NtDREB-1BL1 Enhances Carotenoid Biosynthesis by Regulating Phytoene Synthase in Nicotiana tabacum

As one of the most imperative antioxidants in higher plants, carotenoids serve as accessory pigments to harvest light for photosynthesis as well as photoprotectors for plants to adapt to high light stress. Phytoene synthase (PSY) is the entry enzyme and also the major rate-limiting enzyme in the carotenoid pathway. Here, we report a dehydration-responsive element-binding protein (DREB) transcription factor member in Nicotiana tabacum K326, NtDREB-1BL1, which regulates carotenoids biosynthesis by binding to the NtPSY promoter. The NtDREB-1BL1 transcript was widely distributed in leaves by Real-time PCR. Confocal image revealed that NtDREB-1BL1 was localized in the nucleus. The chromatin immunoprecipitation (ChIP) with the qPCR technique indicated that NtDREB-1BL1 could anchor the promoter region of NtPSY. Overexpression (NtDREB-1BL1 OE) and RNA interference (NtDREB-1BL1 RNAi) of NtDREB-1BL1 were performed to evaluate its biological function in N. tabacum. Both carotenoid and chlorophyll contents increased in transgenic plants of NtDREB-1BL1 OE compared with wild-type (WT) plants, with the augment of the genes involved in carotenoid biosynthesis. In contrast, the contents of carotenoid and chlorophyll significantly decreased in transgenic plants of NtDREB-1BL1 RNAi compared to WT, along with the decline in the expression of genes related to carotenoid biosynthesis. Moreover, transgenic plants of NtDREB-1BL1 OE exhibited enhanced tolerance under drought stress, with the weakened tolerance of drought stress in transgenic plants of NtDREB-1BL1 RNAi. In conclusion, our results illustrated the new role of transcription factor NtDREB-1BL1 in improving carotenoid biosynthesis through regulating NtPSY expression.


Introduction
Carotenoids are essential nutrients and important health-beneficial compounds for humans. As a subgroup of isoprenoid compounds with diverse structures, carotenoids are widely distributed in plants, algae, photosynthetic bacteria, and fungi [1][2][3][4][5]. Carotenoids are well-known antioxidants in higher plants, which not only quench reactive oxygen species (ROS) but also serve to sacrifice themselves under conditions of oxidative stress [2,5]. Moreover, carotenoids play imperative roles in plant growth, development, photosynthesis, and the defense against various stresses. Therefore, regulating carotenoid biosynthesis is of great significance to the production and quality of crops [6][7][8][9][10]. The mevalonate pathway (MVA) and the 2-C-methyl-D-erythritol-4-phosphate (MEP) pathway are found −80 • C. For drought stress, 40-day tobaccos with the same physiological condition were selected and grown in normal conditions without watering for 8 days. Tobacco plants were treated with 300 mM NaCl solution for 6 h [32]. After stress treatment, the leaves of tobaccos were collected and stored in a refrigerator at −80 • C for later use.

