Next Article in Journal
Effect of Different Phospholipids on α-Secretase Activity in the Non-Amyloidogenic Pathway of Alzheimer’s Disease
Next Article in Special Issue
A Rice Immunophilin Gene, OsFKBP16-3, Confers Tolerance to Environmental Stress in Arabidopsis and Rice
Previous Article in Journal
Chronobiology of Melatonin beyond the Feedback to the Suprachiasmatic Nucleus—Consequences to Melatonin Dysfunction
Previous Article in Special Issue
Structural Biology of a Major Signaling Network that Regulates Plant Abiotic Stress: The CBL-CIPK Mediated Pathway
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Structure, Function and Networks of Transcription Factors Involved in Abiotic Stress Responses

1
Biomolecular Sciences, Department of Biology, University of Copenhagen, Ole Maaloes Vej 5, DK-2200 Copenhagen N, Denmark
2
Functional Genomics, Department of Biology, University of Copenhagen, Ole Maaloes Vej 5, DK-2200 Copenhagen N, Denmark
*
Author to whom correspondence should be addressed.
Int. J. Mol. Sci. 2013, 14(3), 5842-5878; https://doi.org/10.3390/ijms14035842
Submission received: 4 February 2013 / Revised: 5 March 2013 / Accepted: 5 March 2013 / Published: 13 March 2013
(This article belongs to the Special Issue Abiotic and Biotic Stress Tolerance Mechanisms in Plants)

Abstract

:
Transcription factors (TFs) are master regulators of abiotic stress responses in plants. This review focuses on TFs from seven major TF families, known to play functional roles in response to abiotic stresses, including drought, high salinity, high osmolarity, temperature extremes and the phytohormone ABA. Although ectopic expression of several TFs has improved abiotic stress tolerance in plants, fine-tuning of TF expression and protein levels remains a challenge to avoid crop yield loss. To further our understanding of TFs in abiotic stress responses, emerging gene regulatory networks based on TFs and their direct targets genes are presented. These revealed components shared between ABA-dependent and independent signaling as well as abiotic and biotic stress signaling. Protein structure analysis suggested that TFs hubs of large interactomes have extended regions with protein intrinsic disorder (ID), referring to their lack of fixed tertiary structures. ID is now an emerging topic in plant science. Furthermore, the importance of the ubiquitin-proteasome protein degradation systems and modification by sumoylation is also apparent from the interactomes. Therefore; TF interaction partners such as E3 ubiquitin ligases and TF regions with ID represent future targets for engineering improved abiotic stress tolerance in crops.

1. Introduction

Plants are constantly being exposed to abiotic stresses such as drought, high salinity, high osmolarity, threshold temperatures, nutrient deficiency, oxidation, and changing light conditions. These environmental stress factors negatively affect growth and productivity, and plants have evolved different mechanisms to respond to such challenges. At the molecular level this involves induction of stress-responsive and stress-tolerance genes [1], often mediated by the phytohormone abscisic acid (ABA). ABA is referred to as the plant stress hormone because, in addition to its role in development, it plays a key role in responses to abiotic stress factors by regulating stomatal closure to optimize transpiration, and by triggering the activation of many stress-related genes [2,3].
In plant genomes approximately 7% of the coding sequences are assigned to transcription factors (TFs) [4], and many of these are immediate-early abiotic stress-responsive genes [5]. These TFs probably initiate the indirect-late phase of responses by binding to cis-acting elements in the promoters of specific target genes encoding proteins with specific functions in for example protein turnover, the dehydration response and cell wall modifications [5]. Some of these TFs are master regulators of signaling and regulatory pathways of stress adaptation, and genetic engineering of one or a few of these may be sufficient to enhance stress tolerance in plants, making these TFs attractive targets for engineering [6].
Several recent reviews have addressed the role of specific TF families in abiotic stress responses [714]. In this review, the focus will be on selected TFs from several large plant TF families, which have been shown to play significant roles in responses to the important abiotic stress factors, including drought, high salinity, high osmolarity, threshold temperatures and the chemical abiotic stress factor ABA (Figure 1A). We will address the following questions: (1) What are the molecular mechanisms of principal TFs in abiotic stress responses? (2) What are their target genes and gene regulatory networks? and (3) How do they function in protein-protein interactions (interactomes), and what is the role of protein intrinsic disorder (ID) in these interactomes?

2. Large Plant TF Families in Abiotic Stress Responses

Several families of plant TFs play significant roles in translating abiotic stress signals into changes in gene expression. So far, research into TFs that regulate abiotic stress responses has mainly focused on single TFs and their isolated function. However, it is becoming increasingly clear that TFs also function as hubs, which have many partner proteins, in dynamic networks and as nodes between different pathways. This is also the picture emerging from analysis of TFs from the large TF families basic leucine zipper (bZIP), APETALA 2/ethylene-responsive element binding factor (AP2/ERF), NAM/ATAF1/CUC2 (NAC), WRKY, MYB, Cys2(C2)His2(H2)-type zinc fingers (ZFs), and basic helix-loop-helix (bHLH). A significant fraction of their members have been characterized with respect to their roles in the regulation of abiotic stress responses, and ectopic expression of several TFs from these families has resulted in improved crop stress tolerance. This section describes TFs which by forward and/or reverse genetic screens have been shown to play a functional role in plant stress responses and their gene regulatory networks, inferred from their direct promoter binding. Figure 1 provides an overview of the networks described in this section with relevant abiotic stress factors (Figure 1A), TFs known to function in abiotic stress responses (black boxes and lines) and/or ABA-associated signaling (red boxes and lines) (Figure 1B), and their direct target genes (Figure 1C).

2.1. bZIP TFs

The approximately 75 members of the Arabidopsis (Arabidopsis thaliana) bZIP TF family are divided into more than ten groups [17]. Many of the well-studied group A bZIP TFs play a central role in ABA signaling [10] (Figure 1B,C). For example, the ABA responsive element (ABRE) binding proteins/factors (AREBs/ABFs) AREB1/ABF2, AREB2/ABF4, ABF1, and ABF3 are mainly expressed in vegetative tissues and all except ABF1 are key regulators of ABA signaling that respond to osmotic stress during vegetative growth [10]. Overexpression of AREB2/ABF4 or ABF3 in Arabidopsis conferred ABA hypersensitivity, reduced transpiration, and enhanced drought tolerance [18], and overexpression of an activated form of AREB1/ABF2 also showed increased ABA sensitivity and drought tolerance [19]. These three AREB/ABF TFs from both Arabidopsis and rice (Oryza sativa) require ABA for full target gene activation, and the areb1 areb2 abf3 triple mutant displayed ABA hyposensitivity and reduced tolerance to drought stress compared to single and double AREB/ABF knockout mutants, suggestive of cooperative action between the three TFs [20,21]. The triple mutant also displayed differential expression of multiple stress-responsive genes, including late embryogenesis-abundant (LEA), group-A type-2C phosphatase (PP2C) and various TF genes [21]. AREB1/ABF2 and AREB2/ABF4 directly activated the expression of the ABRE-containing Responsive to Dessication (RD29B) promoter [20,21], and AREB1/ABF2, AREB2/ABF4, and ABF3 all bound to and activated the DRE-BINDING PROTEIN 2A (DREB2A) promoter in an ABRE-dependent manner. An ABA-dependent pathway was therefore suggested to play a role in the osmotic stress-responsive expression of DREB2A, which is mostly associated with ABA-independent stress-regulation [22].
The five ABI5/DPBF group A bZIP TFs, ABI5, enhanced Em levels (EEL), Dc3 promoter-binding factor 2 (DPBF2)/bZIP67, DPBF4, and AREB3, are mainly expressed in seeds and control ABRE-mediated transcription [10]. ABA mediates phosphorylation and activation of these TFs to regulate the ABRE-dependent gene expression of importance to osmotic adjustment and seed dormancy, as well as seedling growth arrest [10,23]. ABI5 was identified by forward genetic screens for mutants exhibiting ABA-resistant germination [24]. Plants overexpressing ABI5 in a transient transactivation experiment resulted in strong and weak activation of the RD29B and RD29A promoters, respectively [25]. ABI5 and its close paralogues also bind and activate additional LEA class genes. Thus, ABI5, DPBF3, and DPBF4 bound to the Arabidopsis Dc3 promoter [26], and ABI5, ABF3, AREB2/ABF4, AREB3, and EEL activated expression from the wheat (Tritium aestivum) Em promoter in transient overexpression assays, both in the absence and presence of ABA [27]. Interestingly, ABI5 and EEL showed antagonistic action by competing for the same binding site within the Arabidopsis Em1 promoter [28], and chromatin immunoprecipitation (ChIP) experiments revealed that ABA increased ABI5 occupancy on the Em6 promoter [29]. In conclusion, the AREB/ABF and ABI5/DPBF TF genes are key regulators of ABA-mediated ABRE-dependent gene expression.
Additional bZIP TFs are implicated in abiotic stress responses. For example, salt-stress induced proteolysis and translocation from the endoplasmatic reticulum to the nucleus of the group B TF bZIP17 has been observed. This is followed by upregulation of salt stress genes, which was blocked by a T-DNA insertion mutation in the AtbZIP17 gene [30]. Furthermore, transcriptional repression of AtbZIP24, of Group F bZIP, using RNA interference, improved salt tolerance in Arabidopsis[31].
Relatively few bZIP regulators have been explored as potential candidates for application in the improvement of drought tolerance in crops. However, the Group A TF OsABF1 from rice (Oryza sativa) and SlAREB from tomato (Solanum lycopersicum) both enhanced tolerance to drought and salt stress [32,33], and SlAREB was found to bind to and activate transcription from the Arabidopsis RD29B and the tomato leucine aminopeptidase (LAP) promoters in an ABA-dependent manner [33].Furthermore, OsbZIP23 overexpression conferred ABA hypersensitivity, and increased salinity and drought tolerance of rice [34], and overexpression of OsbZIP46 increased ABA sensitivity. However, positive regulation of drought and osmotic stress tolerance by OsbZIP46 was dependent on its activation state [35].
The soybean (Glycine max) AREB/ABF GmbZIP1 was highly induced by ABA, drought, high salt, and low temperature, and its overexpression enhanced the response of transgenic plants to ABA and triggered stomatal closure under stress conditions. Overexpression of GmbZIP1 also enhanced the drought tolerance of transgenic wheat, suggesting that GmbZIP1 may be useful for engineering stress tolerance for crops in general [36].

2.2. AP2/ERF TFs

The AP2/ERF plant-specific family with approximately 145 members in Arabidopsis contains four major subfamilies named AP2, RELATED TO ABI3/VP1 (RAV), ERF and dehydration-responsive element-binding protein (DREB). The DREB subfamily proteins play significant roles in abiotic stress responses by regulating gene expression via the cis-acting dehydration-responsive element/C-repeat (DRE/CRT) element [11] (Figure 1B,C). The DREB1 (A-1) sub-group consists of six members, mentioned below. DREB1A/C-repeat-binding factor 3 (CBF3) was identified from its recognition of the DRE/CTR cis-acting element in the RD29A/COR78/LT178[37] and COR15A promoters [38]. DREB1A/CBF3, DREB1B/CBF1, and DREB1C/CBF2 were all induced by cold, although the expression pattern of DREB1C/CBF2 differed from that of the other two genes. Furthermore, DREB1B/CBF1 and DREB1A/CBF3 positively regulated the same set of target genes and were functionally distinct from DREB1C/CBF2 in cold acclimation [39]. DREB1D/CBF4 is responsive to drought stress and, unlike other DREB1/CBF genes, also responsive to ABA [11,40]. DREB1E/DDF2 and DREB1F/DDF1 were both up-regulated by salinity stress, and DREB1F/DDF1 directly upregulated the expression of the gibberellin-deactivating gene, GA2ox7 under high-salinity stress in Arabidopsis. This resulted in reduction of the endogenous gibberellic acid (GA) level, repressed growth and improved stress adaptation [41].
The DREB2 (A-2) subgroup consists of eight members in Arabidopsis with DREB2A as a well-characterized transcriptional regulator. The DREB2A gene was only slightly up-regulated by ABA and both DREB2A and DREB2B were strongly induced by drought, salt, and temperature stress [37,42]. Transgenic plants overexpressing a constitutively active form of DREB2A (DREB2A CA), which lacks a negative regulatory domain (NRD), displayed improved tolerance to drought, high salinity, and heat shock, although the plants revealed growth retardation. Genes up-regulated by DREB2A were induced either by heat shock, drought or both [43,44]. In agreement with this, DREB2A bound both to the RD29A[37] and heat shock factorA3 (HsfA3) promoters. DREB2A also activated the HsfA3 promoter, and the expression of HsfA3 in turn induced the expression of heat shock protein (Hsp) genes [45]. Heat-induced DREB2C also bound and induced the HsfA3 gene, indicating that DREB2A, DREB2C and HsfA3 cooperate in regulating heat tolerance in Arabidopsis[46]. The DREB2C overexpression lines also displayed altered stress response; while the plants were dehydration sensitive, they showed increased heat and freezing tolerance and were ABA-hypersensitive in accordance with the binding to and up-regulation of the promoters of both HsfA3 and COR15A[47].
Other DREB subgroup genes have been reported to be stress-responsive and confer stress tolerance in transgenic plants. Thus, overexpression of ABI4 of subgroup A-3 resulted in ABA-dependent expression of more than a hundred genes, with a synergistic effect between ABI4 and several ABA-responsive bZIP TFs, including ABI5[48], and a subgroup A-5 member RELATED TO AP2.1 (RAP2.1) acted as a transcriptional repressor to keep cold and drought stress responses under tight control. In line with this, ChIP analysis identified the Cold-regulated15A (COR15A) and RD29A as in vivo downstream targets of RAP2.1 [49]. The ABA-responsive ERF subfamily member RAP2.6 and RAP2.6L play a dual role in abiotic and biotic stress responses, and overexpression of RAP2.6L enhanced performance under salt and drought stresses, without affecting the phenotype [50]. Another ERF subfamily member AP2-like ABA repressor 1 (ABR1) was responsive to ABA and several abiotic stress conditions, and repressed ABA-regulated gene expression [51]. ERF7 also plays an important role in ABA responses, and is part of a transcriptional repressor complex [52].
Several studies have analyzed the DREB1 TFs for their ability to improve rice drought stress responses (for review see [53]). Although growth defects may result from overexpression of DREB1/CBFs using constitutive promoters [53], overexpression of DREB1A/CBF3 using a stress-inducible promoter significantly improved spikelet fertility and increased the yield of transgenic rice compared to wild type plants under stress field conditions [54], and ectopic expression of Arabidopsis HARDY in rice improved water use efficiency without a reduction in growth [55]. Induced overexpression of OsDREB2A also proved successful with respect to improved survival rates of the transgenic rice plants under severe drought and salt conditions [56].

