Dehydration Responsive Element Binding Transcription Research Articles

Transcriptomic and Proteomic Analysis of Drought Stress Response in Opium Poppy Plants during the First Week of Germination.

Water deficiency is one of the most significant abiotic stresses that negatively affects growth and reduces crop yields worldwide. Most research is focused on model plants and/or crops which are most agriculturally important. In this research, drought stress was applied to two drought stress contrasting varieties of Papaver somniferum (the opium poppy), a non-model plant species, during the first week of its germination, which differ in responses to drought stress. After sowing, the poppy seedlings were immediately subjected to drought stress for 7 days. We conducted a large-scale transcriptomic and proteomic analysis for drought stress response. At first, we found that the transcriptomic and proteomic profiles significantly differ. However, the most significant findings are the identification of key genes and proteins with significantly different expressions relating to drought stress, e.g., the heat-shock protein family, dehydration responsive element-binding transcription factors, ubiquitin E3 ligase, and others. In addition, metabolic pathway analysis showed that these genes and proteins were part of several biosynthetic pathways most significantly related to photosynthetic processes, and oxidative stress responses. A future study will focus on a detailed analysis of key genes and the development of selection markers for the determination of drought-resistant varieties and the breeding of new resistant lineages.

Orchestration of plant development and defense by indirect crosstalk of salicylic acid and brassinosteorid signaling via transcription factor GhTINY2.

Salicylic acid (SA) and brassinosteroids (BRs) are well known to regulate diverse processes of plant development and stress responses, but the mechanisms by which these phytohormones mediate the growth and defense trade-off are largely unclear. In addition, little is known about the roles of DEHYDRATION RESPONSIVE ELEMENT BINDING transcription factors, especially in biotic stress and plant growth. Here, we identified a cotton (Gossypium hirsutum) APETALA2/ETHYLENE RESPONSIVE FACTOR gene GhTINY2 that is strongly induced by Verticillium dahliae. Overexpression of GhTINY2 in cotton and Arabidopsis enhanced tolerance to V. dahliae, while knockdown of expression increased the susceptibility of cotton to the pathogen. GhTINY2 was found to promote SA accumulation and SA signaling transduction by directly activating expression of WRKY51. Moreover, GhTINY2-overexpressing cotton and Arabidopsis showed retardation of growth, increased sensitivity to inhibitors of BR biosynthesis, down-regulation of several BR-induced genes, and up-regulation of BR-repressed genes, while GhTINY2-RNAi cotton showed the opposite effects. We further determined that GhTINY2 negatively regulates BR signaling by interacting with BRASSINAZOLE-RESISTANT 1 (BZR1) and restraining its transcriptional activation of the expression of INDOLE-3-ACETIC ACID INDUCIBLE 19 (IAA19). These findings indicate that GhTINY2 fine-tunes the trade-off between immunity and growth via indirect crosstalk between WRKY51-mediated SA biosynthesis and BZR1-IAA19-regulated BR signaling.

Functional analysis of different promoter haplotypes of the coffee (Coffea canephora) CcDREB1D gene through genetic transformation of Nicotiana tabacum

Previous results showed that the three promoter haplotypes (HP15, HP16 and HP17) of the CcDREB1D gene (encoding the dehydration responsive element binding transcription factor) found in the drought-tolerant (HP15/HP16) and drought-sensitive (HP15/HP17) clones of Coffea canephora, diverged by several single nucleotide polymorphisms and insertions/deletions. In order to compare the activities and regulation of these haplotypes in response to abiotic stresses, these sequences were cloned in front of the uidA and analyzed in transgenic tobacco (Nicotiana tabacum) for their ability to regulate the expression of this reporter gene by monitoring GUS histochemical activity under drought (mimicked by dehydration), heat shock and cold treatments. Under unstressed condition, GUS staining was mainly observed in leaf and root vascular tissues of young tobacco plants transformed by the longest sequences of CcDREB1D promoter haplotypes. These GUS activities were not observed in the same tissues of older plants as well as in plants transformed by shorter proximal regions, suggesting a developmentally-regulated activity of CcDREB1D promoters in tobacco and the existence of cis-regulatory elements essential for their regulation in distal regions. Under dehydration and heat shock conditions, GUS staining detected in leaf midribs and secondary veins of pHP17L-transformed plants was correlated with up-regulated expression of uidA reporter gene while no GUS activities were observed in pHP16L-transformed plants. However, all CcDREB1D promoter haplotypes were positively regulated by cold stress in transgenic tobacco. These results showed that these coffee promoters were recognized by the tobacco transcriptional machinery but were regulated in different manners in response to abiotic stress.

Dehydration responsive element binding transcription factors and their applications for the engineering of stress tolerance.