Identification and Analysis of NtDREB
The yeast one-hybrid experiment (Y1H) was performed as the reported method with some modification [33]. Briefly, the promoter of the NtPSY gene (GenBank ID: JF461341) as a bait was cloned into baited vector pHIS2 (Clontech, Mountain View, CA, USA). The recombinant vector was transformed into the yeast Y1H Gold strain (Clontech, Mountain View, CA, USA). Moreover, a total of 1 g of tobacco leaves was crushed, and total RNA was extracted using Plant RNA Purification Reagent (Sangon, Shanghai, China). The first-strand cDNA was synthesized by RNA Reverse Transcription Kit (Thermo Fisher, Waltham, MA, USA), and the amplification was conducted using the Advantage R2 PCR Kit (Clontech, Mountain View, CA, USA). The purified cDNA was mixed with the pGADT7-Rec2 prey vector and transformed into the bait yeast strain containing the promoter of the NtPSY gene. Then, the candidate transcription factors were screened by inoculating the library solution. After the reporter gene detection, DNA sequencing and BLAST comparison analysis of positive clones were applied, and the proteins interacting with the NtPSY gene were determined. Yeast one-hybrid experiments initially found that the transcription factor gene interacting with the key region of the NtPSY gene promoter was NtDREB-1BL1 (GenBank ID: XM_016632493.1).
The homologous proteins of different species were identified from the TIGR rice database (http://rice.plantbiology.msu.edu (accessed on 10 June 2021)) and Arabidopsis TAIR (http://arabidopsis.org (accessed on 10 June 2021)) database. The homologous protein sequences of DREB-1BL1 in N. tomentosiformis, N. sylvestris and N. benthamiana were searched in the tobacco genome database (using BLASTP, e < 0.001). The conservative domain online prediction software SMART version 9 (http://smart.embl-heidelberg.de/ (accessed on 15 June 2021)) was used to analyze the sequence and confirm that all candidate proteins had typical conserved domains [34]. The GSDS version 2.0 online software (http://gsds.cbi.pku.edu.cn/ (accessed on 20 June 2021)) was performed to visualize gene structure and annotated features. Online software HMMER (https://www.ebi.ac.uk/Tools/ hmmer/ (accessed on 25 July 2021)) was used to study the transmembrane domain of candidate proteins [35]. The molecular weight, isoelectric point, and other physical properties of candidate proteins were predicted by Expasy online software (http://web.expasy.org/protparam/ (accessed on 12 August 2021)) [36]. The DREB-1BL1 candidate protein sequences of different species were compared by the Clustal W program. Mega 7.0 was performed (neighbor-joining algorithm, 1000 bootstrap replicates) for sequence alignment and inference of evolutionary tree [37]. The promoter region of NtPSY was analyzed by Plant Care software. (https://www.plantcare.co.uk/ (accessed on 17 August 2021)) [38].

Subcellular Localization of NtDREB-1BL1
The NtDREB-1BL1 gene was amplified by PCR from the cDNA of N. tabacum leaves with the primers (Table S1). The overexpression vector of Sp1300-NtDREB-1BL1-GFP was constructed by XbaI and KpnI restriction enzymes, which was constructed to express NtDREB-1BL1 with a GFP-tag at the C terminus under the control of the cauliflower mosaic virus 35S promoter (Table S1). The recombinant vectors were transferred into Agrobacterium (GV3101) by electroporation and cultured at 30 • C for 2 days. The positive Agrobacterium was scraped from the solid dish with the inoculation loop and cultured in 10 mL YEB medium. Agrobacterium cells were suspended with 10 mM MgCl 2 (including 120 µM acetosyringone, AS) and adjusted OD600 to 0.6. N. benthamiana plants with about five leaves were infected with Agrobacterium for the transient expression of NtDREB-1BL1-GFP protein. Fluorescence observation was performed by a FluoView FV 1000 laser scanning confocal microscopy system (Olympus, Tokyo, Japan) as described previously [31].

Expression Pattern of NtDREB-1BL1 and Genes Involved in Carotenoid Biosynthesis
Total RNA was isolated from plant tissues using the Plant Total RNA Isolation Kit (Sangon, Shanghai, China), and the first-strand cDNA was synthesized by RNA Reverse Transcription Kit (Thermo Fisher, USA). The expression levels of genes were detected via quantitative real-time PCR (qPCR) using 26s rRNA as the reference gene. The reaction system and conditions were consulted with the manufacturer's protocol [30]. Three biological replicates were conducted for each sample. The relative expression levels of genes were calculated using the 2 -∆∆CT method. The gene-specific primers used for qPCR are listed in Table S1.

Vector Construction and Tobacco Transformation
The vector of Sp1300-NtDREB-1BL1-GFP described above was used for overexpression of NtDREB-1BL1. The 200-300 bp fragment of the NtDREB-1BL1 gene was inserted into the silencing vector pHellsgate 2 by BP recombination reaction. The tobacco genetic transformation process was performed as described previously [31]. Homozygous transgenic (T2) plants of NtDREB-1BL1 OE were screened and confirmed by seed germination on the corresponding hygromycin-containing medium in combination with PCR analyses. Moreover, homozygous transgenic (T2) plants of NtDREB-1BL1 RNAi were confirmed by seed germination on the corresponding kanamycin-containing medium in combination with PCR analyses.