2.3. NAC TFs

The NAC family constitutes one of the largest plant-specific TF families with approximately 110 genes in Arabidopsis[57] and 150 genes in rice [58]. NAC TFs have a variety of important functions in plant development and abiotic stress responses [12,13,59] (Figure 1B,C), and whole-genome expression profiling studies in Arabidopsis have shown that most NAC genes are induced by at least one type of abiotic stress signal, such as salinity, drought, cold, or ABA [57].
Some of the well-characterized abiotic stress-associated NAC TFs belong to sub-group III-3, also referred to as ATAF [57] or SNAC (Stress-responsive NAC) sub-group [58]. Members of this sub-group, ANAC019, ANAC055, and RD26 (ANAC072), were induced by drought, high salinity, ABA and JA [57,60], and shown to bind the promoter of EARLY RESPONSIVE TO DEHYDRATION STRESS 1 (ERD1) [60]. Overexpression of these three NAC TFs resulted in up-regulation of several stress-inducible genes and improved drought tolerance of the transgenic plants [60]. Interestingly, up-regulation of the ERD1 gene depended on co-overexpression of one of these NAC TFs and the ZF homeodomain transcriptional activator ZFHD1 [61] suggesting the existence of cooperative regulation of stress responses by members of different TF families. Ectopic expression of ANAC019 and RD26 resulted in ABA-hypersensitivity, suggesting that ANAC019 and RD26 are positive regulators of ABA signaling [57,60,62]. Overexpression of ATAF1 also affected plant tolerance to drought, although contradicting reports suggested positive and/or negative regulatory effects [63,64]. Several of the NAC TFs mentioned above are also implicated in other biological functions. For example, ANAC019 and ANAC055 also regulated jasmonic acid (JA)-induced expression of some defense genes. The anac019 anac055 double mutant plants showed attenuated JA-induced expression of important wound responsive genes, and both JA- and ABA-induced expression of ANAC019 and NAC055 was dependent on the essential JA-signaling regulators, CORONATINE INSENSITIVE 1 (COI1) and MYC2. ANAC019 and ANAC055 may therefore be involved in crosstalk between the JA and ABA pathways for this induction [65,66]. Taken together, subgroup III-3 NAC TFs play important roles in abiotic stress perception and individual NAC members display functional overlap in stress responses.
NAC TFs from other NAC TF groups have also been implicated in abiotic stress responses. Namely, ORE1/AtNAC2/ANAC092 of sub-group II-3 [57], which is involved in lateral root development, was also induced by salt stress and ABA [67], and plays a role in salt-promoted senescence [68]. In addition, the gene VND INTERACTING2 (VNI2; sub-group III-1) was induced by high salinity in an ABA-dependent manner, and overexpression of VNI2 enhanced resistance to salt stress and prolonged leaf longevity, as was also the case for overexpression of the direct target genes COR15A, COR15B, RD29A, and RD29B[69]. Thus, VNI2 integrates ABA-mediated abiotic stress signals into ageing. Furthermore, VNI2 is an interaction partner of the NAC TF VASCULAR-RELATED NAC-DOMAIN7 (VND7), which is a master regulator of xylem vessel differentiation and is related to programmed cell death [70], suggesting that stress tolerance, senescence and programmed cell death are connected via a NAC TF network containing VIN2 and VND7. Together, these examples illustrate how abiotic stress-responsive NAC TFs may be convergence points between functionally different pathways.
Fourteen transmembrane NAC TFs were predicted to be encoded in Arabidopsis[59], some of which are involved in stress responses. Recently the plasma membrane-anchored NTL6 of sub-group I was reported to be proteolytically processed upon exposure to cold. Activated NTL6 migrated to the nucleus and directly induced the Pathogenesis-Related (PR) genes, PR1, PR2, and PR5 directly [71]. Interestingly, ABA simultaneously induced NTL6 expression and NLT6 processing, and transgenic Arabidopsis plants overexpressing NTL6 without the trans-membrane region (35S:6ΔC) were hypersensitive to ABA and high salinity during seed germination [72]. Closely related NAC TFs NTL8 and NTL9 regulated GA-mediated salt signaling in Arabidopsis during seed and leaf senescence, respectively, in response to osmotic stress [73,74]. Furthermore, the ABA, drought and heat inducible NTL4 gene promoted reactive oxygen species (ROS) production during drought-induced senescence in Arabidopsis, and the expressed protein NTL4 directly bound and up-regulated the Atrboh (A, C, and E) genes encoding ROS biosynthetic proteins [75]. In conclusion, several membrane-anchored NTL NAC TFs are nodes connecting different signaling pathways of abiotic and biotic stress responses.
Several studies have addressed the role of crop NAC TFs in abiotic stress responses, and overexpression of SNAC/III-3 sub-group NAC TFs in rice has been especially successful with respect to enhancing stress tolerance. Overexpression of SNAC1 enhanced drought resistance in transgenic rice in the field at the reproductive stage, and also improved drought resistance and salt tolerance in the vegetative stage. Compared to the wild type, the transgenic plants were more hypersensitive to ABA, and water loss was slower due to increased stomatal closure [76]. Overexpression of ABA-inducible OsNAC6/SNAC2 and OsNAC5 increased tolerance to dehydration and high salinity, although with growth retardation and low reproductive yields [77,78], and high salinity [79], respectively. Both NAC TFs bound to the promoter of the stress-inducible OsLEA3 gene [79]. Furthermore, overexpression of ABA-inducible OsNAC10, a subgroup III-2 NAC member, and OsNAC45, a subgroup II-3/CUC member, also enhanced abiotic stress tolerance of rice, in the case of OsNAC10 also under field conditions [80,81]. Finally, overexpression of NAC genes also resulted in increased stress tolerance in other crops such as bread wheat (Triticum aestivum; TaNAC69) [82] and soybean (Glycine max; GmNAC20 and ABA-inducible GmNAC11) [83].

2.4. WRKY TFs

The WRKY TF family, which also constitutes one of the largest plant TF families, is divided into three groups, based on the number of WRKY domains and the features of the associated zinc-finger-like motif [84]. WRKY proteins have been particularly associated with the regulation of plant pathogen responses. However, recent functional analyses have also implicated WRKY TFs in abiotic stress responses [7,14] (Figure 1B,C). For example, overexpression of WRKY25 or WRKY33 increased both salt tolerance and ABA sensitivity [85]. Modulation of the expression of WRKY25, WRKY26, and WRKY33, all group I WRKY genes, also affected resistance to heat stress through modulation of transcriptional reprogramming of heat-inducible genes, and the wrky25,wrky26, wrky33 triple mutant was significantly more sensitive to heat stress than wild type plants [86]. WRKY25 and WRKY33 are also implicated in pathogen defense responses [87], putatively implicating these WRKY TFs in crosstalk between different signaling pathways. Furthermore, in relation to heat stress, heat stress-induced WRKY39, a group II WRKY protein, positively regulated the cooperation between the salicylic acid (SA) and JA activated signaling pathways that mediate responses to heat stress [88]. On the other hand, WRKY34 negatively mediated cold sensitivity of mature Arabidopsis pollen, possibly through the CBF cascade [89].
WRKY TFs also function as key components in ABA-mediated stress signaling. Recently, forward genetics analysis showed that WRKY57 improved drought tolerance in Arabidopsis by increasing the ABA level and up regulating stress-responsive genes. In accordance with this, ChIP assays showed that WRKY57 bound directly to the promoter of RD29A and the key ABA biosynthesis gene 9-cis-epoxycarotenoid dioxygenase3 (NCED3) [90]. A T-DNA insertion mutant of the group III WRKY TF, WRKY63/ABO3, conferred ABA-hypersensitivity during seedling establishment and germination. Furthermore, the abo3 mutation also impaired ABA-induced stomatal closure resulting in increased sensitivity to drought stress of the mutant plants compared to wild type plants [91]. WRKY63/ABO3 bound to the W-box in the promoter of AREB1/ABF2 in accordance with repressed expression of the AREB1/ABF2 gene in abo3 mutant plants [91], and the ABA-dependent induction of WRKY63/ABO3 was impaired in the abi1, abi2, and abi5 mutants. Together, these data showed that WRKY63 is on of the central components of the ABA-dependent gene regulatory network also involving group A ABRE-dependent bZIP TFs.
The closely related group II WRKY TFs, WRKY18, WRKY40 and WRKY60 all function as regulators of ABA signaling in seed germination and postgermination growth [92,93]. WRKY40 inhibited the expression of the important ABA-responsive genes ABF4, ABI4, ABI5, DREB1A, MYB2, and RAB18 by directly binding to the W-box cis-acting element of these promoters [93]. Recently it was shown that not only WRKY40 but also WRKY18 and WRKY60 interacted with the promoters of ABI4 and ABI5 genes and cooperatively inhibited ABI4 and ABI5 expression. This regulation seems to be complex, and one WRKY TF may play either an agonistic or antagotistic role to other WRKY TFs in different situations [94]. This complexity is also clear from the study, in which disruption of WRKY18 and WRKY60 genes decreased ABA sensitivity, while disruption of WRKY40 increased ABA sensitivity. The WRKY18 and WRKY60 mutants, but not the WRKY40 mutant, were more tolerant to salt and osmotic stress than wild type plants. Adding to the complexity, both WRKY40 and WRKY18 bound to and activated the WRKY60 gene, suggesting that WRKY60 is a direct target gene of WRKY40 and WRKY18, in accordance with the induction kinetics of the three genes [92]. WRKY2 of group I also influenced seed germination and post germination growth, and wrky2 knockout mutants displayed delayed or decreased expression of ABI5 and ABI3 and increased or prolonged expression of the LEA genes, Em1 and Em6[95].
WRKY genes have also been explored for their ability to improve abiotic stress tolerance in crops. In rice, expression of OsWRKY11 by the heat-inducible HSP101 promoter resulted in enhanced drought and heat tolerance [96]. Interestingly, OsWRKY45 alleles play different roles in abscisic acid signalling and salt stress tolerance, but similar roles in drought and cold tolerance in rice [97]. Overexpression of GmWRKY21 and GmWRKY54 in Arabidopsis resulted in increased tolerance to cold stress and salt and drought stresses, respectively, whereas overexpression of GmWRKY13 resulted in increased sensitivity to salt and mannitol, but decreased sensitivity to ABA [98], making these genes candidates for improving stress responses, also in soybean (Glycine max).

2.5. Cys2His2 Zinc Finger (C2H2 ZF) TFs

The Arabidopsis genome encodes about 176 Cys2(C2)His2(H2)-type ZFs [99], and C2H2 ZF proteins with an ERF-associated amphiphilic repression (EAR) domain are important transcriptional repressors regulating responses to environmental stress factors [8,100]. Many of these belong to subclass C1-2i, and the members contain two dispersed C2H2-type Zn fingers [8,99]. Several Zat proteins are implicated in abiotic stress responses (Figure 1B,C). Thus Zat10/STZ, the gene of which is cold induced, bound to the promoter of and repressed the RD29A gene [101], and constitutive expression of Zat10 in Arabidopsis enhanced the tolerance of plants to salinity, heat and osmotic stress. Surprisingly, knockout and RNAi mutants of Zat10 turned out to be even more tolerant to osmotic and salinity stress [102]. By contrast, overexpression of Zat7 also resulted in increased tolerance to salinity stress [100]. On the other hand, overexpression of Zat12 in Arabidopsis caused a minor increase in freezing tolerance, and Zat12 downregulated the expression of the DREB/CBF genes suggesting that Zat12 is a negative regulator of the CBF cold response pathway [103].
AZF1 and AZF2, also subclass C1-2i members, were induced by osmotic stress and ABA, and overexpression of these genes compromised plant growth and viability. AZF1 and AZF2 repressed a set of genes that were downregulated by osmotic stress and ABA treatment and many auxin (IAA)-responsive genes, and AZF1 and AZF2 bound the promoter of two of these, SAUR63 and SAUR20, in electrophoretic mobility shift assays (EMSAs). This suggested that AZF1 and AZF2 function as transcriptional repressors to inhibit plant growth, for example by inhibiting auxin-mediated plant growth under abiotic stress conditions [104]. Another EAR-motif C2H2 ZF, SA- and ABA-downregulated zinc finger gene (SAZ) also negatively regulated a subset of ABA-responsive genes, including RD29B and RAB18 in Arabidopsis under unstressed conditions [105].
Similar to the function of Arabidopsis Zat10, the overexpression of OsZat10, which itself is induced by OsDREB1A/CBF3, conferred drought tolerance and, importantly, a 17%–36% yield increase under rain-free conditions [54]. Recently the C2H2 ZF TF DROUGHT AND SALT TOLERANCE (DST) was shown to control stomatal aperture under drought and salt stress in rice by direct modulation of genes related to H2O2 homeostasis. In accordance with this, DST was associated with the promoter sequence of the peroxidase 24 precursor (Osp24p) Osglutathione-S-transferase2 (OsGSTU2), cytochrome P450 71D10 (OscP450-D10), and cytochrome 9450 94A2 (OscP450) genes in ChIP assays [106]. Overexpression of a type TFIIIA C2H2 ZF, ZFP252, enhanced the tolerance of rice seedlings to drought, and this tolerance was correlated with the induction of OsDREB1A and with a higher accumulation of free proline and soluble sugars. Therefore, ZFP252 represents another candidate for engineering crop plants with enhanced tolerance to salt and drought stresses [107]. In a recent addition to this research field, the EAR-motif containing C2H2 ZF ZFP182 from rice was shown to mediate salt, cold, and drought tolerance [108].

2.6. MYB TFs

The Arabidopsis genome encodes 126 MYB TFs, characterized by sequence repeats R1, R2, and R3 of the MYB domain. The R2R3-MYB sub-family is highly expanded in plants [9], and several R2R3-MYB genes are implicated in ABA-mediated abiotic stress responses (Figure 1B,C). For example, MYB60 is downregulated by ABA and dehydration stress and involved in regulation of stomatal opening [109], and MYB44/MYBR1 also regulated ABA-mediated stomatal closure in response to abiotic stress. Furthermore, overexpression of MYB44/MYBR1 resulted in suppression of JA-responsive gene activation. The hypothesis of mutually antagonistic actions between JA- and ABA-signaling pathways was therefore proposed [110,111]. MYB96, induced by drought and ABA, regulated drought stress responses by integrating ABA and auxin signals [112]. MYB2 was inducible by ABA and dehydration, and transgenic Arabidopsis plants overexpressing both MYB2 and the bHLH TF gene MYC2/RD22BP1 exhibited hypersensitivity to ABA and enhanced osmotic stress response compared to wildtype plants [113]. Both proteins bound to and activated transcription from the dehydration-responsive gene RD22[114].
The MYB15 gene is upregulated by cold stress, and MYB15 bound to Myb recognition sites in the promoter of DREB1B/CBF1, DREB1C/CBF2, and DREB1A/CBF3 and downregulated these genes. In accordance with this, MYB15 reduced freezing tolerance [115]. MYB15 was also associated with additional abiotic stress responses, since overexpression of MYB15 improved drought and salt tolerance in Arabidopsis and resulted in ABA-hypersensitivity [116].
Only a limited number of studies have analyzed the effect of ectopic MYB expression in crop plants. In a recent study, OsMYB2 overexpressing plants were shown to be more tolerant to salt, cold, and dehydration stresses and more sensitive to ABA than wildtype plants [117]. Enhanced tolerance to cold stress in OsMYB3R-2 transgenic rice was suggested to be mediated by alteration in cell cycle and ectopic expression of stress genes. Furthermore, OsMYB3R-2 bound directly to the promoter of the cycling gene, OsCycB1[118]. Recently the wheat MYB TF TaPIMP1 was shown to be a positive molecular linker mediating resistance to both Bipolaris sorokiniana and drought stress by regulating stress-related genes in ABA- and SA-signaling pathways in wheat [119]. PIMP1 thereby represents one of several MYBs implicated in both biotic and abiotic stresses [9].

2.7. bHLH TFs

Proteins of the bHLH family are encoded by 162 genes in Arabidopsis[120], and a few of these play a role in ABA-signaling and abiotic stress responses (Figure 1B,C). ABA-inducible MYC2/RD22BP1 was initially characterized as a positive regulator of ABA-inducible genes under osmotic stress conditions, and MYC2 functioned cooperatively with MYB2 TFs in transactivation of the RD22 gene [113,114]. MYC2 has been referred to as the master of action because of its role in the regulation of crosstalk between the signaling pathways of JA and ABA, SA, GAs, and auxin (IAA) [121]. The ABA-inducible TF AIB positively regulated ABA responses in Arabidopsis and plants overexpressing AIB showed increased drought tolerance [122]. The bHLH92 gene was induced by NaCl, dehydration, mannitol, and cold treatments, and overexpression of bHLH92 resulted in a modest increase in tolerance towards NaCl and osmotic stresses through regulation of salt- and drought-responsive genes [123].
The well-characterized bHLH TF inducer of CBF expression 1 (ICE1) is a regulator of CBF genes during cold periods. The ice1 mutation abrogated the expression of DREB1A/CBF3 and decreased the expression of many genes downstream of CBFs, which resulted in a significant reduction in plant tolerance to cold and freezing [124]. ICE1 interacted with MYB15, and together these TFs bound to the DREB1A/CBF3 promoter to regulate cold stress tolerance [115]. ICE1 also bound to the promoter of the BON1-associaited protein1 (BAP1) that is responsive to a moderate decrease in temperature, and is required for the cooling induction of BAP1. The ice1 mutant showed a low level of induction of BAP1 and enhanced resistance to a bacterial pathogen, possibly through potentiating SA-signaling [125].

2.8. Various TFs in Abiotic Stress Responses

Recently, an additional TF was reported to be involved in the DREB2A abiotic stress network (Figure 1B,C). A yeast one-hybrid screening for TFs binding to the DREB2A promoter identified GROWTH-REGULATING FACTOR7 (GRF7) as a repressor of DREB2A. GRF7 was suggested to function as a repressor of a broad range of osmotic stress and/or ABA-responsive genes to prevent growth inhibition normally associated with increased stress tolerance by DREB2A [126]. In relation to the involvement of DREB2A in heat stress, HsfA1-type TFs activated the transcription of the DREB2A gene, and the heat shock-responsive expression of DREB2A disappeared in hsfa1 a/b/d triple and hsfa 1 a/b/d/e quadruple mutants. The triple mutant showed greatly reduced tolerance to heat shock stress compared to wildtype plants [127]. The B3 domain TF ABI3, another well characterized TF, acted upstream of ABI5 to regulate ABA-dependent gene regulation during germination [29]. ABI3 regulated the RD29B and RD29A promoters strongly and weakly, respectively [25], and recent evidence showed that ABI3 also activated the promoter of SOMNUS, a key negative regulator of seed germination [128].

