Biological mechanisms of cadmium accumulation in edible Amaranth (Amaranthus mangostanus L.) cultivars promoted by salinity: A transcriptome analysis
Autor: | Zhi-Min Xu, Han-Jie Ye, Eddy Y. Zeng, Junfeng Wang, Ling-Yan Jiang, Li-Li Wang, Shi-Hong Guo, Qu-Sheng Li, Bao-Yan He, Chu Zhou |
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Rok vydání: | 2019 |
Předmět: |
Salinity
010504 meteorology & atmospheric sciences Health Toxicology and Mutagenesis ATPase chemistry.chemical_element Amaranth 010501 environmental sciences Toxicology 01 natural sciences Plant Roots Transcriptome chemistry.chemical_compound Soil Botany Soil Pollutants 0105 earth and related environmental sciences chemistry.chemical_classification Cadmium Amaranthus biology Gene Expression Profiling General Medicine Pollution Fold change Enzyme chemistry biology.protein Organic acid |
Zdroj: | Environmental pollution (Barking, Essex : 1987). 262 |
ISSN: | 1873-6424 |
Popis: | Strategies to prevent cadmium (Cd) mobilization by crops under salinity conditions differs among distinct genotypes, but the biological mechanisms of Cd accumulation in different genotype crops promoted by salinity have remained scarce. In this study, we investigated the biological mechanisms of Cd accumulation in two quite different amaranth cultivars of low-Cd accumulator Quanhong (QH) and high-Cd accumulator Liuye (LY) in response to salt stress. Transcriptomes analysis was carried out on leaves and roots tissues of LY and QH grown with exchangeable Cd 0.27 mg kg−1 and salinity 3.0 g kg−1 treatment or control conditions, respectively. A total of 3224 differentially expressed genes (DEGs) in LY (1119 in roots, 2105 in leaves) and 848 in QH (207 in roots, 641 in leaves) were identified. Almost in each fold change category (2-25, 25-210, >210), the numbers of DEGs induced by salinity in LY treatments were much more than those in QH treatments, indicating that LY is more salt sensitive. Gene ontology (GO) analysis revealed that salinity stress promoted soil acidification and Cd mobilization in LY treatments through the enhancive expression of genes related to adenine metabolism (84-fold enrichment) and proton pumping ATPase (50-fold enrichment) in roots, and carbohydrate hydrolysis (2.5-fold enrichment) in leaves compared with that of whole genome, respectively. The genes expression of organic acid transporter (ALMT) was promoted by 2.71- to 3.94-fold in roots, facilitating the secretion of organic acids. Salt stress also inhibited the expression of key enzymes related to cell wall biosynthesis in roots, reducing the physical barriers for Cd uptake. All these processes altered in LY were more substantially compared with that of QH, suggesting that salt sensitive cultivars might accumulate more Cd and pose a higher health risk. |
Databáze: | OpenAIRE |
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