Chromatin Immunoprecipitation (ChIP) Assay
An EpiQuik Chromatin Immunoprecipitation kit (Epigentek, Farmingdale, NY, USA) was used to determine whether NtDREB-1BL1 could bind to the key segments of the NtPSY gene promoter according to reported protocol with some modification [39]. Briefly, twoweek-old tobacco seedlings cultured on MS medium were collected and immediately fixed in 1% formaldehyde solution under vacuum infiltration for 10 min. The chromatin was sheared by sonication to break the DNA into 200-1000 bp fragments. The NtDREB-1BL1-GFP fusion protein was pulled down in the strip wells with an Anti-GFP antibody (Abcam, Waltham, MA, USA). DNA fragments were eluted from the fusion protein and examined by the qRT-PCR analyses. The enrichment of the genomic fragment in two tubulin beta chain genes (NtTUBB, XP_016456097.1, and NP_001312648.1) was used as the negative control. The primers used for fragment amplification are listed in Table S1.

Extraction and Determination of Chlorophyll and Carotenoid
The chlorophyll and carotenoids determinations were performed from transgenic tobacco as described previously [40]. Briefly, 50 mg of leaves were ground into fine powder, and mixed with 80% acetone. The mixture of leaves was protected from light and shocked at 4 • C to bleach completely. The supernatant was harvested by centrifugation at 9000 rpm for 2 min at 4 • C, and the absorbance values at the wavelengths of A663, A647, and A470 were measured by the enzyme marker using 80% acetone as control. Chlorophyll and carotenoid contents were calculated as follows: Chlorophyll a = 12.25 × A663 − 2.79 × A647; Chlorophyll b = 21.50 × A647 − 5.10 × A663; Total chlorophyll = 7.15 × A663 + 18.71 × A647; Carotenoids = (1000 × A470 − 1.82 × Chl a − 85.02 × Chl b) /198.

Reactive Oxygen Species (ROS) Detection
The staining methods used for the DAB detection of H 2 O 2 and the NBT detection of O 2 − were performed as described previously [30]. The contents of O 2 − and H 2 O 2 in leaves were analyzed according to the color variations of the leaves. Leaves of transgenic tobaccos from the same position were taken and separately stained with DAB or NBT for 24 h in the dark at 28 • C. The leaves were washed with distilled water to remove DAB or NBT, and repeatedly boiled in 80% ethanol until they were completely decolorized. The leaves were laid on a colorless solid medium for taking photographs. Moreover, ROS in transgenic tobacco was quantified by a colorimetric method using O 2 − and H 2 O 2 content assay kits (Sangon, China).

Statistical Analysis
Statistical analysis was performed as our previous study [31]. A completely randomized block design with at least three biological replicates was applied for each experiment. The data were represented by the mean ± standard deviation from three biological samples, and further analyzed using the SPSS statistical package (version 8.0). The student's t test was used for statistical analysis. * and ** indicated that compared with the control, the difference was statistically significant, p < 0.05 and p < 0.01, respectively.

Identification and Characterization of NtDREB-1BL1
The NtDREB-1BL1 gene was identified from N. tabacum (XM_016632493.1). The molecular weight and isoelectric point of the protein were shown in Table S2. Homologous genes of the NtDREB-1BL1 gene were identified in the N. sylvestris and N. tomentosiformis, which were named as NtomDREB1 and NsyDREB1. The similarity of these three genes was 97.35%, and the similarity of the coding DNA sequences was 96.92%. The NtDREB-1BL1 gene was 99.54% similar to NsyDREB1. NtDREB-1BL1 was rich in hydrophilic amino acid residues, without transmembrane domain. The size of the protein was about 24 kDa. The protein instability coefficient was greater than 40, which indicated that transmembrane domain was necessary for protein stability. The cis-acting element bound by the DNA binding region was DRE/CRT (dehydration responsive element/C-repeat element), and the core sequence was ACCGAC.

Phylogenetic Analysis, Exon-Intron Architecture and Conserved Domains of NtDREB -1BL1
DREB belonged to the AP2/EREBP family and contained only one AP2 domain. Based on the combined analysis of gene annotation and conserved domains, NtDREB without the complete AP2 domain was eliminated. A total of 63 genes with the complete AP2 domains (conserved YRG and RAHD regions) were detected ( Figure 1A). Phylogenetic analysis indicated that the members of the NtDREB family were divided into six subgroups ( Figure 1B). NtDREB-1BL1 was grouped in the A-1 class, containing 16 members. The exon-intron architecture was analyzed by GSDS 2.0 software, indicating that most members of the NtDREB family had no introns.

