Plant growth
Plant Sciences
Plant stress
Reactive oxygen species
root growth
sequence analysis
Signal transduction
stress tolerance
Toxicity
Transcriptomes
Transcriptomics
농학
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Summary:Cesium (Cs) toxicity has deleterious effects on plant growth and development. However, the molecular mechanism of the toxic effect of Cs on plants has been poorly understood. To obtain insights into the molecular events occurring in plants under Cs stress, we performed a comparative transcriptomic analysis between control and Cs-treated plants via RNA-seq. We identified 183 differentially expressed genes (141 upregulated and 42 downregulated) under Cs stress (1.5 mM CsCl). Gene ontology (GO) analysis using differentially expressed genes in Cs stress indicated that Cs triggered plant stress signaling pathways like reactive oxygen species (i.e., hydrogen peroxide). Further KEGG and MapMan metabolic pathway analyses revealed that many abiotic/biotic stress signaling pathways were highly induced. In particular, heat shock protein family genes were substantially induced upon exposure to Cs stress. We investigated the root growth of several knockout mutants of heat shock protein family genes and found that heat stress response was compromised in these mutants compared to wild type plants. It suggested that heat shock protein genes including HSP17s, HSP23s , HSP101 , and HSFA2 proteins are deployed upon exposure to Cs for plant stress tolerance. Our study provided novel insights into the molecular events occurring in Cs-stressed plants.
ISSN:1863-5466
1863-5474
DOI:10.1007/s11816-024-00895-4