2.9. Gene Regulatory Networks in Abiotic Stress Responses

Figure 1 provides an overview of TFs, representing several large plant TF families, which play a functional role in responses to the important abiotic stress factors drought, high salinity, high osmolarity, temperature extremes and the stress hormone ABA. Most of these TFs are implicated in ABA-dependent signaling as shown by the red-boxed protein names in Figure 1B. ABA signaling is positively regulated by the PYRABACTIN RESISTANCE (PYR)/PYR1-LIKE (PYL)/REGULATORY COMPONENT OF ABA RECEPTOR (RCAR) ABA receptor (ABAR) (Figure 1A), which perceives ABA intracellularily and forms stable ternary complexes with clade A protein phosphatases 2C (PP2Cs). This inactivates the phosphatases, which allows autophosphorylation and activation of downstream subclass III sucrose non-fermenting 1 (SNF1)-related protein kinase 2 (SnRK2). The activated kinase phosphorylates and thereby activates the key components of ABA-signaling, the AREB/ABF TFs and ABI5 [15], which directly induce the expression of genes encoding, for example, LEA proteins and RD29A/B (Figure 1), contributing to stress tolerance and adaptation.
Figure 1C shows direct target genes, identified in ChIP experiments, EMSAs and transactivation assays, for the TFs shown in B. This can be used for assembly of putative gene regulatory networks. Interestingly, some of the AREB/ABF and ABI5-like TFs are themselves direct downstream targets of other TFs. Thus WRKY63 directly regulated AREB1/ABF2[91], whereas WRKY40 directly regulated AREB2/ABF4 and ABI5. ABI5 was also shown to be a direct downstream target of the close relatives of WRKY40, WRKY18 and WRKY60 [93,94] (Figure 1B,C). This suggests that some of the WRKY TFs are early nodes in ABA-signaling [14], with the LEA and RD29A/B proteins as putative functional proteins. Only genes which have so far been shown to be direct targets of the TFs in B are shown in Figure 1C. Due to this high level of stringency, components such as WRKY63 [14] may be missing from the emerging networks. Another interesting putative network is related to cold responses. Thus the functional genes COR15A and RD29A were identified as direct targets of DREB1A/CBF3 [37,38]. DREB1A/CBF3, on the other hand, is immediately downstream of the interacting cold-regulating TFs ICE1 and MYB15 [115]. MYB15 also directly targets additional DREB/CBF TFs and BAP1 [125]. Thus, this putative network involves cold-associated TFs from at least three major plant TF families. The figure also illustrates suggested crosstalk between abiotic stress signaling involving ABA-regulated NTL6, and biotic stress signaling involving the PR genes.
Some of the TF target genes shown in Figure 1C are direct targets of multiple TFs representing several TF families. For example, the well-studied RD29A and RD29B genes are common targets of both NAC, WRKY, bZIP, C2H2 ZF, AP2/ERF, and B3 domain TFs, suggestive of overlapping regulatory mechanisms and crosstalk between pathways involving, for example, drought, low temperature, osmotic stress, dehydration, and cold. Regulation of the RD29A and RD29B genes can also be both ABA-dependent and ABA-independent, which in the case of RD29A can be integrated through the DRE/CRT and ABRE cis-acting elements [129].
Figure 1C shows the Gene Ontology (GO) molecular function term for the TF target genes. A significant fraction of these are themselves TFs. However, many of the target genes also encode cell protection proteins such as the LEA proteins (LEA3, Em6, Dc3, Em1, COR15A, COR15B, RAB18, Em), which can function as chaperones [130], additional chaperones (SlLAP), biosynthetic enzymes (NCED3), and cell cycle regulators (CycB1). In addition, although the TFs presented have been studied in relation to their function in abiotic stress responses several direct target genes (PR1, 2, and 5, SAUR20 and 63, and GA2OX7) have mainly been associated with different biological functions.

3. Structures of Abiotic Stress-Related TFs: Determinants of Function

The TFs discussed above are gene-specific DNA-binding regulatory proteins, which either activate or repress transcription of target genes. TFs are grouped into families based on the DNA-binding domain (DBD). TFs predominantly bind DNA in a sequence-specific manner via the DBD, thereby only targeting promoters with a given consensus sequence [131]. Apart from the DBD, TFs contain a transcription regulatory domain (TRD), most commonly a transcriptional activation domain (TAD), which has been classified on the basis of amino acid profile, e.g., as acidic, glutamine-, proline- or serine/threonine-rich. TRDs often have a high degree of low-complexity sequences and a propensity for flexible protein segments that fail to self-fold into an ordered three-dimensional structure, commonly referred to as intrinsic disorder (ID) [132]. Plant TFs of different families, e.g., NAC, bHLH, MYB, bZIP, WRKY, ZF, and AP2/ERF also have significant degrees of ID, which can play a functional role in interactions with other regulatory proteins, as exemplified by the interaction between the C-terminal domain of HvNAC013 and Radical Induced Cell Death1 (RCD1) [133,134]. In this section, we describe structure-function aspects of significant members of the TFs families presented above. Figure 2 summarizes the information and for each TF known plant DNA-binding sites are integrated below the structures. An exception is mouse Zif268 where the DNA sequence shown is adapted from the UniProbe database ( http://thebrain.bwh.harvard.edu/uniprobe/). Information about TAD, NRD, leucine zipper (zip), and bacterial aspartate kinase, chorismate mutase and TyrA (ACT) domain were identified by BLAST searches and literature mining. For POND-FIT [135] analysis a threshold is applied with disorder assigned to values ≥0.5.

3.1. bZIP DBD and Overall Structure of ABI5

The Arabidopsis bZIP TFs are divided into 10 groups based on sequence similarities of their basic regions. Members within the same group have additional features in common, such as the size of the leucine zipper and conserved sequence motifs [17]. Figure 2A shows the schematic structure of the extensively studied Group A bZIP TF ABI5. The bZIP DBD consists of two α-helices with a basic region that binds DNA, and a leucine zipper dimerization motif, as illustrated in Figure 2 by the X-ray structure of the bZIP from mammalian cAMP response element-binding protein (CREB) in complex with target DNA [136]. Plant bZIP proteins preferentially bind to DNA with an ACGT core with binding specificity being regulated by flaking nucleotides from the TACGTA (A-box), GACGTC (C-box) and CACGTG (G-box) [17] or ABRE (ACGTGT/GC) [137]. ABI5 is predicted to be remarkably disordered with the TAD (amino acids residues 9-122; [138]) mapping to regions with a large degree of the ID (Figure 2A). The RCD1-interacting bZIP TGA2 also contains large regions with ID propensity [134].

3.2. AP2/ERF DBD and Overall Structure of DREB2A

DREB2A is a well-studied member of the AP2/ERF TF family, and aspects of both the AP2/ERF DBD and the overall DREB2A structure have been reviewed recently (Figure 2B) [134,139]. AP2/ERF family members share a conserved AP2/ERF DBD of approximately 60 amino acid residues referred to as the GCC-box binding domain (GBD). The NMR solution structure of the AP2/ERF DBD of ERF1 in complex with GCC-box DNA (5′-TAGCCGCCA-3′) revealed that the AP2/ERF DBD contains an N-terminal, three-strand anti-parallel β-sheet that recognizes a target sequence and a C-terminal α-helix, which is packed parallel to the second beta-strand [140] (Figure 2B). The DNA sequences recognized and bound by the DBDs differ between the AP2/ERF subfamilies, and the DREB/CBF TFs also depend on short signature sequences both N-terminally and C-terminally of the DBD for binding to the DRE [141]. Members of the DREB and ERF subfamilies recognize similar, but slightly different sequences. For example, DREB/CBF TFs recognize the DRE sequence, 5′-[A/G]CCGAC-3′, and ERF TFs recognize the GCC-box sequence, 5′-AGCCGCC-3′ and variations thereof, respectively [11]. Members of the AP2 subfamily recognize longer sequences with a 5′-GCAC[A/G]N[A/T]TCCC[A/G]ANG[C/T]-3′ consensus [142], and the AP2/ERF domain of RAV1 recognizes the 5′-CAACA-3′ motif [143]. The recently published ID-prediction profile showed that DREB2A has a high degree of ID in both the N- and C-termini [134]. The transcription activation domain (TAD) of DREB2A maps to region 254 to 335 [43], which is part of a larger DREB2A fragment that was shown to lack secondary structure [144], and the NRD of DREB2A maps to region 136–165, [43], which on the other hand is predicted to be structured (Figure 2B).

3.3. NAC DBD and Overall Structure of ANAC019

The NAC DBD of ANAC019, shown by schematic structure in Figure 2C), was for a long time the only NAC domain for which the tertiary structure was known [145]. The X-ray crystal structure showed that the 168 amino acid residues NAC DBD forms a novel fold consisting of a twisted antiparallel β-sheet that packs against an N-terminal α-helix on one side and a short α-helix on the other side. This overall fold was also found by the recent determination of the rice SNAC1 NAC domain structure [146]. The strict consensus binding site for ANAC019, the NAC-binding site (NACBS), was identified using a reiterative selection procedure and shown to be 5′-TTNCGT[A/G]-3′ [147], in accordance with the core consensus CGT[G/A] identified for several other NAC proteins [13,60]. Although NAC TFs may target single NACBSs in vivo[60], palindromic NACBSs bind with higher affinity [147], and were therefore used for structure determination. Information from a combination of low resolution X-ray crystallography and biochemical solution studies showed that a β-strand with the highly conserved sequence WKATQTD sequence protrudes into the major groove of the DNA (Figure 2C) [148]. Interestingly, both GLIAL CELL MISSING (GCM) TFs and WRKY TFs also use a central β-sheet with similar topology for DNA binding. When the sheets were superimposed, the DNA-binding strand of NAC aligned with the DNA-binding strands of GCM and WRKY [139,149,150], providing solid support for a relationship between the NAC, GCM and WRKY TFs. The TAD of the NAC TFs map to the C-terminal part of the proteins, which were predicted to be disordered especially compared to the N-terminal NAC domain [57]. This is also the case for ANAC019 (Figure 2C), and ID of the TAD was experimentally verified for senescence-associated HvNAC013 [133].

3.4. WRKY DBD and Overall Structure of WRKY40

Figure 2D shows the schematic structure of abiotic stress associated WRKY40, and the tertiary structure of the WRKY DBD of WRKY4. So far, the tertiary structure has not been determined for a WRKY domain from an abiotic stress-related WRKY TF. However, the structure of the 60 amino acid residues WRKY domain of WRKY1 and WRKY4 and the NMR solution structure of WRKY4 in complex with target DNA have been determined [139,151,152]. Figure 2D shows the position of the WRKY domain in the schematic structure of WRKY40. The WRKY domain consists of a four- or five stranded antiparallel β-sheet structure with a Zn-binding pocket formed by either CX4–5CX22–23HXH or CX7CX23HXC at the N-terminus [153]. A β-strand with the conserved WRKYGQK sequence enters the major groove of the target DNA and is involved in sequence-specific DNA binding [150]. The conservation of the WRKY domain is in accordance with a high degree of conservation of its cognate binding site the W-box 5′-TTGAC[C/T]-3′ [153], and mutations in both the WRKYGQK sequence and of the Zn-binding residues impaired DNA-binding [154]. In general WRKY TFs can activate or repress transcription, and they are rich in potential transcriptional activation and repression domains [84]. The schematic structure of WRKY40 suggests that this TF has several regions with ID, which represent putative TRDs and PPIs regions.

3.5. C2H2 ZF DBD and Overall Structure of Zat7

The 168 amino acid residues C2H2-type ZF TF Zat7 contain two C2H2 ZFs both with a conserved plant-specific DNA-binding QALGGH sequence (Figure 2E) [8]. The C2H2-motif consists of approximately 30 amino acid residues and includes two conserved Cys and His bound to one zinc ion. Each finger forms two β strands and one α helix, as shown by the X-ray structure of three ZFs from mouse Immediate-Early protein Zif268 [155]. As is typical for plant C2H2-type ZFs [8], the two fingers in Zat7 are separated by a long spacer predicted to be flexible (Figure 2E). In vitro binding analysis revealed that the conserved plant-specific QALGGH motif plays a critical role in DNA binding activity [156]. Surprisingly, the small Zat7 protein, which also contains two EAR repression domains [100], was predicted to be mostly structured (Figure 2E). This is in contrast to the large C2H2 ZF TF INDETERMINATE DOMAIN5 (IDD5), which was predicted to be structured only in the ZF region [134].

3.6. Helix-Turn-Helix (HTH) DBD and Overall Structure of MYB15

MYB15 is shown as a representative of the R2R3 MYB TFs which are highly proliferated in plants (Figure 2F) [9]. The MYB DBD is highly conserved and consists of sequence repeats (R) of about 52 amino acid residues, each forming three α-helixes. The second and third helices of each repeat form a helix-turn-helix (HTH) structure with a hydrophobic core in the HTH fold [157]. MYB TFs have binding specificity to either type I (5′-CNGTT[A/G]-3′) or type II (5′-G[G/T]T[A/T]GTT[(A/G]-3) and type IIG (5′-G[G/T]T[(A/T]GGT[A/G]-3′) MYB recognition sequences. MYB15 preferentially bound to type II and type IIG [115,158]. MYB15 contains one R2 and one R3 type sequence repeat in the MYB DBD. Since no R2R3 MYB-DNA complex structure has been determined, the HTH domain of the teleomeric DNA-binding protein TRF2 in complex with target DNA [159] is shown together with the schematic structure of MYB15 (Figure 2F). MYB15 is predicted to have a large disordered region in the middle of its sequence.

3.7. bHLH DBD and Overall Structure of ICE1

The bHLH TF ICE1 consists of 494 amino acid residues, and in addition the DBD it contains one recognizable domain, the bacterial aspartate kinase, chorismate mutase and TyrA (ACT) amino acid-binding (Figure 2G). The bHLH DBD consists of approximately 60 amino acids with two functionally distinct regions. The basic N-terminal region of the DBD is approximately 15 amino acid residues long and is involved in DNA-binding, whereas the C-terminal end functions as a dimerization domain and consists mainly of hydrophobic amino acid residues that form two amphiphatic α-helices separated by a loop region [160]. Co-crystal structural analysis showed that the interaction between the bHLH regions of two separate polypeptides leads to formation of homodimers and/or heterodimers and that the basic region of each partner binds to half of the DNA recognition site, as shown for the X-ray structure of the mouse MyoD bHLH domain bound to DNA [161] (Figure 2G). The core DNA sequence recognized by the bHLH proteins is a consensus hexanucleotide sequence known as the E-box (5′-CANNTG-3′). There are different types of E-boxes, and one of the most common ones is the palindromic G-box (5′-CACGTG) [160]. ICE1 bound to five different E-box variants in the CBF3 promoter [124] and to the 5′-CAAATG-3′ sequence in the BAP1 promoter [125]. ICE1 is predicted to have a significant degree of ID, as was also the case for the bHLH proteins PIF3 and bHLH011 [134].

3.8. Structure of TFs in Abiotic Stress Responses

Gene-specific TFs recognize DNA by their DBD, which is generally known to determine DNA-binding specificity. The DBDs of the TFs shown in Figure 2 all have well-defined tertiary folds, providing a scaffold. As expected, the DBD generally maps to regions predicted to be structured (Figure 2). However, many of the DBDs are surrounded by regions with high propensities for ID, and such flanking disordered regions have recently been suggested to affect DNA-binding specificity and affinity [162,163]. Interestingly, remote ID regions may fine-tune selectivity as well as affinity of DNA-binding through fuzzy (involving ID) interactions with the DNA binding surface [164]. All the TFs shown in Figure 2, except Zat7, were predicted to have a significant degree of ID, and ABI5 and ICE1 were predicted to be mostly disordered. Whether or how the disordered regions affect DNA-binding specificity remains to be determined. Regions with ID are extremely flexible, which forms the basis for their function. Many ID regions (IDRs) are multi-specific and can adapt to several diverse interactions partners. The large interaction potential allows IDRs to interact as hubs with many protein partners [165] in interactomes. The importance of ID to protein interactions is just becoming appreciated in plant science [134].

4. Regulation of TF Activity through Protein-Protein Interactions (PPIs)

Several of the TFs presented are key regulators of abiotic plant stress responses, and some of these have also proved successful in controlling stress responses in field-grown crops [53,54,76]. Even though many of the TFs function by enhancing stress adaptation, abiotic stress responses often interfere with normal growth and development. This makes proper control of the level and the activity of these TFs essential, and several mechanisms are used for this purpose. As shown by the many examples presented here, transcriptional regulation of gene expression by specific TFs binding to specific cis-acting elements in gene promoters represents a major level of control. It is also becoming increasingly clear that the efficiency of gene expression is influenced by the chromatin structure, which is regulated by processes such as DNA methylation and posttranslational modification of histones. The SWI2/SNF2 chromatin remodeling ATPase BRAHMA (BRM), which represses ABA signaling in the absence of stress stimuli in Arabidopsis, represents a recent example of this type of control. In accordance with this, ABI5 expression was derepressed in drought tolerant brm mutants [166]. At the post-transcriptional level several of the TFs are potential regulatory targets of silencing by small RNAs (miRNAs). For example, miRNA164 has affinity for several NAC mRNAs [13], and four NAC targets of miRNA164 were identified as drought responsive in different Populus species [167]. Alternative splicing also represents a method of control, as shown for DREB2A [168]. Here we focus on post-translational control involving PPIs through analysis of the interactomes of the TFs selected and presented in section 3.