Expression Pattern and Subcellular Localization of NtDREB-1BL1
Real-time qPCR was used to evaluate the expression level of NtDREB-1BL1 in of leaves, stem, root and flower in N. tabacum. The transcript level was the highest leaves, with the lowest in the flowers (Figure 2A). Additionally, both NaCl and d stress induced the up-regulation of NtDREB-1BL1 in leaves of N. tabacum ( Figure 2B dicted localization of NtDREB-1BL1 by the WoLF PSORT system suggested that Nt 1BL1 was most probably localized in the nucleus. Additionally, the transient prot pression system of Agrobacterium-infected tobacco leaves was used to illustrate Nt 1BL1 localization. The control tobacco leaves was inoculated by Agrobacterium ca Sup1300-GFP empty vector, whose green fluorescence was mainly distributed in toplasm and nucleus. While the green fluorescence signal of NtDREB-1BL1-GFP protein was only visible in the nucleus ( Figure 2C), which was in accordance w expression pattern of the transcription factor and its possible regulatory role.

Expression Pattern and Subcellular Localization of NtDREB-1BL1
Real-time qPCR was used to evaluate the expression level of NtDREB-1BL1 in tissues of leaves, stem, root and flower in N. tabacum. The transcript level was the highest in the leaves, with the lowest in the flowers (Figure 2A). Additionally, both NaCl and drought stress induced the up-regulation of NtDREB-1BL1 in leaves of N. tabacum ( Figure 2B). Predicted localization of NtDREB-1BL1 by the WoLF PSORT system suggested that NtDREB-1BL1 was most probably localized in the nucleus. Additionally, the transient protein expression system of Agrobacterium-infected tobacco leaves was used to illustrate NtDREB-1BL1 localization. The control tobacco leaves was inoculated by Agrobacterium carrying Sup1300-GFP empty vector, whose green fluorescence was mainly distributed in the cytoplasm and nucleus. While the green fluorescence signal of NtDREB-1BL1-GFP fusion protein was only visible in the nucleus ( Figure 2C), which was in accordance with the expression pattern of the transcription factor and its possible regulatory role.

ChIP-qPCR Analysis
The Plant Care software was used to analyze the promoter region of the NtPSY g in N. tabacum, which was divided into 10 segments, and the distribution of cis-acting ments (Table S3) was analyzed. The specific qPCR primers were designed to identify association between transcription factors and its target cis-acting elements. The DNA fr ments obtained in the ChIP experiment were used as substrates to perform qPCR exp ment. As shown in Figure 2D, four fragments containing the binding site of NtDREB-1 in the promoter regions of NtPSY genes were significantly enriched after immunopre itation. Among these four fragments, the relative expression level of the ninth segm was significantly higher than that of other segments ( Figure 2D). The promoters dist uted in ninth segment included CAAT-box, TATA-box and MBS, of which CAAT-box w the common cis-acting element in promoter and enhancer regions, and MBS was an portant element involved in drought induction (Table S3).

Characterization of NtDREB-1BL1 OE and RNAi Transgenic Tobacco
The NtDREB-1BL1 OE transgenic T1 line were obtained ( Figure 3A), and four tra genic T1 lines were selected for further analysis. NtDREB-1BL1 transcripts were sign ChIP enrichment test of the promoter regions bound by NtDREB-1BL1 was examined by ChIP-qPCR. Asterisks represent statistically significant differences between WT and transgenic plants determined by Student's t-test (**, p < 0.01; *, p < 0.05).

ChIP-qPCR Analysis
The Plant Care software was used to analyze the promoter region of the NtPSY gene in N. tabacum, which was divided into 10 segments, and the distribution of cisacting elements (Table S3) was analyzed. The specific qPCR primers were designed to identify the association between transcription factors and its target cis-acting elements. The DNA fragments obtained in the ChIP experiment were used as substrates to perform qPCR experiment. As shown in Figure 2D, four fragments containing the binding site of NtDREB-1BL1 in the promoter regions of NtPSY genes were significantly enriched after immunoprecipitation. Among these four fragments, the relative expression level of the ninth segment was significantly higher than that of other segments ( Figure 2D). The promoters distributed in ninth segment included CAAT-box, TATA-box and MBS, of which CAAT-box was the common cis-acting element in promoter and enhancer regions, and MBS was an important element involved in drought induction (Table S3).

