Abstract
Microarray expression profile analysis is a useful approach to increase our knowledge about genes involved in regulatory networks and signal transduction pathways related to abiotic stress tolerance. Salt and drought, as two important abiotic stresses, adversely affect plant productivity in the world every year. To understand stress response mechanisms and identify genes and proteins which play critical roles in these mechanisms, the study of individual genes and proteins cannot be considered as an effective approach. On the other hand, the availability of new global data provides us an effective way to shed some light on the central role of molecules involved in stress response mechanisms in the plant. A meta-analysis of salt and drought stress responses was carried out using 38 samples of different experiments from leaves and roots of Arabidopsis plants exposed to drought and salt stresses. We figured out the number of differentially expressed genes (DEGs) was higher in roots under both stresses. Also, we found that the number of common DEGs under both stresses was more in roots and also the number of common DEGs in both tissues under salt stress was more than drought stress. The highest percent of DEGs was related to cell and cell part (about 87%). Around 9% and 7% of DEGs in roots and leaves encoded transcription factors, respectively. Network analysis revealed that three transcription factor families HSF, AP2/ERF and C2H2, may have critical roles in salt and drought stress response mechanisms in Arabidopsis and some proteins like STZ may be introduced as a new candidate gene for enhancing salt and drought tolerance in crop plants.
Highlights
Plants unlike animals are not able to move and escape from undesirable condition and stresses
We identified a set of 4540 up-regulated differentially expressed genes (DEGs) in the leaf tissue which 1643 (36%) and 2897 (64%) of them up-regulated in response to drought and salt stress, respectively, whereas in the root tissue 6906 DEGs were up-regulated that 3150 (46%) and 3756 (54%) of them upregulated in response to drought and salt stress, respectively
The diagram represented a list of 584 (13%) DEGs was up-regulated under salt and drought stresses in leaf tissue, but 1186 (17%) DEGs were common between drought and salt stresses in roots (Fig. 1)
Summary
Plants unlike animals are not able to move and escape from undesirable condition and stresses. Abiotic stresses such as drought, salt, extreme temperature, heavy metals and nutrient deficiency have undesirable effects on plants [1]. These stresses cause decrease in growth and productivity of plants. Among these stresses, drought and salt are two major environmental factors which have detrimental effects on growth, yield and crop production. It is necessary to improve water use efficiency and salt tolerance of crops through plant breeding projects using new tools like biotechnology [2]
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