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Article

Transcriptomic Analysis Provides Insight into the ROS Scavenging System and Regulatory Mechanisms in Atriplex canescens Response to Salinity

by
Shan Feng
,
Beibei Wang
,
Chan Li
,
Huan Guo
and
Ai-Ke Bao
*
State Key Laboratory of Herbage Improvement and Grassland Agro-Ecosystems, Key Laboratory of Grassland Livestock Industry Innovation, Ministry of Agriculture and Rural Affairs, College of Pastoral Agriculture Science and Technology, Lanzhou University, Lanzhou 730020, China
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Int. J. Mol. Sci. 2023, 24(1), 242; https://doi.org/10.3390/ijms24010242
Submission received: 31 October 2022 / Revised: 16 December 2022 / Accepted: 20 December 2022 / Published: 23 December 2022
(This article belongs to the Special Issue Molecular Aspects of Plant Salinity Stress and Tolerance 2.0)
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Abstract

:
Atriplex canescens is a representative halophyte with excellent tolerance to salt. Previous studies have revealed certain physiological mechanisms and detected functional genes associated with salt tolerance. However, knowledge on the ROS scavenging system and regulatory mechanisms in this species when adapting to salinity is limited. Therefore, this study further analyzed the transcriptional changes in genes related to the ROS scavenging system and important regulatory mechanisms in A. canescens under saline conditions using our previous RNA sequencing data. The Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway annotation revealed that the differentially expressed genes (DEGs) were highly enriched in signal transduction- and reactive oxygen species-related biological processes, including “response to oxidative stress”, “oxidoreductase activity”, “protein kinase activity”, “transcription factor activity”, and “plant hormone signal transduction”. Further analyses suggested that the transcription abundance of many genes involved in SOD, the AsA-GSH cycle, the GPX pathway, PrxR/Trx, and the flavonoid biosynthesis pathway were obviously enhanced. These pathways are favorable for scavenging excessive ROS induced by salt and maintaining the integrity of the cell membrane. Meanwhile, many vital transcription factor genes (WRKY, MYB, ZF, HSF, DREB, and NAC) exhibited increased transcripts, which is conducive to dealing with saline conditions by regulating downstream salt-responsive genes. Furthermore, a larger number of genes encoding protein kinases (RLK, CDPK, MAPK, and CTR1) were significantly induced by saline conditions, which is beneficial to the reception/transduction of salt-related signals. This study describes the abundant genetic resources for enhancing the salt tolerance in salt-sensitive plants, especially in forages and crops.

1. Introduction

Salinity is an adverse abiotic stress that impairs the growth and development in plants, restricting the production and quality of crops and endangering the ecological environment [1,2]. Approximately one-fifth of cultivated land and one-half of irrigated land have been affected by salinization worldwide [3]. Introducing novel exogenous genes or altering the expression levels of endogenous genes is necessary to enhance the salt tolerance of plants [4]. Halophytic species growing in saline lands over a long time have developed multiple strategies to adapt to salt [1,3,5]. Accordingly, identifying the important genes and analyzing the regulatory mechanisms for salt tolerance in these species are key premises [3,6].
Atriplex canescens, a C4 semi-evergreen shrub with a strong tolerance to salt and drought stresses, is widely distributed in saline and arid regions [7]. It is used to reclaim marginal lands and is also an excellent forage for many livestock [8,9,10]. Our previous study has indicated that the addition of 100 mM NaCl (moderate salinity) could stimulate the growth of A. canescens, and its seedlings still maintained a certain degree of growth under 400 mM NaCl (high salinity) treatment [9]. Further physiological studies have revealed that a high capacity for photosynthesis, osmotic adjustment, and Na+/K+ homeostasis were the primary reasons for the salt tolerance of A. canescens [9]. According to these results, we generated transcriptome datasets of the roots and leaves of A. canescens to identify the important candidate genes underlying the above physiological mechanisms. We mainly focused on the differentially expressed genes (DEGs) related to ion transport, organic osmolyte accumulation, water transport, and photosynthesis [11,12]. However, salt tolerance is a complex trait involving various biochemical and physiological mechanisms, and is controlled by multiple genes. In addition to the abovementioned functional genes, the genes involved in mechanisms, such as the antioxidant systems and signaling regulatory networks, play essential roles in the response of plants to soil salinity [13,14].
The level of reactive oxygen species (ROS) in plants is low under normal growth conditions, but it increases significantly under stress conditions [15]. Numerous studies have shown that salt stress can cause ionic stress and osmotic stress in plant cells, which further results in the production of ROS [16]. High levels of ROS in plant cells trigger programmed cell death [17]. In order to maintain the balance between ROS production and scavenging, plants have developed a complex ROS scavenging system including enzymatic and non-enzymatic (antioxidants) systems [18]. Non-enzymatic systems, such as glutathione, carotenoids and phenolics, react directly with ROS by scavenging them. Enzymatic systems include superoxide dismutase, peroxidase, and catalase, which can eliminate superoxide and hydrogen peroxide [18]. It has been reported that flavonoids are the major non-enzymatic antioxidant produced in the stressed plant, and they have the ability to scavenge ROS molecules such as superoxide, hydroxyl radicals, and hydrogen peroxide (H2O2) [19]. Although studies have indicated that the high ROS scavenging capacity is also a considerable physiological trait of strong salt tolerance in A. canescens [20], the potential molecular basis has not yet been explored.
On the other hand, previous studies have reported that some genes are responsible for the reception/transduction of salt-related signals in plants and the regulation of downstream stress-responsive genes [4,21]. They include genes encoding various transcription factors (TFs), protein kinases, and ubiquitin-mediated proteolysis machinery [22]. However, previous studies on the molecular basis of salt tolerance in plants have mainly focused on the salt tolerance mechanisms of the model plant Arabidopsis and conventional crops [23]. Halophytes have evolved many unique strategies for adaptation to saline environments and may contain superior stress-resistant genes [2]. Nevertheless, knowledge on the regulatory mechanisms for A. canescens’ salt tolerance is also limited. Thus, the screening and identifying of genes related to its adversity response regulatory network is of great significance for comprehensively elucidating the mechanism of this species in adapting to a salty environment and improving the salt tolerance of crops.
Therefore, to obtain a more complete picture of the molecular mechanisms for adapting to salinity in A. canescens, we further analyzed the DEGs related to ROS scavenging, transcription factors, and protein kinases by using the previous transcriptome data from A. canescens leaves and roots under 100 mM NaCl treatment. Finally, candidate genes were selected and qRT-PCR was used to verify the expression pattern.