NtDREB-1BL1 Function in Defense against Drought Stress
The WT, NtDREB-1BL1 OE and RNAi transgenic tobacco lines with consistent growth were selected for drought treatment. The leaves of control and NtDREB-1BL1 RNAi tobacco seedlings were withered, whereas the NtDREB-1BL1 OE transgenic seedlings still exhibited healthy condition ( Figure 5A). An analysis of the color of the leaves showed that a more dark brown color appeared in NtDREB-1BL1 RNAi transgenic tobacco after DAB staining compared with the control ( Figure 5B). However, the color of NtDREB-1BL1 OE transgenic tobacco leaves was lighter than control tobacco. A similar phenomenon was also detected after NBT staining. Darker blue staining was detected in NtDREB-1BL1 RNAi transgenic tobacco compared with control, while the blue was lighter in NtDREB-1BL1 OE transgenic leaves. Drought treatment promoted the accumulation of ROS in WT, NtDREB-1BL1 RNAi and OE transgenic tobacco. However, the increase in O2 − and H2O2 was lower in NtDREB-1BL1 OE transgenic lines than WT, which was more in RNAi transgenic lines than WT ( Figure 5C,D). The lower levels of ROS caused by NtDREB-1BL1 indicated that NtDREB-1BL1 conferred enhanced protection from oxidative damage and a better ROS scavenging ability in tobacco.

NtDREB-1BL1 Function in Defense Against Drought Stress
The WT, NtDREB-1BL1 OE and RNAi transgenic tobacco lines with consistent growth were selected for drought treatment. The leaves of control and NtDREB-1BL1 RNAi tobacco seedlings were withered, whereas the NtDREB-1BL1 OE transgenic seedlings still exhibited healthy condition ( Figure 5A). An analysis of the color of the leaves showed that a more dark brown color appeared in NtDREB-1BL1 RNAi transgenic tobacco after DAB staining compared with the control ( Figure 5B). However, the color of NtDREB-1BL1 OE transgenic tobacco leaves was lighter than control tobacco. A similar phenomenon was also detected after NBT staining. Darker blue staining was detected in NtDREB-1BL1 RNAi transgenic tobacco compared with control, while the blue was lighter in NtDREB-1BL1 OE transgenic leaves. Drought treatment promoted the accumulation of ROS in WT, NtDREB-1BL1 RNAi and OE transgenic tobacco. However, the increase in O 2 − and H 2 O 2 was lower in NtDREB-1BL1 OE transgenic lines than WT, which was more in RNAi transgenic lines than WT ( Figure 5C,D). The lower levels of ROS caused by NtDREB-1BL1 indicated that NtDREB-1BL1 conferred enhanced protection from oxidative damage and a better ROS scavenging ability in tobacco. The detailed O2and H2O2 contents in these materials were relatively quantified by the colorimetric method. Asterisks represent statistically significant differences between WT and transgenic plants determined by Student's t-test (*, p < 0.05). [41], O. sativa [42], Z. mays [43,44], and T. aestivum [45], improving the tolerance of plants to low temperature, drought, and high salt. The DREB family plays important roles in the response to abiotic stress. However, knowledge of NtDREB genes is limited. In this study, the NtDREB-1BL1 gene was isolated from N. tabacum. A detailed study of the classification, phylogenetic evolution, gene structure, and expression pattern of these NtDREB-1BL1 in response to drought stress was carried out ( Figure 1). As an unstable hydrophilic protein, NtDREB-1BL1 was located in the nucleus (Figure 2). ChIP-qPCR technology confirmed that the NtDREB-1BL1 could anchor the key segment of the NtPSY promoter (Figure 2), which was a major rate-limiting enzyme of carotenogenesis [46]. Overexpression of NtDREB-1BL1 increased the expression of the NtPSY gene, thereby increasing the expression of genes in the carotenoid synthesis pathway. The contents of chlorophyll a, chlorophyll b, and carotenoid were increased in NtDREB-1BL1 OE transgenic plants, along with the decline in NtDREB-1BL1 RNAi transgenic tobacco (Figures 3 and 4). This suggests that NtDREB-1BL1 has a positive effect on carotenoids biosynthesis, indicating that the NtDREB-1BL1 gene functions as an important transcriptional activator.