4.1. ABI5 Interactome and Regulation

ABI5 has a significantly sized interactome (Figure 3A) reflecting both positive and negative regulation of this key regulator of ABA-dependent stress responses. ABI5 is positively regulated through the PYR/PYL/RCAR ABA receptor (Figure 1) [15]. Thus, phosphorylation of ABI5 by SnRK2 (not shown in Figure 3A) in a region from amino acid residue 132 to 190 (Figure 2A) is a requirement for effective function as an ABA-dependent TF regulating downstream target genes [170,171]. Several negative regulators of ABI5 have been reported. The ABI five binding proteins (AFPs), identified as ABI5 interaction partners in yeast two-hybrid screenings, negatively affected ABA and salt sensitivity and the level of ABI5, possibly through ubiquitin-dependent proteasomal degradation [172,173], which plays a significant role in regulating the ABI5 level. ABI5 also interacted with the RING finger ubiquitin E3 ligase KEEP ON GOING (KEG), which is also a negative regulator of ABA signaling. T-DNA insertions in KEG resulted in increased levels of ABI5, and KEG E3 ubiquitin ligase activity is required for KEG-mediated regulation of ABI5 abundance [174]. It was suggested that ABA promotes ABI5 accumulation by inducing selfubiquitination and proteasomal degradation of KEG. DWA1 and DWA2, which are components of CUL4-based E3 ubiquitin ligases, interacted with ABI5 in vivo and were also suggested to target ABI5 for degradation [174,175]. Furthermore, proteosome-dependent degradation of ABI5 was suggested from analysis of the 26S proteasome subunit, RPN10. The rpn10 mutant showed hypersensitivity to ABA as well as stabilization of the short-lived ABI5 [176].
The E3 small ubiquitin-related modifier (SUMO) ligase SIZ1 also negatively regulated ABI5 to attenuate ABA-signaling. A [K319R] substitution in ABI5 blocked SIZ1-mediated sumoylation of ABI5 in vitro and in abi5-4 plants ABI5(K391R) expression caused greater ABA hypersensitivity than plants expressing wild-type ABI5 (Figure 2A). The conjugation of SUMO to ABI5 both repressed its activity and prevented its degradation [23,177]. Further studies will reveal whether an interplay exists between ubiquitination and sumoylation in regulating ABI5.
The Arabidopsis Mediator subunit MED25, a coactivator of the RNA polymerase, represents a different type of negative regulator of ABI5. MED25 physically associated with ABI5 in promoter regions of ABI5 target genes, which resulted in a negative effect on ABI5-regulated gene expression. Interestingly, MED25 was highly enriched in the Em6 promoter in the absence of ABA, but in response to ABA treatment MED25 recruitment to the Em6 promoter decreased [178]. ABI5 also participates in additional interactions, which may play regulatory roles. Thus, ABI5 physically interacted with ABI3, with which it also interacted genetically, using the region of amino acid residues 123–371, and ABI5 and ABI3 were suggested to be part of regulatory complexes of varying composition [138].

4.2. DREB2A Interactome and Regulation

Many protein interaction partners have been assigned to the DREB2 interactome (Figure 3B), and some of these are regulators of the DREB2A activity and level. The E3 ubiquitin ligases DREB2A INTERACTING PROTEINS 1 and 2 (DRIP1 and 2) were identified as DREB2A interaction partners and may utilize ID in the N-terminal region of DREB2A for these interactions (Figures 2B and 3B). DRIP1 and 2 negatively regulated plant drought stress-responsive gene expression, possibly through targeting of DREB2A for proteasomal degradation [179]. DREB2A also interacted with the regulatory hub protein Radical Induced Cell Death 1 (RCD1) and its closest paralogue SIMILAR TO RCD ONE (SRO1) [180]. RCD1 is degraded upon heat shock and the RCD1-interaction-deficient dreb2a splice variant DREB1a.2, accumulated upon heat shock and senescence. It was, therefore, suggested that removal of RCD1 or the loss of the interaction domain in DREB2A is required for proper DREB2A function under abiotic stress conditions [168]. Interestingly, the RCD1-interacting motif in DREB2A is present in an α-helical region [168], which is part of a larger disordered region in DREB2A that may provide flexibility to the regulatory interaction with RCD1 (Figure 2B) [134].
DREB2A interactions with MED25 also involved the C-terminal part of DREB2A (Figures 2B and 3B), which was shown by biophysical analysis to be disordered [144]. Interestingly, binding of DREB2A to both MED25 and the DRE cis-acting element resulted in structure induction in DREB2A, and the presence of the DRE cis-acting element reduced the affinity of the interaction between DREB2A and MED25. This suggested that transcriptional regulation by DREB2A is facilitated by small but distinct structural changes [144], which may involve structure induction in the ID regions of DREB2A. The additional interaction partners in the DREB2A interactome (Figure 3B) were identified in yeast two-hybrid screenings, and have so far not been characterized further [179,180]. In conclusion, DREB2A regions with a significant degree of ID are implicated in interactions with important regulators of DREB2A level and function. Future research will show whether or how the proteins in the large DREB2A interactome influence the functionality of the stress-associated biochemical hub DREB2A.

4.3. ANAC019 Interactome and Regulation

As for other NAC TFs, the interactome of ANAC109 is limited, especially when excluding homo and hetero dimerization, which takes place through the N-terminal NAC domain (Figures 2C and 3C) [13,147]. Many interactions can be expected for the large, relatively disordered NAC TADs, but the low number of identified interaction partners may reflect the challenge of identifying interaction partners of self-activating protein regions using yeast two-hydrid screenings. However, the DNA-binding NAC domain is also implicated in interactions with other proteins, as exemplified by the regulatory interactions between ANAC019 or NAC1 and E3 protein ubiquitin ligases [181,182] (Figure 2C). ANAC019 was identified as an interaction partner of the small RING-H2 protein RHA2a [181], which is a functional E3 ubiquitin ligase and a positive regulator of ABA-signaling [183]. Additional RING-H2 proteins also interacted with ANAC019 in yeast two-hybrid assays (Figure 3C). Further studies are needed to analyze if RHA2A or other RING-H2 proteins mediate proteasome-dependent degradation of ANAC019 for example to attenuate ABA signals.
Up-regulation of the ERD1 gene depended on co-overexpression of ANAC019 and ZFHD1, and this cooperation may depend on the physical interaction between ANAC019 (region 1–186) and ZFHD1 [61] (Figures 2C and 3C). A putative function of the interaction between ANAC019 and Arabidopsis CTD phosphate-like1 (CPL1) remains to be determined [184]. Clearly, additional interaction partners can be expected to be identified for ANAC019 and other stress-related NAC TF in the future.

4.4. WRKY40 Interactome and Regulation

So far the interactome of WRKY40 is limited to homodimerization and interactions with the closely related WRKY18 and WRKY60 in plant defense responses and the ABA receptor magnesium-protoporphyrin IX chelatase H subunit (CHLH/ABAR) [93,185] (Figure 3D). When the ABA level is high WRKY40 is recruited from the nucleus to the cytosol, where it interacts with CHLH/ABAR localized to the chloroplast/plastid envelope membrane. Thereby CHLH/ABAR mediates de-repression of ABA-responsive genes such as ABI5 allowing ABA responses [93]. Interestingly, homo dimerization of WRKY40 and interactions with WRKY18 and WRK60 was dependent on a potential leucine zipper region outside the WRKY DBD domain (Figure 2D) [185]. Hetero dimerization of these WRKY TFs have also been suggested to play a functional role in ABA responses. Thus, a WRKY18/WRKY40 hetero complex was suggested to regulate the expression of the WRKY60 gene, in accordance with the induction kinetics of these three genes [92]. WRKY40, WRKY18, and WRKY60 also had partially redundant negative effects on SA-mediated defense but played a positive role in JA-mediated defense [185]. These WRKY TFs may therefore mediate crosstalk between plant defense and ABA-related signaling.

4.5. Zat7 Interactome and Regulation

The EAR motifs of Zat7 (Figure 2E) are implicated in the function and interactions of this repressor. Thus, transgenic plants overexpressing Zat7 are more tolerant to salt stress than wild type plants, but deletion or mutation of the EAR motifs abolished this increased tolerance. In contrast, the EAR-motif did not affect growth repression reported for Zat7 overexpressing plants. The interactome of Zat7 is large, but only nine proteins which were regarded potential interactions partners [100] are shown in Figure 3E. Zat7 interacted with stress-responsive and defense-related proteins such as the TF WRKY70 and the miRNA transport protein HASTY through its EAR motifs. Zat7, WRKY70, and HASTY were shown to be co-expressed in plants deficient in the H2O2-scavenging enzyme ascorbate peroxidase 1 (apx1) [186,187]. Since apx1 plants were also more tolerant to salinity stress, Zat7, WRKY70, and HASTY may be part of the same salt stress signaling pathway [100]. Interestingly, WRKY70 is critical for effective defense against pathogen attack and a key regulator in the antagonistic interaction between SA and JA [188], but also likely to play an important role in abiotic stress responses. In conclusion, the EAR-motifs of the Cys2/His2-type zinc finger repressor Zat7 play a role in abiotic stress responses through interactions with other proteins.

4.6. ICE1 and MYB15 Interactomes and Regulation

The cold response in Arabidopsis is also attenuated by the proteasome pathway [189]. The variant RING finger protein HIGH EXPRESSION OF OSMOTICALLY RESPONSIVE GENE 1 (HOS1) physically interacted with ICE1 (Figure 3G) and was required for ubiquitination of ICE1. Cold induced degradation of ICE1 was blocked by the hos1 mutation, and overexpression of HOS1 in transgenic Arabidopsis reduced the expression of DREB/CBF genes and decreased plant-freezing tolerance [189]. Recently Ser403 of ICE1 was shown to be polyubiquitinated in vivo (Figure 2G) and to play a role in both the transactivation activity and the cold induced proteasome-dependent degradation of ICE1 [190].
Like ABI5, ICE1 is a target of SIZ1 [191,192] (Figure 3G). SIZ1-mediated sumoylation of ICE1 at K393 (Figure 2G) facilitated ICE1 activity and stability and, thereby, positively regulated DREB1A/CBF3-dependent cold responses. Furthermore, sumoylated ICE1 repressed the function of both HOS1 and MYB15, which are negative regulators of the DREB/CBF genes, from its interactome (Figure 3G). Thus, sumoylation of ICE1 blocked HOS1-mediated poly-ubiquitination of ICE1, as an example of an antagonistic effect of ubiquitination and sumoylation, and downregulated MYB15 expression [192]. ICE1 remains the only known interaction partner of MYB15 (Figure 3F). Since MYB15 plays a significant role in cold regulation, and possibly also in drought and salt stress regulation, mapping of the MYB15 interactome is of great interest.
Heptahelical protein 1 (HHP1) which is a negative regulator in ABA and osmotic signaling in Arabidopsis also interacted with ICE1 and the hhp1-1 mutant showed hypersensitivity to cold stress with limited watering suggestive of crosstalk between cold and osmotic signaling [193]. SPEECHLESS (SPCH), MUTE, and FAMA of the ICE1 interactome are implicated in stomatal development and possibly related to abiotic stress through their interaction with ICE1 (Figure 3G) [194].

4.7. TF Interactomes in Abiotic Plant Stress

Currently data on plant interactomes is accumulating fast from both individual studies and large scale analysis, as apparent for ABI5, DREB2A, ANAC019, and ICE1. E3 ubiquitin ligases are significant components in several of the TF interactomes shown in Figure 3 involving both ABA-dependent (ABI5 and ANAC019) and ABA-independent (DREB2A and ICE1) signaling pathways. This reflects the importance of the ubiquitin-proteasome system (UPS) in removing regulatory proteins, like TFs, when they have become ubiquitin-tagged. This type of regulation allows the cell to respond rapidly to changes such as environmental stress [195]. Thus, interactomes as shown in Figure 3 complement gene regulatory networks as shown in Figure 1 in describing the molecular regulatory mechanisms of abiotic stress responses.
Within the last ten years the ubiquitin-like modifying protein SUMO has been shown to regulate TF level and activity [196]. The significant role of sumoylation of TFs in abiotic stress responses is also demonstrated by the examples highlighted in this review. The E3 SUMO ligase SIZ1 interacted with and regulated the level of both ABI5 implicated in ABA-signaling and osmotic regulation [23], and ICE1, a regulator of the cold responses [192]. Still much remains to be elucidated to improve the understanding of the SUMO-abiotic stress association.
The interactomes in Figure 3 represents additional interesting regulatory interactions. The RCD1-interaction-deficient dreb2a splice variant DREB2a.2, which lacks the RCD1-interacting region, accumulated upon heat shock and senescence. This suggested that abolishment of the RCD1-DREB2A interaction is required for DREB2A function, and that RCD1 could mediate DREB2A degradation [168]. This illustrates the importance of both protein level and alternative splicing in TF regulation. The interaction between the ABA-receptor CHLH/ABAR and WRKY40 to abolish repression of WRKY40 target genes such as ABI5 [93], and the EAR-motif-dependent repressor function of Zat7, likely involving PPIs [100], represent different TF regulatory mechanisms.
Figure 2 also shows TF regions involved in interactions with other proteins and positions or regions of post translational modification of the TFs. Sumoylation of ABI5 at position 391 is in accordance with the emerging picture that post translational modifications are often targeted towards regions with ID (Figure 2A) [162]. ICE1 is also both sumoylated and ubiquitinated in disordered regions (Figure 2G). ID is also utilized for protein interactions of ABI5 (Figure 2A), DREB2A (Figure 2B) [134,144], and possibly ICE1 (Figure 2G). The significant degree of disorder in several of the TFs suggests that these TFs are hubs of large interactomes [197]. From analysis of human proteins it is becoming apparent that regions with ID represent suitable target for drugs, such as peptide-inhibitors, which associate with proteins interaction surfaces [198]. Such peptide drugs only interfere with a specific, or a few, of the many potential interactions of large hub TFs and therefore may have well-defined, or more specific, effects compared to those obtained from ectopic TF expression. However, for NAC019, the folded DNA-binding NAC domain is responsible for interactions with both RHA2A and ZFHD1 [61,181]. The capability of the NAC domain to interact with both DNA and other proteins may either be explained by its large size or suggest competition for binding. The relatively small protein Zat7, predicted to be mostly folded also in the protein-interaction EAR-motif region, may also use folded ZFs to expand its interaction potential. In conclusion, although some of the TFs in Figures 2 and 3 can use folded domains for protein interactions, the overall interaction potential of ID regions is clear from the interactomes presented.

5. Conclusion

A multitude of examples in section 2 demonstrate that TFs are key regulators of both ABA-dependent and ABA-independent abiotic stress responses. Several examples from the model species Arabidopsis demonstrate how ectopic expression of some of the TFs can improve stress tolerance, also without negative effects on growth and development [53,55]. Ectopic expression of specific TFs with the purpose of improving stress tolerance has also been successful in different crop species [10,13,36,53,76]. However, the effect of ectopic expression is not always simple, as shown for Zat10 which may be both a positive and a negative regulator of plant abiotic stress responses [102]. Future efforts in genetic engineering include fine-tuning of the expression of key TFs for stress tolerance in specific temporal and spatial patterns to avoid negative effects in growth and yield. Different types of regulatory proteins such as ubiquitin E3 ligases with specific TF substrates represent alternative future targets of genetic engineering of improved stress tolerance. In this review we also focused on TF structure including ID, which is an emerging scientific topic that deserves attention in future basic and applied plant research. In conclusion, novel strategies may enter plant science in near future to meet agro-economical interests.

Acknowledgements

This work was supported by the Danish Agency for Science Technology and Innovation grant numbers 274-07-0173 (to K.S.) and 10-093596 (to S.L.).

