AI Article Synopsis
- MicroRNA (miRNA)-target gene modules are key players in how plants like wheat respond to drought stress, but there's limited knowledge about them specifically in wheat.
- Using systems biology, researchers identified a specific miRNA-target module that changes in expression when comparing drought-stressed to non-stressed conditions in different wheat genotypes.
- The study found that this module is linked to various physiological traits important for drought tolerance, such as hormone levels, water balance, and antioxidant activities, suggesting its crucial role in helping wheat withstand drought.
Article Abstract
MicroRNA (miRNA)-target gene modules are essential components of plants' abiotic stress signalling pathways Little is known about the drought-responsive miRNA-target modules in wheat, but systems biology approaches have enabled the prediction of these regulatory modules and systematic study of their roles in responses to abiotic stresses. Using such an approach, we sought miRNA-target module(s) that may be differentially expressed under drought and non-stressed conditions by mining Expressed Sequence Tag (EST) libraries of wheat roots and identified a strong candidate (). We then assessed molecular and physiochemical differences between two wheat genotypes with contrasting drought tolerance in a controlled drought experiment and assessed possible relationships between their tolerance and evaluated traits. We found that the module significantly responds to drought stress in wheat roots. It is differentially expressed between the contrasting wheat genotypes and under drought versus non-stressed conditions. We also found significant associations between the module's expression profiles and ABA hormone content, water relations, photosynthetic activities, HO levels, plasma membrane damage, and antioxidant enzyme activities in wheat. Collectively, our results suggest that a regulatory module consisting of and may play an important role in wheat's drought tolerance.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10266357 | PMC |
| http://dx.doi.org/10.3389/fpls.2023.1161245 | DOI Listing |
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