DREB transcription factors have been successfully transformed into model plants such as A. thaliana
Drought stress inhibits plant root tip growth, leaf area, biomass accumulation, plant fresh weight and dry weight, causing serious losses to plant growth and development. When plants are subjected to drought and salt stresses, ROS are rapidly produced and accumulated in plant cells, resulting in severe oxidative damage. DREB1A in transgenic wheat participated in the process of plant drought resistance, which improved the drought resistance of transgenic plants [47]. NtDREB-1BL1 was significantly and positively regulated by drought stress (Figure 5). This suggests that NtDREB-1BL1 has role of defending against drought stress. Under drought stress, the ROS content of NtDREB-1BL1 OE transgenic tobacco was lower than that in the control, with the increase in ROS content in NtDREB-1BL1 RNAi transgenic tobacco ( Figure 5). The lower levels of ROS may indicate that NtDREB-1BL1 conferred enhanced protection from oxidative damage and a better ROS scavenging ability in the transgenic plants. It suggested that NtDREB-1BL1 stimulated carotenoid accumulation in N. tabacum, which acted as essential antioxidants to scavenge ROS caused by drought stress. Our research provides a new idea and theoretical Asterisks represent statistically significant differences between WT and transgenic plants determined by Student's t-test (*, p < 0.05).

Discussion
DREB transcription factors have been successfully transformed into model plants such as A. thaliana [41], O. sativa [42], Z. mays [43,44], and T. aestivum [45], improving the tolerance of plants to low temperature, drought, and high salt. The DREB family plays important roles in the response to abiotic stress. However, knowledge of NtDREB genes is limited. In this study, the NtDREB-1BL1 gene was isolated from N. tabacum. A detailed study of the classification, phylogenetic evolution, gene structure, and expression pattern of these NtDREB-1BL1 in response to drought stress was carried out ( Figure 1). As an unstable hydrophilic protein, NtDREB-1BL1 was located in the nucleus (Figure 2). ChIP-qPCR technology confirmed that the NtDREB-1BL1 could anchor the key segment of the NtPSY promoter (Figure 2), which was a major rate-limiting enzyme of carotenogenesis [46]. Overexpression of NtDREB-1BL1 increased the expression of the NtPSY gene, thereby increasing the expression of genes in the carotenoid synthesis pathway. The contents of chlorophyll a, chlorophyll b, and carotenoid were increased in NtDREB-1BL1 OE transgenic plants, along with the decline in NtDREB-1BL1 RNAi transgenic tobacco (Figures 3 and 4). This suggests that NtDREB-1BL1 has a positive effect on carotenoids biosynthesis, indicating that the NtDREB-1BL1 gene functions as an important transcriptional activator.
Drought stress inhibits plant root tip growth, leaf area, biomass accumulation, plant fresh weight and dry weight, causing serious losses to plant growth and development. When plants are subjected to drought and salt stresses, ROS are rapidly produced and accumulated in plant cells, resulting in severe oxidative damage. DREB1A in transgenic wheat participated in the process of plant drought resistance, which improved the drought resistance of transgenic plants [47]. NtDREB-1BL1 was significantly and positively regulated by drought stress (Figure 5). This suggests that NtDREB-1BL1 has role of defending against drought stress. Under drought stress, the ROS content of NtDREB-1BL1 OE transgenic tobacco was lower than that in the control, with the increase in ROS content in NtDREB-1BL1 RNAi transgenic tobacco ( Figure 5). The lower levels of ROS may indicate that NtDREB-1BL1 conferred enhanced protection from oxidative damage and a better ROS scavenging ability in the transgenic plants. It suggested that NtDREB-1BL1 stimulated carotenoid accumulation in N. tabacum, which acted as essential antioxidants to scavenge ROS caused by drought stress. Our research provides a new idea and theoretical basis for the regulation of plant carotenoid biosynthesis. This study was able to provide new ideas and new understandings for the regulation of plant carotenoid biosynthesis.

Conclusions
In conclusion, we summarize NtDREB-1BL1 participates in regulating carotenoids biosynthesis by binding to the NtPSY promoter, which further enhances drought resistance of transgenic plants. Exploring the regulation of carotenoid biosynthesis by NtDREB-1BL1 will provide a new strategy of the genetic regulation of carotenoid content. Overall, our findings provide new insights into the characteristics and potential functions of NtDREB-1BL1 and offer a better understanding of their molecular basis in response to drought stress in N. tabacum.

Data Availability Statement:
The data presented in the study are available in this manuscript.