References

  1. Matsui, A.; Ishida, J.; Morosawa, T.; Mochizuki, Y.; Kaminuma, E.; Endo, T.A.; Okamoto, M.; Nambara, E.; Nakajima, M.; Kawashima, M.; et al. Arabidopsis transcriptome analysis under drought, cold, high-salinity and ABA treatment conditions using a tiling array. Plant Cell Physiol 2008, 49, 1135–1149. [Google Scholar]
  2. Cutler, S.R.; Rodriguez, P.L.; Finkelstein, R.R.; Abrams, S.R. Abscisic acid: Emergence of a core signaling network. Annu. Rev. Plant Biol 2010, 61, 651–679. [Google Scholar]
  3. Finkelstein, R.R.; Gampala, S.S.; Rock, C.D. Abscisic acid signaling in seeds and seedlings. Plant Cell 2002, 14, S15–S45. [Google Scholar]
  4. Udvardi, M.K.; Kakar, K.; Wandrey, M.; Montanari, O.; Murray, J.; Andriankaja, A.; Zhang, J.Y.; Benedito, V.; Hofer, J.M.; Chueng, F.; et al. Legume transcription factors: Global regulators of plant development and response to the environment. Plant Physiol 2007, 144, 538–549. [Google Scholar]
  5. Kilian, J.; Peschke, F.; Berendzen, K.W.; Harter, K.; Wanke, D. Prerequisites, performance and profits of transcriptional profiling the abiotic stress response. Biochim. Biophys. Acta 2012, 1819, 166–175. [Google Scholar]
  6. Golldack, D.; Lüking, I.; Yang, O. Plant tolerance to draught and salinity: Stress regulating transcription factors and their functional significance in the cellular transcriptional network. Plant Cell Rep 2011, 30, 1389–1391. [Google Scholar]
  7. Chen, L.; Song, Y.; Li, S.; Zhang, L.; Zou, C.; Yu, D. The role of WRKY transcription factors in plant abiotic stresses. Biochim. Biophys. Acta 2012, 1819, 120–128. [Google Scholar]
  8. Ciftci-Yilmaz, S.; Mittler, R. The zinc finger network of plants. Cell Mol. Life Sci 2008, 65, 1150–1160. [Google Scholar]
  9. Dubos, C.; Stracke, R.; Grotewold, E.; Weisshaar, B.; Martin, C.; Lepiniec, L. MYB transcription factors in Arabidopsis. Trends Plant Sci 2010, 15, 573–581. [Google Scholar]
  10. Fujita, Y.; Fujita, M.; Shinozaki, K.; Yamaguchi-Shinozaki, K. ABA-mediated transcriptional regulation in response to osmotic stress in plants. J. Plant Res 2011, 124, 509–525. [Google Scholar]
  11. Mizoi, J.; Shinozaki, K.; Yamaguchi-Shinozaki, K. AP2/ERF family transcription factors in plant abiotic stress responses. Biochim. Biophys. Acta 2012, 1819, 86–96. [Google Scholar]
  12. Nakashima, K.; Takasaki, H.; Mizoi, J.; Shinozaki, K.; Yamaguchi-Shinozaki, K. NAC transcription factors in plant abiotic stress responses. Biochim. Biophys. Acta 2012, 1819, 97–103. [Google Scholar]
  13. Puranik, S.; Sahu, P.P.; Srivastava, P.S.; Prasad, M. NAC proteins: Regulation and role in stress tolerance. Trends Plant Sci 2012, 17, 369–381. [Google Scholar]
  14. Rushton, D.L.; Tripathi, P.; Rabara, R.C.; Lin, J.; Ringler, P.; Boken, A.K.; Langum, T.J.; Smidt, L.; Boomsma, D.D.; Emme, N.J.; et al. WRKY transcription factors: Key components in abscisic acid signalling. Plant Biotechnol. J 2012, 10, 2–11. [Google Scholar]
  15. Umezawa, T.; Nakashima, K.; Miyakawa, T.; Kuromori, T.; Tanokura, M.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Molecular basis of the core regulatory network in ABA responses: Sensing, signaling and transport. Plant Cell Physiol 2010, 51, 1821–1839. [Google Scholar]
  16. Gene Ontology search tool. Available online: http://www.arabidopsis.org/tools/bulk/go/index.jsp accessed on 27 February 2013.
  17. Jakoby, M.; Weisshaar, B.; Droge-Laser, W.; Vicente-Carbajosa, J.; Tiedemann, J.; Kroj, T.; Parcy, F. bZIP transcription factors in Arabidopsis. Trends Plant Sci 2002, 7, 106–111. [Google Scholar]
  18. Kang, J.Y.; Choi, H.I.; Im, M.Y.; Kim, S.Y. Arabidopsis basic leucine zipper proteins that mediate stress-responsive abscisic acid signaling. Plant Cell 2002, 14, 343–357. [Google Scholar]
  19. Fujita, Y.; Fujita, M.; Satoh, R.; Maruyama, K.; Parvez, M.M.; Seki, M.; Hiratsu, K.; Ohme-Takagi, M.; Shinozaki, K.; Yamaguchi-Shinozaki, K. AREB1 is a transcription activator of novel ABRE-dependent ABA signaling that enhances drought stress tolerance in Arabidopsis. Plant Cell 2005, 17, 3470–3488. [Google Scholar]
  20. Uno, Y.; Furihata, T.; Abe, H.; Yoshida, R.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Arabidopsis basic leucine zipper transcription factors involved in an abscisic acid-dependent signal transduction pathway under drought and high-salinity conditions. Proc. Natl. Acad. Sci. USA 2000, 97, 11632–11637. [Google Scholar]
  21. Yoshida, T.; Fujita, Y.; Sayama, H.; Kidokoro, S.; Maruyama, K.; Mizoi, J.; Shinozaki, K.; Yamaguchi-Shinozaki, K. AREB1, AREB2, and ABF3 are master transcription factors that cooperatively regulate ABRE-dependent ABA signaling involved in drought stress tolerance and require ABA for full activation. Plant J 2010, 61, 672–685. [Google Scholar]
  22. Kim, J.S.; Mizoi, J.; Yoshida, T.; Fujita, Y.; Nakajima, J.; Ohori, T.; Todaka, D.; Nakashima, K.; Hirayama, T.; Shinozaki, K.; et al. An ABRE promoter sequence is involved in osmotic stress-responsive expression of the DREB2A gene, which encodes a transcription factor regulating drought-inducible genes in Arabidopsis. Plant Cell Physiol 2011, 52, 2136–2146. [Google Scholar]
  23. Miura, K.; Lee, J.; Jin, J.B.; Yoo, C.Y.; Miura, T.; Hasegawa, P.M. Sumoylation of ABI5 by the Arabidopsis SUMO E3 ligase SIZ1 negatively regulates abscisic acid signaling. Proc. Natl. Acad. Sci. USA 2009, 106, 5418–5423. [Google Scholar] [Green Version]
  24. Finkelstein, R.R. Maternal Effects Govern Variable Dominance of Two Abscisic Acid Response Mutations in Arabidopsis thaliana. Plant Physiol 1994, 105, 1203–1208. [Google Scholar]
  25. Nakashima, K.; Fujita, Y.; Katsura, K.; Maruyama, K.; Narusaka, Y.; Seki, M.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Transcriptional regulation of. Plant Mol Biol 2006, 60, 51–68. [Google Scholar]
  26. Kim, S.Y.; Ma, J.; Perret, P.; Li, Z.; Thomas, T.L. Arabidopsis ABI5 subfamily members have distinct DNA-binding and transcriptional activities. Plant Physiol 2002, 130, 688–697. [Google Scholar]
  27. Finkelstein, R.; Gampala, S.S.; Lynch, T.J.; Thomas, T.L.; Rock, C.D. Redundant and distinct functions of the ABA response loci ABA-INSENSITIVE(ABI)5 and ABRE-BINDING FACTOR (ABF)3. Plant Mol. Biol 2005, 59, 253–267. [Google Scholar]
  28. Bensmihen, S.; Rippa, S.; Lambert, G.; Jublot, D.; Pautot, V.; Granier, F.; Giraudat, J.; Parcy, F. The homologous ABI5 and EEL transcription factors function antagonistically to fine-tune gene expression during late embryogenesis. Plant Cell 2002, 14, 1391–1403. [Google Scholar]
  29. Lopez-Molina, L.; Mongrand, S.; McLachlin, D.T.; Chait, B.T.; Chua, N.H. ABI5 acts downstream of ABI3 to execute an ABA-dependent growth arrest during germination. Plant J 2002, 32, 317–328. [Google Scholar]
  30. Liu, J.X.; Srivastava, R.; Che, P.; Howell, S.H. Salt stress responses in Arabidopsis utilize a signal transduction pathway related to endoplasmic reticulum stress signaling. Plant J 2007, 51, 897–909. [Google Scholar]
  31. Yang, O.; Popova, O.V.; Suthoff, U.; Luking, I.; Dietz, K.J.; Golldack, D. The Arabidopsis basic leucine zipper transcription factor AtbZIP24 regulates complex transcriptional networks involved in abiotic stress resistance. Gene 2009, 436, 45–55. [Google Scholar]
  32. Amir, H.M.; Lee, Y.; Cho, J.I.; Ahn, C.H.; Lee, S.K.; Jeon, J.S.; Kang, H.; Lee, C.H.; An, G.; Park, P.B. The bZIP transcription factor OsABF1 is an ABA responsive element binding factor that enhances abiotic stress signaling in rice. Plant Mol. Biol 2010, 72, 557–566. [Google Scholar]
  33. Hsieh, T.H.; Li, C.W.; Su, R.C.; Cheng, C.P.; Tsai, Y.C.; Chan, M.T. A tomato bZIP transcription factor, SlAREB, is involved in water deficit and salt stress response. Planta 2010, 231, 1459–1473. [Google Scholar]
  34. Xiang, Y.; Tang, N.; Du, H.; Ye, H.; Xiong, L. Characterization of OsbZIP23 as a key player of the basic leucine zipper transcription factor family for conferring abscisic acid sensitivity and salinity and drought tolerance in rice. Plant Physiol 2008, 148, 1938–1952. [Google Scholar]
  35. Tang, N.; Zhang, H.; Li, X.; Xiao, J.; Xiong, L. Constitutive activation of transcription factor OsbZIP46 improves drought tolerance in rice. Plant Physiol 2012, 158, 1755–1768. [Google Scholar]
  36. Gao, S.Q.; Chen, M.; Xu, Z.S.; Zhao, C.P.; Li, L.; Xu, H.J.; Tang, Y.M.; Zhao, X.; Ma, Y.Z. The soybean GmbZIP1 transcription factor enhances multiple abiotic stress tolerances in transgenic plants. Plant Mol. Biol 2011, 75, 537–553. [Google Scholar]
  37. Liu, Q.; Kasuga, M.; Sakuma, Y.; Abe, H.; Miura, S.; Yamaguchi-Shinozaki, K.; Shinozaki, K. Two transcription factors, DREB1 and DREB2, with an EREBP/AP2 DNA binding domain separate two cellular signal transduction pathways in drought- and low-temperature-responsive gene expression, respectively, in Arabidopsis. Plant Cell 1998, 10, 1391–1406. [Google Scholar]
  38. Stockinger, E.J.; Gilmour, S.J.; Thomashow, M.F. Arabidopsis thaliana CBF1 encodes an AP2 domain-containing transcriptional activator that binds to the C-repeat/DRE, a cis-acting DNA regulatory element that stimulates transcription in response to low temperature and water deficit. Proc. Natl. Acad. Sci. USA 1997, 94, 1035–1040. [Google Scholar]
  39. Novillo, F.; Medina, J.; Salinas, J. Arabidopsis CBF1 and CBF3 have a different function than CBF2 in cold acclimation and define different gene classes in the CBF regulon. Proc. Natl. Acad. Sci. USA 2007, 104, 21002–21007. [Google Scholar]
  40. Haake, V.; Cook, D.; Riechmann, J.L.; Pineda, O.; Thomashow, M.F.; Zhang, J.Z. Transcription factor CBF4 is a regulator of drought adaptation in Arabidopsis. Plant Physiol 2002, 130, 639–648. [Google Scholar]
  41. Magome, H.; Yamaguchi, S.; Hanada, A.; Kamiya, Y.; Oda, K. The DDF1 transcriptional activator upregulates expression of a gibberellin-deactivating gene, GA2ox7, under high-salinity stress in Arabidopsis. Plant J 2008, 56, 613–626. [Google Scholar]
  42. Nakashima, K.; Shinwari, Z.K.; Sakuma, Y.; Seki, M.; Miura, S.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Organization and expression of two Arabidopsis DREB2 genes encoding DRE-binding proteins involved in dehydration- and high-salinity-responsive gene expression. Plant Mol. Biol 2000, 42, 657–665. [Google Scholar]
  43. Sakuma, Y.; Maruyama, K.; Osakabe, Y.; Qin, F.; Seki, M.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Functional analysis of an Arabidopsis transcription factor, DREB2A, involved in drought-responsive gene expression. Plant Cell 2006, 18, 1292–1309. [Google Scholar]
  44. Sakuma, Y.; Maruyama, K.; Qin, F.; Osakabe, Y.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Dual function of an Arabidopsis transcription factor DREB2A in water-stress-responsive and heat-stress-responsive gene expression. Proc. Natl. Acad. Sci USA 2006, 103, 18822–18827. [Google Scholar]
  45. Schramm, F.; Larkindale, J.; Kiehlmann, E.; Ganguli, A.; Englich, G.; Vierling, E.; von Koskull-Doring, P. A cascade of transcription factor DREB2A and heat stress transcription factor HsfA3 regulates the heat stress response of Arabidopsis. Plant J 2008, 53, 264–274. [Google Scholar]
  46. Chen, H.; Hwang, J.E.; Lim, C.J.; Kim, D.Y.; Lee, S.Y.; Lim, C.O. Arabidopsis DREB2C functions as a transcriptional activator of HsfA3 during the heat stress response. Biochem. Biophys. Res. Commun 2010, 401, 238–244. [Google Scholar]
  47. Lee, S.J.; Kang, J.Y.; Park, H.J.; Kim, M.D.; Bae, M.S.; Choi, H.I.; Kim, S.Y. DREB2C interacts with ABF2, a bZIP protein regulating abscisic acid-responsive gene expression, and its overexpression affects abscisic acid sensitivity. Plant Physiol 2010, 153, 716–727. [Google Scholar]
  48. Reeves, W.M.; Lynch, T.J.; Mobin, R.; Finkelstein, R.R. Direct targets of the transcription factors ABA-Insensitive(ABI)4 and ABI5 reveal synergistic action by ABI4 and several bZIP ABA response factors. Plant Mol. Biol 2011, 75, 347–363. [Google Scholar]
  49. Dong, C.J.; Liu, J.Y. The Arabidopsis EAR-motif-containing protein RAP2.1 functions as an active transcriptional repressor to keep stress responses under tight control. BMC Plant Biol 2010, 10, 47. [Google Scholar]
  50. Krishnaswamy, S.; Verma, S.; Rahman, M.H.; Kav, N.N. Functional characterization of four APETALA2-family genes (RAP2.6, RAP2.6L, DREB19 and DREB26) in Arabidopsis. Plant Mol. Biol 2011, 75, 107–127. [Google Scholar]
  51. Pandey, G.K.; Grant, J.J.; Cheong, Y.H.; Kim, B.G.; Li, L.; Luan, S. ABR1, an APETALA2-domain transcription factor that functions as a repressor of ABA response in Arabidopsis. Plant Physiol 2005, 139, 1185–1193. [Google Scholar]
  52. Song, C.P.; Agarwal, M.; Ohta, M.; Guo, Y.; Halfter, U.; Wang, P.; Zhu, J.K. Role of an Arabidopsis AP2/EREBP-type transcriptional repressor in abscisic acid and drought stress responses. Plant Cell 2005, 17, 2384–2396. [Google Scholar]
  53. Yang, S.; Vanderbeld, B.; Wan, J.; Huang, Y. Narrowing down the targets: Towards successful genetic engineering of drought-tolerant crops. Mol. Plant 2010, 3, 469–490. [Google Scholar]
  54. Xiao, B.Z.; Chen, X.; Xiang, C.B.; Tang, N.; Zhang, Q.F.; Xiong, L.Z. Evaluation of seven function-known candidate genes for their effects on improving drought resistance of transgenic rice under field conditions. Mol. Plant 2009, 2, 73–83. [Google Scholar]
  55. Karaba, A.; Dixit, S.; Greco, R.; Aharoni, A.; Trijatmiko, K.R.; Marsch-Martinez, N.; Krishnan, A.; Nataraja, K.N.; Udayakumar, M.; Pereira, A. Improvement of water use efficiency in rice by expression of HARDY, an Arabidopsis drought and salt tolerance gene. Proc. Natl. Acad. Sci. USA 2007, 104, 15270–15275. [Google Scholar]