Dehydration responsive element binding (DREB) factors or CRT element binding factors (CBFs) are members of the AP2/ERF family, which comprises a large number of stress-responsive regulatory genes. This review traverses almost two decades of research, from the discovery of DREB/CBF factors to their optimization for application in plant biotechnology. In this review, we describe (i) the discovery, classification, structure, and evolution of DREB genes and proteins; (ii) induction of DREB genes by abiotic stresses and involvement of their products in stress responses; (iii) protein structure and DNA binding selectivity of different groups of DREB proteins; (iv) post-transcriptional and post-translational mechanisms of DREB transcription factor (TF) regulation; and (v) physical and/or functional interaction of DREB TFs with other proteins during plant stress responses. We also discuss existing issues in applications of DREB TFs for engineering of enhanced stress tolerance and improved performance under stress of transgenic crop plants.

Isolation and Functional Characterization of a Novel Gene Encoding a Dehydration Responsive Element Binding Transcription Factor from Populus euphratica.

Dehydration responsive element binding (DREB) transcription factors (TFs) play a key role in regulating abiotic stress related genes. A new gene (PeDREB2b) encoding an unidentified DRE-binding protein was isolated from 20% PEG6000 treated Populus euphratica Oliv. seedlings by RT-PCR and RACE. Full length of PeDREB2b cDNA was 1110 bp, and an ORF of 870 bp, which encoded 289-amino-acids polypeptide, were included. The deduced amino acid sequence analysis revealed that this protein was a putative AP2/EREBP transcription factor with a conserved AP2/EREBP domain of 64 amino acids and a potential nuclear localization signal (NLS). Based on phylogenetic characterization, PeDREB2b was classified as a member of A-5 group belonged to the DREB family. The PeDREB2b gene is induced by salinization, low temperature, drought and phytohormones GA3, NAA and 6BA, but not by ABA treatment. The fact that the product of PeDREB2b as a DREB transcription factor was verified in our further experiment: the nuclear localization of the gene when it was expressed transiently as a GFP fusion in onion epidermal cells. In addition, PeDREB2b was capable of activating reporter gene expression. To study the salt and drought stress responses for PeDREB2b transgenic Arabidopsis thaliana in detail, integrated physiological, biochemical and genetic approach methods were used. Results indicated that the PeDREB2b gene was over-expressed under stress-inducible rd29A promotor in transgenic plants alleviates the adverse effects of environmental stresses.

The gene family of dehydration responsive element-binding transcription factors in grape (Vitis vinifera): genome-wide identification and analysis, expression profiles, and involvement in abiotic stress resistance

The dehydration responsive element-binding (DREB) proteins play a critical role in plant development and abiotic stress-mediated gene expression. Therefore, they represent one of the most attractive regulons for breeding programs. However, no comprehensive summary of grapevine DREB family genes is available. During this study, 38 VvDREB members were identified from the entire grapevine genome and its expression sequence tag assembly. These were organized into the same subgroups, A1 through A6, as for Arabidopsis DREBs. The VvDREB genes were distributed in 15 out of 19 chromosomes in grapevine. Multiple sequence alignments were performed and a three-dimensional structure was created to demonstrate sequence conservation. Microarray analysis showed potential regulatory roles for VvDREBs in responses to various abiotic stresses, hormone treatments, berry ripening, exposure to light, and bud development. Cis-acting regulatory elements, such as W-box, MYB-binding site, and light-responsive elements, were the most frequently found in the putative promoter regions. Furthermore, microarray transcriptional profiling of grapevine plants that over-expressed VvDREB23 revealed 248 up-regulated and 229 down-regulated genes, with fold-changes of >1.5 when compared with the empty vector control. Gene ontology classifications showed that different genes function in cellular glucan metabolism, lipid transport, the endomembrane system, cell wall structure, and other important metabolic and developmental processes, as well as in the regulation of molecular functions. Our report provides an overview and constitutes a foundation for further study of this VvDREB gene family. All the microarray data and transcription profiling of transgenic versus empty-vector control transformant grapevines were retrieved from the online resources.

Isolation and characterization of a buffalograss (Buchloe dactyloides) dehydration responsive element binding transcription factor, BdDREB2

Dehydration responsive element binding (DREB) transcription factors play an important role in the regulation of stress-related genes. These factors contribute to resistance to different abiotic stresses. In the present study, a novel DREB transcription factor, BdDREB2, isolated from Buchloe dactyloides, was cloned and characterized. The BdDREB2 protein was estimated to have a molecular weight of 28.36kDa, a pI of 5.53 and a typical AP2/ERF domain. The expression of BdDREB2 was involved in responses to drought and salt stresses. Overexpression of BdDREB2 in tobacco showed higher relative water and proline content, and was associated with lower MDA content under drought stress, suggesting that the transgenic tobacco may tolerate drought stress better. Results demonstrate that BdDREB2 may play an important role in the regulation of abiotic stress responses, and mediate many physiological pathways that enhance stress tolerance in plants.