  56. Cui, M.; Zhang, W.; Zhang, Q.; Xu, Z.; Zhu, Z.; Duan, F.; Wu, R. Induced over-expression of the transcription factor OsDREB2A improves drought tolerance in rice. Plant Physiol. Biochem 2011, 49, 1384–1391. [Google Scholar]
  57. Jensen, M.K.; Kjaersgaard, T.; Nielsen, M.M.; Galberg, P.; Petersen, K.; O’Shea, C.; Skriver, K. The Arabidopsis thaliana NAC transcription factor family: Structure-function relationships and determinants of ANAC019 stress signalling. Biochem. J 2010, 426, 183–196. [Google Scholar]
  58. Nuruzzaman, M.; Manimekalai, R.; Sharoni, A.M.; Satoh, K.; Kondoh, H.; Ooka, H.; Kikuchi, S. Genome-wide analysis of NAC transcription factor family in rice. Gene 2010, 465, 30–44. [Google Scholar]
  59. Olsen, A.N.; Ernst, H.A.; Leggio, L.L.; Skriver, K. NAC transcription factors: Structurally distinct, functionally diverse. Trends Plant Sci 2005, 10, 79–87. [Google Scholar]
  60. Tran, L.S.; Nakashima, K.; Sakuma, Y.; Simpson, S.D.; Fujita, Y.; Maruyama, K.; Fujita, M.; Seki, M.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Isolation and functional analysis of Arabidopsis stress-inducible NAC transcription factors that bind to a drought-responsive cis-element in the early responsive to dehydration stress 1 promoter. Plant Cell 2004, 16, 2481–2498. [Google Scholar]
  61. Tran, L.S.; Nakashima, K.; Sakuma, Y.; Osakabe, Y.; Qin, F.; Simpson, S.D.; Maruyama, K.; Fujita, Y.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Co-expression of the stress-inducible zinc finger homeodomain ZFHD1 and NAC transcription factors enhances expression of the ERD1 gene in Arabidopsis. Plant J 2007, 49, 46–63. [Google Scholar]
  62. Fujita, M.; Fujita, Y.; Maruyama, K.; Seki, M.; Hiratsu, K.; Ohme-Takagi, M.; Tran, L.S.; Yamaguchi-Shinozaki, K.; Shinozaki, K. A dehydration-induced NAC protein, RD26, is involved in a novel ABA-dependent stress-signaling pathway. Plant J 2004, 39, 863–876. [Google Scholar]
  63. Lu, P.L.; Chen, N.Z.; An, R.; Su, Z.; Qi, B.S.; Ren, F.; Chen, J.; Wang, X.C. A novel drought-inducible gene, ATAF1, encodes a NAC family protein that negatively regulates the expression of stress-responsive genes in Arabidopsis. Plant Mol. Biol 2007, 63, 289–305. [Google Scholar]
  64. Wu, Y.; Deng, Z.; Lai, J.; Zhang, Y.; Yang, C.; Yin, B.; Zhao, Q.; Zhang, L.; Li, Y.; Yang, C.; et al. Dual function of Arabidopsis ATAF1 in abiotic and biotic stress responses. Cell Res 2009, 19, 1279–1290. [Google Scholar]
  65. Bu, Q.; Jiang, H.; Li, C.B.; Zhai, Q.; Zhang, J.; Wu, X.; Sun, J.; Xie, Q.; Li, C. Role of the Arabidopsis thaliana NAC transcription factors ANAC019 and ANAC055 in regulating jasmonic acid-signaled defense responses. Cell Res 2008, 18, 756–767. [Google Scholar]
  66. Jiang, H.; Li, H.; Bu, Q.; Li, C. The RHA2a-interacting proteins ANAC019 and ANAC055 may play a dual role in regulating ABA response and jasmonate response. Plant Signal. Behav 2009, 4, 464–466. [Google Scholar]
  67. He, X.J.; Mu, R.L.; Cao, W.H.; Zhang, Z.G.; Zhang, J.S.; Chen, S.Y. AtNAC2, a transcription factor downstream of ethylene and auxin signaling pathways, is involved in salt stress response and lateral root development. Plant J 2005, 44, 903–916. [Google Scholar]
  68. Balazadeh, S.; Siddiqui, H.; Allu, A.D.; Matallana-Ramirez, L.P.; Caldana, C.; Mehrnia, M.; Zanor, M.I.; Kohler, B.; Mueller-Roeber, B. A gene regulatory network controlled by the NAC transcription factor ANAC092/AtNAC2/ORE1 during salt-promoted senescence. Plant J 2010, 62, 250–264. [Google Scholar]
  69. Yang, S.D.; Seo, P.J.; Yoon, H.K.; Park, C.M. The Arabidopsis NAC transcription factor VNI2 integrates abscisic acid signals into leaf senescence via the COR/RD genes. Plant Cell 2011, 23, 2155–2168. [Google Scholar]
  70. Yamaguchi, M.; Ohtani, M.; Mitsuda, N.; Kubo, M.; Ohme-Takagi, M.; Fukuda, H.; Demura, T. VND-INTERACTING2, a NAC domain transcription factor, negatively regulates xylem vessel formation in Arabidopsis. Plant Cell 2010, 22, 1249–1263. [Google Scholar]
  71. Seo, P.J.; Kim, M.J.; Park, J.Y.; Kim, S.Y.; Jeon, J.; Lee, Y.H.; Kim, J.; Park, C.M. Cold activation of a plasma membrane-tethered NAC transcription factor induces a pathogen resistance response in Arabidopsis. Plant J 2010, 61, 661–671. [Google Scholar]
  72. Seo, P.J.; Park, C.M. A membrane-bound NAC transcription factor as an integrator of biotic and abiotic stress signals. Plant Signal. Behav 2010, 5, 481–483. [Google Scholar]
  73. Kim, S.G.; Lee, A.K.; Yoon, H.K.; Park, C.M. A membrane-bound NAC transcription factor NTL8 regulates gibberellic acid-mediated salt signaling in Arabidopsis seed germination. Plant J 2008, 55, 77–88. [Google Scholar]
  74. Yoon, H.K.; Kim, S.G.; Kim, S.Y.; Park, C.M. Regulation of leaf senescence by NTL9-mediated osmotic stress signaling in Arabidopsis. Mol. Cells 2008, 25, 438–445. [Google Scholar]
  75. Lee, S.; Seo, P.J.; Lee, H.J.; Park, C.M. A NAC transcription factor NTL4 promotes reactive oxygen species production during drought-induced leaf senescence in Arabidopsis. Plant J 2012, 70, 831–844. [Google Scholar]
  76. Hu, H.; Dai, M.; Yao, J.; Xiao, B.; Li, X.; Zhang, Q.; Xiong, L. Overexpressing a NAM, ATAF, and CUC (NAC) transcription factor enhances drought resistance and salt tolerance in rice. Proc. Natl. Acad. Sci. USA 2006, 103, 12987–12992. [Google Scholar]
  77. Hu, H.; You, J.; Fang, Y.; Zhu, X.; Qi, Z.; Xiong, L. Characterization of transcription factor gene SNAC2 conferring cold and salt tolerance in rice. Plant Mol. Biol 2008, 67, 169–181. [Google Scholar]
  78. Nakashima, K.; Tran, L.S.; Van, N.D.; Fujita, M.; Maruyama, K.; Todaka, D.; Ito, Y.; Hayashi, N.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Functional analysis of a NAC-type transcription factor OsNAC6 involved in abiotic and biotic stress-responsive gene expression in rice. Plant J 2007, 51, 617–630. [Google Scholar]
  79. Takasaki, H.; Maruyama, K.; Kidokoro, S.; Ito, Y.; Fujita, Y.; Shinozaki, K.; Yamaguchi-Shinozaki, K.; Nakashima, K. The abiotic stress-responsive NAC-type transcription factor OsNAC5 regulates stress-inducible genes and stress tolerance in rice. Mol. Genet. Genomics 2010, 284, 173–183. [Google Scholar]
  80. Jeong, J.S.; Kim, Y.S.; Baek, K.H.; Jung, H.; Ha, S.H.; Do, C.Y.; Kim, M.; Reuzeau, C.; Kim, J.K. Root-specific expression of OsNAC10 improves drought tolerance and grain yield in rice under field drought conditions. Plant Physiol 2010, 153, 185–197. [Google Scholar]
  81. Zheng, X.; Chen, B.; Lu, G.; Han, B. Overexpression of a NAC transcription factor enhances rice drought and salt tolerance. Biochem. Biophys. Res. Commun 2009, 379, 985–989. [Google Scholar]
  82. Xue, G.P.; Way, H.M.; Richardson, T.; Drenth, J.; Joyce, P.A.; McIntyre, C.L. Overexpression of TaNAC69 leads to enhanced transcript levels of stress up-regulated genes and dehydration tolerance in bread wheat. Mol. Plant 2011, 4, 697–712. [Google Scholar]
  83. Hao, Y.J.; Wei, W.; Song, Q.X.; Chen, H.W.; Zhang, Y.Q.; Wang, F.; Zou, H.F.; Lei, G.; Tian, A.G.; Zhang, W.K.; et al. Soybean NAC transcription factors promote abiotic stress tolerance and lateral root formation in transgenic plants. Plant J 2011, 68, 302–313. [Google Scholar]
  84. Eulgem, T.; Rushton, P.J.; Robatzek, S.; Somssich, I.E. The WRKY superfamily of plant transcription factors. Trends Plant Sci 2000, 5, 199–206. [Google Scholar]
  85. Jiang, Y.; Deyholos, M.K. Functional characterization of Arabidopsis NaCl-inducible WRKY25 and WRKY33 transcription factors in abiotic stresses. Plant Mol. Biol 2009, 69, 91–105. [Google Scholar]
  86. Li, S.; Fu, Q.; Chen, L.; Huang, W.; Yu, D. Arabidopsis thaliana WRKY25, WRKY26, and WRKY33 coordinate induction of plant thermotolerance. Planta 2011, 233, 1237–1252. [Google Scholar]
  87. Andreasson, E.; Jenkins, T.; Brodersen, P.; Thorgrimsen, S.; Petersen, N.H.; Zhu, S.; Qiu, J.L.; Micheelsen, P.; Rocher, A.; Petersen, M.; et al. The MAP kinase substrate MKS1 is a regulator of plant defense responses. EMBO J 2005, 24, 2579–2589. [Google Scholar]
  88. Li, S.; Zhou, X.; Chen, L.; Huang, W.; Yu, D. Functional characterization of Arabidopsis thaliana WRKY39 in heat stress. Mol. Cells 2010, 29, 475–483. [Google Scholar]
  89. Zou, C.; Jiang, W.; Yu, D. Male gametophyte-specific WRKY34 transcription factor mediates cold sensitivity of mature pollen in Arabidopsis. J. Exp. Bot 2010, 61, 3901–3914. [Google Scholar]
  90. Jiang, Y.; Liang, G.; Yu, D. Activated Expression of WRKY57 Confers Drought Tolerance in Arabidopsis. Mol. Plant 2012, 5, 1375–1388. [Google Scholar]
  91. Ren, X.; Chen, Z.; Liu, Y.; Zhang, H.; Zhang, M.; Liu, Q.; Hong, X.; Zhu, J.K.; Gong, Z. ABO3, a WRKY transcription factor, mediates plant responses to abscisic acid and drought tolerance in Arabidopsis. Plant J 2010, 63, 417–429. [Google Scholar]
  92. Chen, H.; Lai, Z.; Shi, J.; Xiao, Y.; Chen, Z.; Xu, X. Roles of arabidopsis WRKY18, WRKY40 and WRKY60 transcription factors in plant responses to abscisic acid and abiotic stress. BMC Plant Biol 2010, 10, 281. [Google Scholar]
  93. Shang, Y.; Yan, L.; Liu, Z.Q.; Cao, Z.; Mei, C.; Xin, Q.; Wu, F.Q.; Wang, X.F.; Du, S.Y.; Jiang, T.; et al. The Mg-chelatase H subunit of Arabidopsis antagonizes a group of WRKY transcription repressors to relieve ABA-responsive genes of inhibition. Plant Cell 2010, 22, 1909–1935. [Google Scholar]
  94. Liu, Z.Q.; Yan, L.; Wu, Z.; Mei, C.; Lu, K.; Yu, Y.T.; Liang, S.; Zhang, X.F.; Wang, X.F.; Zhang, D.P. Cooperation of three WRKY-domain transcription factors WRKY18, WRKY40, and WRKY60 in repressing two ABA-responsive genes ABI4 and ABI5 in Arabidopsis. J. Exp. Bot 2012, 63, 6371–6392. [Google Scholar]
  95. Jiang, W.; Yu, D. Arabidopsis WRKY2 transcription factor mediates seed germination and postgermination arrest of development by abscisic acid. BMC Plant Biol 2009, 9, 96. [Google Scholar]
  96. Wu, X.; Shiroto, Y.; Kishitani, S.; Ito, Y.; Toriyama, K. Enhanced heat and drought tolerance in transgenic rice seedlings overexpressing OsWRKY11 under the control of HSP101 promoter. Plant Cell Rep 2009, 28, 21–30. [Google Scholar]
  97. Tao, Z.; Kou, Y.; Liu, H.; Li, X.; Xiao, J.; Wang, S. OsWRKY45 alleles play different roles in abscisic acid signalling and salt stress tolerance but similar roles in drought and cold tolerance in rice. J. Exp. Bot 2011, 62, 4863–4874. [Google Scholar]
  98. Zhou, Q.Y.; Tian, A.G.; Zou, H.F.; Xie, Z.M.; Lei, G.; Huang, J.; Wang, C.M.; Wang, H.W.; Zhang, J.S.; Chen, S.Y. Soybean WRKY-type transcription factor genes, GmWRKY13, GmWRKY21, and GmWRKY54, confer differential tolerance to abiotic stresses in transgenic Arabidopsis plants. Plant Biotechnol. J 2008, 6, 486–503. [Google Scholar]
  99. Englbrecht, C.C.; Schoof, H.; Bohm, S. Conservation, diversification and expansion of C2H2 zinc finger proteins in the Arabidopsis thaliana genome. BMC Genomics 2004, 5, 39. [Google Scholar]
  100. Ciftci-Yilmaz, S.; Morsy, M.R.; Song, L.; Coutu, A.; Krizek, B.A.; Lewis, M.W.; Warren, D.; Cushman, J.; Connolly, E.L.; Mittler, R. The EAR-motif of the Cys2/His2-type zinc finger protein Zat7 plays a key role in the defense response of Arabidopsis to salinity stress. J. Biol. Chem 2007, 282, 9260–9268. [Google Scholar]
  101. Lee, H.; Guo, Y.; Ohta, M.; Xiong, L.; Stevenson, B.; Zhu, J.K. LOS2, a genetic locus required for cold-responsive gene transcription encodes a bi-functional enolase. EMBO J 2002, 21, 2692–2702. [Google Scholar]
  102. Mittler, R.; Kim, Y.; Song, L.; Coutu, J.; Coutu, A.; Ciftci-Yilmaz, S.; Lee, H.; Stevenson, B.; Zhu, J.K. Gain- and loss-of-function mutations in Zat10 enhance the tolerance of plants to abiotic stress. FEBS Lett 2006, 580, 6537–6542. [Google Scholar]
  103. Vogel, J.T.; Zarka, D.G.; Van Buskirk, H.A.; Fowler, S.G.; Thomashow, M.F. Roles of the CBF2 and ZAT12 transcription factors in configuring the low temperature transcriptome of Arabidopsis. Plant J 2005, 41, 195–211. [Google Scholar]
  104. Kodaira, K.S.; Qin, F.; Tran, L.S.; Maruyama, K.; Kidokoro, S.; Fujita, Y.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Arabidopsis Cys2/His2 zinc-finger proteins AZF1 and AZF2 negatively regulate abscisic acid-repressive and auxin-inducible genes under abiotic stress conditions. Plant Physiol 2011, 157, 742–756. [Google Scholar]
  105. Jiang, C.J.; Aono, M.; Tamaoki, M.; Maeda, S.; Sugano, S.; Mori, M.; Takatsuji, H. SAZ, a new SUPERMAN-like protein, negatively regulates a subset of ABA-responsive genes in Arabidopsis. Mol. Genet. Genomics 2008, 279, 183–192. [Google Scholar]
  106. Huang, X.Y.; Chao, D.Y.; Gao, J.P.; Zhu, M.Z.; Shi, M.; Lin, H.X. A previously unknown zinc finger protein, DST, regulates drought and salt tolerance in rice via stomatal aperture control. Genes Dev 2009, 23, 1805–1817. [Google Scholar]
  107. Xu, D.Q.; Huang, J.; Guo, S.Q.; Yang, X.; Bao, Y.M.; Tang, H.J.; Zhang, H.S. Overexpression of a TFIIIA-type zinc finger protein gene ZFP252 enhances drought and salt tolerance in rice (Oryza sativa L.). FEBS Lett 2008, 582, 1037–1043. [Google Scholar]
  108. Huang, J.; Sun, S.; Xu, D.; Lan, H.; Sun, H.; Wang, Z.; Bao, Y.; Wang, J.; Tang, H.; Zhang, H. A TFIIIA-type zinc finger protein confers multiple abiotic stress tolerances in transgenic rice (Oryza sativa L.). Plant Mol. Biol 2012, 80, 337–350. [Google Scholar]
  109. Cominelli, E.; Galbiati, M.; Vavasseur, A.; Conti, L.; Sala, T.; Vuylsteke, M.; Leonhardt, N.; Dellaporta, S.L.; Tonelli, C. A guard-cell-specific MYB transcription factor regulates stomatal movements and plant drought tolerance. Curr. Biol 2005, 15, 1196–1200. [Google Scholar]
  110. Jung, C.; Seo, J.S.; Han, S.W.; Koo, Y.J.; Kim, C.H.; Song, S.I.; Nahm, B.H.; Choi, Y.D.; Cheong, J.J. Overexpression of AtMYB44 enhances stomatal closure to confer abiotic stress tolerance in transgenic Arabidopsis. Plant Physiol 2008, 146, 623–635. [Google Scholar]
  111. Jung, C.; Shim, J.S.; Seo, J.S.; Lee, H.Y.; Kim, C.H.; Choi, Y.D.; Cheong, J.J. Non-specific phytohormonal induction of AtMYB44 and suppression of jasmonate-responsive gene activation in Arabidopsis thaliana. Mol. Cells 2010, 29, 71–86. [Google Scholar]
  112. Seo, P.J.; Xiang, F.; Qiao, M.; Park, J.Y.; Lee, Y.N.; Kim, S.G.; Lee, Y.H.; Park, W.J.; Park, C.M. The MYB96 transcription factor mediates abscisic acid signaling during drought stress response in Arabidopsis. Plant Physiol 2009, 151, 275–289. [Google Scholar]
  113. Abe, H.; Urao, T.; Ito, T.; Seki, M.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Arabidopsis AtMYC2 (bHLH) and AtMYB2 (MYB) function as transcriptional activators in abscisic acid signaling. Plant Cell 2003, 15, 63–78. [Google Scholar]
  114. Abe, H.; Yamaguchi-Shinozaki, K.; Urao, T.; Iwasaki, T.; Hosokawa, D.; Shinozaki, K. Role of arabidopsis MYC and MYB homologs in drought- and abscisic acid-regulated gene expression. Plant Cell 1997, 9, 1859–1868. [Google Scholar]
  115. Agarwal, M.; Hao, Y.; Kapoor, A.; Dong, C.H.; Fujii, H.; Zheng, X.; Zhu, J.K. A R2R3 type MYB transcription factor is involved in the cold regulation of CBF genes and in acquired freezing tolerance. J. Biol. Chem 2006, 281, 37636–37645. [Google Scholar]
  116. Ding, Z.; Li, S.; An, X.; Liu, X.; Qin, H.; Wang, D. Transgenic expression of MYB15 confers enhanced sensitivity to abscisic acid and improved drought tolerance in Arabidopsis thaliana. J. Genet. Genomics 2009, 36, 17–29. [Google Scholar]
  117. Yang, A.; Dai, X.; Zhang, W.H. A R2R3-type MYB gene, OsMYB2, is involved in salt, cold, and dehydration tolerance in rice. J. Exp. Bot 2012, 63, 2541–2556. [Google Scholar]
  118. Ma, Q.; Dai, X.; Xu, Y.; Guo, J.; Liu, Y.; Chen, N.; Xiao, J.; Zhang, D.; Xu, Z.; Zhang, X.; et al. Enhanced tolerance to chilling stress in OsMYB3R-2 transgenic rice is mediated by alteration in cell cycle and ectopic expression of stress genes. Plant Physiol 2009, 150, 244–256. [Google Scholar]
  119. Zhang, Z.; Liu, X.; Wang, X.; Zhou, M.; Zhou, X.; Ye, X.; Wei, X. An R2R3 MYB transcription factor in wheat, TaPIMP1, mediates host resistance to Bipolaris sorokiniana and drought stresses through regulation of defense- and stress-related genes. New Phytol 2012, 196, 1155–1170. [Google Scholar]
  120. Bailey, P.C.; Martin, C.; Toledo-Ortiz, G.; Quail, P.H.; Huq, E.; Heim, M.A.; Jakoby, M.; Werber, M.; Weisshaar, B. Update on the basic helix-loop-helix transcription factor gene family in Arabidopsis thaliana. Plant Cell 2003, 15, 2497–2502. [Google Scholar]
  121. Kazan, K.; Manners, J.M. MYC2: The Master in Action. Mol. Plant 2012. [Google Scholar] [CrossRef]
  122. Li, H.; Sun, J.; Xu, Y.; Jiang, H.; Wu, X.; Li, C. The bHLH-type transcription factor AtAIB positively regulates ABA response in Arabidopsis. Plant Mol. Biol 2007, 65, 655–665. [Google Scholar]
  123. Jiang, Y.; Yang, B.; Deyholos, M.K. Functional characterization of the Arabidopsis bHLH92 transcription factor in abiotic stress. Mol. Genet. Genomics 2009, 282, 503–516. [Google Scholar]
  124. Chinnusamy, V.; Ohta, M.; Kanrar, S.; Lee, B.H.; Hong, X.; Agarwal, M.; Zhu, J.K. ICE1: A regulator of cold-induced transcriptome and freezing tolerance in Arabidopsis. Genes Dev 2003, 17, 1043–1054. [Google Scholar]
  125. Zhu, Y.; Yang, H.; Mang, H.G.; Hua, J. Induction of BAP1 by a moderate decrease in temperature is mediated by ICE1 in Arabidopsis. Plant Physiol 2011, 155, 580–588. [Google Scholar]
  126. Kim, J.S.; Mizoi, J.; Kidokoro, S.; Maruyama, K.; Nakajima, J.; Nakashima, K.; Mitsuda, N.; Takiguchi, Y.; Ohme-Takagi, M.; Kondou, Y.; et al. Arabidopsis growth-regulating factor7 functions as a transcriptional repressor of abscisic acid- and osmotic stress-responsive genes, including DREB2A. Plant Cell 2012, 24, 3393–3405. [Google Scholar]
  127. Yoshida, T.; Ohama, N.; Nakajima, J.; Kidokoro, S.; Mizoi, J.; Nakashima, K.; Maruyama, K.; Kim, J.M.; Seki, M.; Todaka, D.; et al. Arabidopsis HsfA1 transcription factors function as the main positive regulators in heat shock-responsive gene expression. Mol. Genet. Genomics 2011, 286, 321–332. [Google Scholar]
  128. Park, J.; Lee, N.; Kim, W.; Lim, S.; Choi, G. ABI3 and PIL5 collaboratively activate the expression of SOMNUS by directly binding to its promoter in imbibed Arabidopsis seeds. Plant Cell 2011, 23, 1404–1415. [Google Scholar]
  129. Yamaguchi-Shinozaki, K.; Shinozaki, K. Organization of cis-acting regulatory elements in osmotic- and cold-stress-responsive promoters. Trends Plant Sci 2005, 10, 88–94. [Google Scholar]
  130. Tompa, P.; Kovacs, D. Intrinsically disordered chaperones in plants and animals. Biochem. Cell Biol 2010, 88, 167–174. [Google Scholar]
  131. Luscombe, N.M.; Thornton, J.M. Protein-DNA interactions: Amino acid conservation and the effects of mutations on binding specificity. J. Mol. Biol 2002, 320, 991–1009. [Google Scholar]
  132. Dyson, H.J.; Wright, P.E. Intrinsically unstructured proteins and their functions. Nat Rev Mol. Cell Biol 2005, 6, 197–208. [Google Scholar]
  133. Kjaersgaard, T.; Jensen, M.K.; Christiansen, M.W.; Gregersen, P.; Kragelund, B.B.; Skriver, K. Senescence-associated barley NAC (NAM, ATAF1,2, CUC) transcription factor interacts with radical-induced cell death 1 through a disordered regulatory domain. J. Biol. Chem 2011, 286, 35418–35429. [Google Scholar]
  134. Kragelund, B.B.; Jensen, M.K.; Skriver, K. Order by disorder in plant signaling. Trends Plant Sci 2012, 17, 625–632. [Google Scholar]
  135. Xue, B.; Dunbrack, R.L.; Williams, R.W.; Dunker, A.K.; Uversky, V.N. PONDR-FIT: A meta-predictor of intrinsically disordered amino acids. Biochim. Biophys. Acta 2010, 1804, 996–1010. [Google Scholar]
  136. Schumacher, M.A.; Goodman, R.H.; Brennan, R.G. The structure of a CREB bZIP.somatostatin CRE complex reveals the basis for selective dimerization and divalent cation-enhanced DNA binding. J. Biol. Chem 2000, 275, 35242–35247. [Google Scholar]
  137. Skriver, K.; Olsen, F.L.; Rogers, J.C.; Mundy, J. cis-acting DNA elements responsive to gibberellin and its antagonist abscisic acid. Proc. Natl. Acad. Sci. USA 1991, 88, 7266–7270. [Google Scholar]
  138. Nakamura, S.; Lynch, T.J.; Finkelstein, R.R. Physical interactions between ABA response loci of Arabidopsis. Plant J 2001, 26, 627–635. [Google Scholar]
  139. Yamasaki, K.; Kigawa, T.; Seki, M.; Shinozaki, K.; Yokoyama, S. DNA-binding domains of plant-specific transcription factors: Structure, function, and evolution. Trends Plant Sci 2012. [Google Scholar] [CrossRef]
  140. Allen, M.D.; Yamasaki, K.; Ohme-Takagi, M.; Tateno, M.; Suzuki, M. A novel mode of DNA recognition by a beta-sheet revealed by the solution structure of the GCC-box binding domain in complex with DNA. EMBO J 1998, 17, 5484–5496. [Google Scholar]
  141. Canella, D.; Gilmour, S.J.; Kuhn, L.A.; Thomashow, M.F. DNA binding by the Arabidopsis CBF1 transcription factor requires the PKKP/RAGRxKFxETRHP signature sequence. Biochim. Biophys. Acta 2010, 1799, 454–462. [Google Scholar]
  142. Nole-Wilson, S.; Krizek, B.A. DNA binding properties of the Arabidopsis floral development protein AINTEGUMENTA. Nucleic Acids Res 2000, 28, 4076–4082. [Google Scholar]
  143. Kagaya, Y.; Ohmiya, K.; Hattori, T. RAV1, a novel DNA-binding protein, binds to bipartite recognition sequence through two distinct DNA-binding domains uniquely found in higher plants. Nucleic Acids Res 1999, 27, 470–478. [Google Scholar]
  144. Blomberg, J.; Aguilar, X.; Brannstrom, K.; Rautio, L.; Olofsson, A.; Wittung-Stafshede, P.; Bjorklund, S. Interactions between DNA, transcriptional regulator Dreb2a and the Med25 mediator subunit from Arabidopsis thaliana involve conformational changes. Nucleic Acids Res 2012, 40, 5938–5950. [Google Scholar]
  145. Ernst, H.A.; Olsen, A.N.; Larsen, S.; Lo, L.L. Structure of the conserved domain of ANAC, a member of the NAC family of transcription factors. EMBO Rep 2004, 5, 297–303. [Google Scholar]
  146. Chen, Q.; Wang, Q.; Xiong, L.; Lou, Z. A structural view of the conserved domain of rice stress-responsive NAC1. Protein Cell 2011, 2, 55–63. [Google Scholar]
  147. Olsen, A.N.; Ernst, H.A.; Leggio, L.L.; Skriver, K. DNA-binding specificity and molecular finctions of NAC transcription factros. Plant Sci 2005, 169, 785–797. [Google Scholar]
  148. Welner, D.H.; Lindemose, S.; Grossmann, J.G.; Mollegaard, N.E.; Olsen, A.N.; Helgstrand, C.; Skriver, K.; Lo, L.L. DNA binding by the plant-specific NAC transcription factors in crystal and solution: A firm link to WRKY and GCM transcription factors. Biochem J 2012, 444, 395–404. [Google Scholar]
  149. Cohen, S.X.; Moulin, M.; Hashemolhosseini, S.; Kilian, K.; Wegner, M.; Muller, C.W. Structure of the GCM domain-DNA complex: A DNA-binding domain with a novel fold and mode of target site recognition. EMBO J 2003, 22, 1835–1845. [Google Scholar]
  150. Yamasaki, K.; Kigawa, T.; Watanabe, S.; Inoue, M.; Yamasaki, T.; Seki, M.; Shinozaki, K.; Yokoyama, S. Structural basis for sequence-specific DNA recognition by an Arabidopsis WRKY transcription factor. J. Biol. Chem 2012, 287, 7683–7691. [Google Scholar]
  151. Duan, M.R.; Nan, J.; Liang, Y.H.; Mao, P.; Lu, L.; Li, L.; Wei, C.; Lai, L.; Li, Y.; Su, X.D. DNA binding mechanism revealed by high resolution crystal structure of Arabidopsis thaliana WRKY1 protein. Nucleic Acids Res 2007, 35, 1145–1154. [Google Scholar]
  152. Yamasaki, K.; Kigawa, T.; Inoue, M.; Tateno, M.; Yamasaki, T.; Yabuki, T.; Aoki, M.; Seki, E.; Matsuda, T.; Tomo, Y.; et al. Solution structure of an Arabidopsis WRKY DNA binding domain. Plant Cell 2005, 17, 944–956. [Google Scholar]
  153. Rushton, P.J.; Somssich, I.E.; Ringler, P.; Shen, Q.J. WRKY transcription factors. Trends Plant Sci 2010, 15, 247–258. [Google Scholar]
  154. Maeo, K.; Hayashi, S.; Kojima-Suzuki, H.; Morikami, A.; Nakamura, K. Role of conserved residues of the WRKY domain in the DNA-binding of tobacco WRKY family proteins. Biosci. Biotechnol. Biochem 2001, 65, 2428–2436. [Google Scholar]
  155. Pavletich, N.P.; Pabo, C.O. Zinc finger-DNA recognition: Crystal structure of a Zif268-DNA complex at 2.1 A. Science 1991, 252, 809–817. [Google Scholar]
  156. Kubo, K.; Sakamoto, A.; Kobayashi, A.; Rybka, Z.; Kanno, Y.; Nakagawa, H.; Takatsuji, H. Cys2/His2 zinc-finger protein family of petunia: Evolution and general mechanism of target-sequence recognition. Nucleic Acids Res 1998, 26, 608–615. [Google Scholar]
  157. Ogata, K.; Kanei-Ishii, C.; Sasaki, M.; Hatanaka, H.; Nagadoi, A.; Enari, M.; Nakamura, H.; Nishimura, Y.; Ishii, S.; Sarai, A. The cavity in the hydrophobic core of Myb DNA-binding domain is reserved for DNA recognition and trans-activation. Nat. Struct. Biol 1996, 3, 178–187. [Google Scholar]
  158. Romero, I.; Fuertes, A.; Benito, M.J.; Malpica, J.M.; Leyva, A.; Paz-Ares, J. More than 80R2R3-MYB regulatory genes in the genome of Arabidopsis thaliana. Plant J 1998, 14, 273–284. [Google Scholar]
  159. Hanaoka, S.; Nagadoi, A.; Nishimura, Y. Comparison between TRF2 and TRF1 of their telomeric DNA-bound structures and DNA-binding activities. Protein Sci 2005, 14, 119–130. [Google Scholar]
  160. Toledo-Ortiz, G.; Huq, E.; Quail, P.H. The Arabidopsis basic/helix-loop-helix transcription factor family. Plant Cell 2003, 15, 1749–1770. [Google Scholar]
  161. Ma, P.C.; Rould, M.A.; Weintraub, H.; Pabo, C.O. Crystal structure of MyoD bHLH domain-DNA complex: Perspectives on DNA recognition and implications for transcriptional activation. Cell 1994, 77, 451–459. [Google Scholar]
  162. Fuxreiter, M.; Simon, I.; Bondos, S. Dynamic protein-DNA recognition: Beyond what can be seen. Trends Biochem. Sci 2001, 36, 415–423. [Google Scholar]
  163. Guo, X.; Bulyk, M.L.; Hartemink, A.J. Intrinsic disorder within and flanking the DNA-binding domains of human transcription factors. Pac. Symp. Biocomput. 2012, 104–115. [Google Scholar]
  164. Fuxreiter, M.; Tompa, P.; Simon, I. Local structural disorder imparts plasticity on linear motifs. Bioinformatics 2007, 23, 950–956. [Google Scholar]
  165. Han, J.D.; Bertin, N.; Hao, T.; Goldberg, D.S.; Berriz, G.F.; Zhang, L.V.; Dupuy, D.; Walhout, A.J.; Cusick, M.E.; Roth, F.P.; et al. Evidence for dynamically organized modularity in the yeast protein-protein interaction network. Nature 2004, 430, 88–93. [Google Scholar]
  166. Han, S.K.; Sang, Y.; Rodrigues, A.; Wu, M.F.; Rodriguez, P.L.; Wagner, D. The SWI2/SNF2 Chromatin Remodeling ATPase BRAHMA Represses Abscisic Acid Responses in the Absence of the Stress Stimulus in Arabidopsis. Plant Cell 2012, 24, 4892–4906. [Google Scholar]
  167. Li, B.; Qin, Y.; Duan, H.; Yin, W.; Xia, X. Genome-wide characterization of new and drought stress responsive microRNAs in Populus euphratica. J. Exp. Bot 2011, 62, 3765–3779. [Google Scholar]
  168. Vainonen, J.P.; Jaspers, P.; Wrzaczek, M.; Lamminmaki, A.; Reddy, R.A.; Vaahtera, L.; Brosche, M.; Kangasjarvi, J. RCD1-DREB2A interaction in leaf senescence and stress responses in Arabidopsis thaliana. Biochem. J 2012, 442, 573–581. [Google Scholar]
  169. Kao, H.L.; Gunsalus, K.C. Browsing multidimensional molecular networks with the generic network browser (N-Browse). Curr. Protoc. Bioinform. 2008. [Google Scholar] [CrossRef]
  170. Fujii, H.; Verslues, P.E.; Zhu, J.K. Identification of two protein kinases required for abscisic acid regulation of seed germination, root growth, and gene expression in Arabidopsis. Plant Cell 2007, 19, 485–494. [Google Scholar]
  171. Nakashima, K.; Fujita, Y.; Kanamori, N.; Katagiri, T.; Umezawa, T.; Kidokoro, S.; Maruyama, K.; Yoshida, T.; Ishiyama, K.; Kobayashi, M.; et al. Three Arabidopsis SnRK2 protein kinases, SRK2D/SnRK2.2, SRK2E/SnRK2.6/OST1 and SRK2I/SnRK2.3, involved in ABA signaling are essential for the control of seed development and dormancy. Plant Cell Physiol 2009, 50, 1345–1363. [Google Scholar]
  172. Garcia, M.E.; Lynch, T.; Peeters, J.; Snowden, C.; Finkelstein, R. A small plant-specific protein family of ABI five binding proteins (AFPs) regulates stress response in germinating Arabidopsis seeds and seedlings. Plant Mol. Biol 2008, 67, 643–658. [Google Scholar]
  173. Lopez-Molina, L.; Mongrand, S.; Kinoshita, N.; Chua, N.H. AFP is a novel negative regulator of ABA signaling that promotes ABI5 protein degradation. Genes Dev 2003, 17, 410–418. [Google Scholar]
  174. Liu, H.; Stone, S.L. Abscisic acid increases Arabidopsis ABI5 transcription factor levels by promoting KEG E3 ligase self-ubiquitination and proteasomal degradation. Plant Cell. 2010, 22, 2630–2641. [Google Scholar]
  175. Stone, S.L.; Williams, L.A.; Farmer, L.M.; Vierstra, R.D.; Callis, J. KEEP ON GOING, a RING E3 ligase essential for Arabidopsis growth and development, is involved in abscisic acid signaling. Plant Cell 2006, 18, 3415–3428. [Google Scholar]
  176. Smalle, J.; Kurepa, J.; Yang, P.; Emborg, T.J.; Babiychuk, E.; Kushnir, S.; Vierstra, R.D. The pleiotropic role of the 26S proteasome subunit RPN10 in Arabidopsis growth and development supports a substrate-specific function in abscisic acid signaling. Plant Cell 2003, 15, 965–980. [Google Scholar]
  177. Miura, K.; Hasegawa, P.M. Sumoylation and abscisic acid signaling. Plant Signal. Behav 2009, 4, 1176–1178. [Google Scholar]
  178. Chen, R.; Jiang, H.; Li, L.; Zhai, Q.; Qi, L.; Zhou, W.; Liu, X.; Li, H.; Zheng, W.; Sun, J.; et al. The Arabidopsis mediator subunit MED25 differentially regulates jasmonate and abscisic acid signaling through interacting with the MYC2 and ABI5 transcription factors. Plant Cell 2012, 24, 2898–2916. [Google Scholar]
  179. Qin, F.; Sakuma, Y.; Tran, L.S.; Maruyama, K.; Kidokoro, S.; Fujita, Y.; Fujita, M.; Umezawa, T.; Sawano, Y.; Miyazono, K.; et al. Arabidopsis DREB2A-interacting proteins function as RING E3 ligases and negatively regulate plant drought stress-responsive gene expression. Plant Cell 2008, 20, 1693–1707. [Google Scholar]
  180. Jaspers, P.; Blomster, T.; Brosche, M.; Salojarvi, J.; Ahlfors, R.; Vainonen, J.P.; Reddy, R.A.; Immink, R.; Angenent, G.; Turck, F.; et al. Unequally redundant RCD1 and SRO1 mediate stress and developmental responses and interact with transcription factors. Plant J 2009, 60, 268–279. [Google Scholar]
  181. Greve, K.; La Cour, T.; Jensen, M.K.; Poulsen, F.M.; Skriver, K. Interactions between plant RING-H2 and plant-specific NAC (NAM/ATAF1/2/CUC2) proteins: RING-H2 molecular specificity and cellular localization. Biochem J 2003, 371, 97–108. [Google Scholar]
  182. Xie, Q.; Guo, H.S.; Dallman, G.; Fang, S.; Weissman, A.M.; Chua, N.H. SINAT5 promotes ubiquitin-related degradation of NAC1 to attenuate auxin signals. Nature 2002, 419, 167–170. [Google Scholar]
  183. Bu, Q.; Li, H.; Zhao, Q.; Jiang, H.; Zhai, Q.; Zhang, J.; Wu, X.; Sun, J.; Xie, Q.; Wang, D.; et al. The Arabidopsis RING finger E3 ligase RHA2a is a novel positive regulator of abscisic acid signaling during seed germination and early seedling development. Plant Physiol 2009, 150, 463–481. [Google Scholar]
  184. Bang, W.Y.; Kim, S.W.; Jeong, I.S.; Koiwa, H.; Bahk, J.D. The C-terminal region (640–967) of Arabidopsis CPL1 interacts with the abiotic stress- and ABA-responsive transcription factors. Biochem. Biophys. Res. Commun 2008, 372, 907–912. [Google Scholar]
  185. Xu, X.; Chen, C.; Fan, B.; Chen, Z. Physical and functional interactions between pathogen-induced Arabidopsis WRKY18, WRKY40, and WRKY60 transcription factors. Plant Cell 2006, 18, 1310–1326. [Google Scholar]
  186. Davletova, S.; Rizhsky, L.; Liang, H.; Shengqiang, Z.; Oliver, D.J.; Coutu, J.; Shulaev, V.; Schlauch, K.; Mittler, R. Cytosolic ascorbate peroxidase 1 is a central component of the reactive oxygen gene network of Arabidopsis. Plant Cell 2005, 17, 268–281. [Google Scholar]
  187. Pnueli, L.; Liang, H.; Rozenberg, M.; Mittler, R. Growth suppression, altered stomatal responses, and augmented induction of heat shock proteins in cytosolic ascorbate peroxidase (Apx1)-deficient Arabidopsis plants. Plant J 2003, 34, 187–203. [Google Scholar]
  188. Li, J.; Brader, G.; Palva, E.T. The WRKY70 transcription factor: A node of convergence for jasmonate-mediated and salicylate-mediated signals in plant defense. Plant Cell 2004, 16, 319–331. [Google Scholar]
  189. Dong, C.H.; Agarwal, M.; Zhang, Y.; Xie, Q.; Zhu, J.K. The negative regulator of plant cold responses, HOS1, is a RING E3 ligase that mediates the ubiquitination and degradation of ICE1. Proc. Natl. Acad. Sci. USA 2006, 103, 8281–8286. [Google Scholar]
  190. Miura, K.; Ohta, M.; Nakazawa, M.; Ono, M.; Hasegawa, P.M. ICE1 Ser403 is necessary for protein stabilization and regulation of cold signaling and tolerance. Plant J 2011, 67, 269–279. [Google Scholar] [Green Version]
  191. Miura, K.; Hasegawa, P.M. Regulation of cold signaling by sumoylation of ICE1. Plant Signal. Behav 2008, 3, 52–53. [Google Scholar]
  192. Miura, K.; Jin, J.B.; Lee, J.; Yoo, C.Y.; Stirm, V.; Miura, T.; Ashworth, E.N.; Bressan, R.A.; Yun, D.J.; Hasegawa, P.M. SIZ1-mediated sumoylation of ICE1 controls CBF3/DREB1A expression and freezing tolerance in Arabidopsis. Plant Cell 2007, 19, 1403–1414. [Google Scholar]
  193. Chen, C.C.; Liang, C.S.; Kao, A.L.; Yang, C.C. HHP1, a novel signalling component in the cross-talk between the cold and osmotic signalling pathways in Arabidopsis. J. Exp. Bot 2010, 61, 3305–3320. [Google Scholar]
  194. Kanaoka, M.M.; Pillitteri, L.J.; Fujii, H.; Yoshida, Y.; Bogenschutz, N.L.; Takabayashi, J.; Zhu, J.K.; Torii, K.U. SCREAM/ICE1 and SCREAM2 specify three cell-state transitional steps leading to arabidopsis stomatal differentiation. Plant Cell 2008, 20, 1775–1785. [Google Scholar]
  195. Sadanandom, A.; Bailey, M.; Ewan, R.; Lee, J.; Nelis, S. The ubiquitin-proteasome system: Central modifier of plant signalling. New Phytol 2012, 196, 13–28. [Google Scholar]
  196. Castro, P.H.; Tavares, R.M.; Bejarano, E.R.; Azevedo, H. SUMO, a heavyweight player in plant abiotic stress responses. Cell. Mol. Life. Sci 2012, 69, 3269–3283. [Google Scholar]
  197. Dunker, A.K.; Cortese, M.S.; Romero, P.; Iakoucheva, L.M.; Uversky, V.N. Flexible nets. The roles of intrinsic disorder in protein interaction networks. FEBS J 2005, 272, 5129–5148. [Google Scholar]
  198. Oldfield, C.J.; Meng, J.; Yang, J.Y.; Yang, M.Q.; Uversky, V.N.; Dunker, A.K. Flexible nets: Disorder and induced fit in the associations of p53 and 14-3-3 with their partners. BMC Genomics 2008, 9. [Google Scholar] [CrossRef]
Figure 1. Gene regulatory networks of plant transcription factors (TFs) in plant abiotic stress responses and abscisic acid-dependent gene expression. (A) Drought, salt, osmotic stress, temperature, and ABA stress factors modulating the level and activity of the TF (B) and their target genes (C). ABA-dependent signaling pathway can involve TF phosphorylation through the PYR/PYL/RCAR ABA receptor [15]. (B) The boxes represent TF proteins from the model plant Arabidopsis or from different crop plants. Red boxes and lines show that the TF is associated with ABA-signaling. For TF and target genes with several names only one of the names is shown. For references and abbreviations used see the main text. (C) The direct target genes are divided into regulatory genes including TF genes and stress-responsive genes encoding functional proteins. The Gene Ontology (GO) molecular function term is shown as a circle with color code below each Arabidopsis target gene. The GO molecular function annotation was obtained using the Gene Ontology search tool [16] at The Arabidopsis Information Resource. Green arrows and red bars denote TF activation and repression, respectively. Some target genes with no known GO-based molecular function were grouped (i.e., PR1 and PR5, Atrboh A and Atrboh E, SAUR20 and SAUR63, but also rice genes involved in ROS/H2O2 homeostasis, such as OsGSTU2).
Figure 1. Gene regulatory networks of plant transcription factors (TFs) in plant abiotic stress responses and abscisic acid-dependent gene expression. (A) Drought, salt, osmotic stress, temperature, and ABA stress factors modulating the level and activity of the TF (B) and their target genes (C). ABA-dependent signaling pathway can involve TF phosphorylation through the PYR/PYL/RCAR ABA receptor [15]. (B) The boxes represent TF proteins from the model plant Arabidopsis or from different crop plants. Red boxes and lines show that the TF is associated with ABA-signaling. For TF and target genes with several names only one of the names is shown. For references and abbreviations used see the main text. (C) The direct target genes are divided into regulatory genes including TF genes and stress-responsive genes encoding functional proteins. The Gene Ontology (GO) molecular function term is shown as a circle with color code below each Arabidopsis target gene. The GO molecular function annotation was obtained using the Gene Ontology search tool [16] at The Arabidopsis Information Resource. Green arrows and red bars denote TF activation and repression, respectively. Some target genes with no known GO-based molecular function were grouped (i.e., PR1 and PR5, Atrboh A and Atrboh E, SAUR20 and SAUR63, but also rice genes involved in ROS/H2O2 homeostasis, such as OsGSTU2).
Ijms 14 05842f1
Figure 2. Structure of well-studied members of the bZIP, AP2/ERF, NAC, WRKY, C2H2 ZF, HTH and bHLH TF families. (I) Tertiary structure of the TF family designating DBD in complex with DNA. (II) Schematic primary structure drawn to scale and disorder predictions for a selected TF. (III) Regions involved in protein-protein interactions and post-translational modifications. (A) X-ray structure of the bZIP DBD from mouse CREB (PDB accession code 1DH3) and schematic representation of the bZIP TF ABI5. (B) NMR structure of the ERF DBD from Arabidopsis ERF1 (1GCC) and schematic representation of the AP2/ERF TF DREB2A. (C) X-ray structure of the NAC DBD from Arabidopsis ANAC019 (3SWP) and schematic structure of ANAC019. (D) NMR structure of the WRKY DBD from Arabidopsis WRKY4 (2LEX) and schematic representation of WRKY40. (E) X-ray structure of the C2H2 ZF DBD from mouse Zif268 and schematic representation of Zat7. (F) NMR structure of the HTH domain, part of the MYB DBD, from human TRF2 and schematic representation of MYB15. (G) X-ray structure of the bHLH DBD from mouse MyoD and schematic representation of ICE1.
Figure 2. Structure of well-studied members of the bZIP, AP2/ERF, NAC, WRKY, C2H2 ZF, HTH and bHLH TF families. (I) Tertiary structure of the TF family designating DBD in complex with DNA. (II) Schematic primary structure drawn to scale and disorder predictions for a selected TF. (III) Regions involved in protein-protein interactions and post-translational modifications. (A) X-ray structure of the bZIP DBD from mouse CREB (PDB accession code 1DH3) and schematic representation of the bZIP TF ABI5. (B) NMR structure of the ERF DBD from Arabidopsis ERF1 (1GCC) and schematic representation of the AP2/ERF TF DREB2A. (C) X-ray structure of the NAC DBD from Arabidopsis ANAC019 (3SWP) and schematic structure of ANAC019. (D) NMR structure of the WRKY DBD from Arabidopsis WRKY4 (2LEX) and schematic representation of WRKY40. (E) X-ray structure of the C2H2 ZF DBD from mouse Zif268 and schematic representation of Zat7. (F) NMR structure of the HTH domain, part of the MYB DBD, from human TRF2 and schematic representation of MYB15. (G) X-ray structure of the bHLH DBD from mouse MyoD and schematic representation of ICE1.
Ijms 14 05842f2
Figure 3. Arabidopsis interaction networks with different abiotic stress-related TFs as hub. The interactomes are visualized from the N-Browse viewer ( http://www.arabidopsis.org/tools/nbrowse.jsp) [169] with manual modifications as indicated below (A) ABI5 interactome; (B) DREB2A interactome with addition of SRO1; (C) ANAC019 interactome; (D) WRKY40 interactome with addition of CHLH/ABAR; (E) Zat7 interactome; (F) MYB15 interactome; (G) ICE1 interactome.
Figure 3. Arabidopsis interaction networks with different abiotic stress-related TFs as hub. The interactomes are visualized from the N-Browse viewer ( http://www.arabidopsis.org/tools/nbrowse.jsp) [169] with manual modifications as indicated below (A) ABI5 interactome; (B) DREB2A interactome with addition of SRO1; (C) ANAC019 interactome; (D) WRKY40 interactome with addition of CHLH/ABAR; (E) Zat7 interactome; (F) MYB15 interactome; (G) ICE1 interactome.
Ijms 14 05842f3

Share and Cite

MDPI and ACS Style

Lindemose, S.; O'Shea, C.; Jensen, M.K.; Skriver, K. Structure, Function and Networks of Transcription Factors Involved in Abiotic Stress Responses. Int. J. Mol. Sci. 2013, 14, 5842-5878. https://doi.org/10.3390/ijms14035842

AMA Style

Lindemose S, O'Shea C, Jensen MK, Skriver K. Structure, Function and Networks of Transcription Factors Involved in Abiotic Stress Responses. International Journal of Molecular Sciences. 2013; 14(3):5842-5878. https://doi.org/10.3390/ijms14035842

Chicago/Turabian Style

Lindemose, Søren, Charlotte O'Shea, Michael Krogh Jensen, and Karen Skriver. 2013. "Structure, Function and Networks of Transcription Factors Involved in Abiotic Stress Responses" International Journal of Molecular Sciences 14, no. 3: 5842-5878. https://doi.org/10.3390/ijms14035842

Article Metrics

Back to TopTop