2. Results

2.1. Transcriptome Profile of Leaves and Roots under NaCl Treatments

To learn more about how A. canescens adapts to a saline environment, we further analyzed the transcriptome data of the leaves and roots of seedlings treated with 100 mM NaCl treatments for 6 and 24 h [12]. The method of determining the DEGs was as described above. A total of 36,800 DEGs (CL6-vs-SL6, CL24-vs-SL24, CR6-vs-SR6, and CR24-vs-SR24) were identified in four comparisons: ‘C’ and ‘S’ denote the control group and salt treatment group, respectively; ‘L’ and ‘R’ denote the leaves and roots of seedlings, respectively, and ‘6’ and ‘24’ denote treatment for 6 and 24 h, respectively [12]. According to the Venn diagram, 4506 and 6128 DEGs were specifically expressed in the leaves and roots at 6 h, while 10,178 DEGs at 6 h showed overlapping expression in both the leaves and roots, indicating that signal pathways controlling these responses in A. canescens were interacting in different tissues (Figure 1A). Similarly, there were 2728 and 1730 DEGs specifically expressed in the leaves and roots at 24 h, while 675 DEGs showed overlapping expression in both the leaves and roots (Figure 1B). Overall, the results demonstrated that the number of DEGs at 6 h after NaCl treatment was significantly higher than at 24 h, indicating that the regulatory genes may be more complicated at an earlier time point.

2.2. Functional Analysis of DEGs

To study the biological pathways and molecular functions of DEGs in A. canescens under salt treatments, we performed a functional enrichment analysis for the GO and KEGG pathways in the DEGs at each time point for CL vs. SL and CR vs. SR. The GO annotation indicated that the DEGs at different stages and in different organs were enriched in many biological processes, cellular components, and molecular functions. At 6 h in the leaves and roots, the genes related to ROS functions were enriched among the DEGs (e.g., “response to oxidative stress”, “oxidoreductase activity”, “response to oxygen-containing compound”, and “oxidation-reduction process”) (Figure 2A,B). In particular, the biological processes related to “carotenoid metabolic process”, “carotenoid biosynthetic process”, “response to reactive oxygen species”, and “response to stimulus” were significantly enriched in DEGs at 6 h (Figure 2A). In addition, the molecular functions “oxidoreductase activity, acting on the CH-OH group of donors, oxygen as acceptor”, “peroxidase activity”, and “antioxidant activity” were enriched at 6 h in both the leaves and roots (Figure 2B, Tables S1 and S2). At 24 h, the terms “response to stimulus”, “cell communication”, “signal transduction”, “regulation of biological process”, and “biological regulation” were only significantly enriched in the leaves (Figure 3A), while “metabolic process”, “cellular metabolic process”, “biosynthetic process”, and “protein metabolic process” were obviously enriched in the roots (Figure 3A). In addition, the molecular functions “kinase activity”, “protein kinase activity”, “calcium ion binding”, and “peroxidase activity” were enriched in the leaves, and “signaling receptor activity”, “lyase activity”, and “acetyltransferase activity” were significantly enriched in the roots (Figure 3B, Tables S5 and S6). The above results indicated that ROS metabolism and regulatory genes may play crucial roles in A. canescens’ response to salt stress.
For the KEGG pathway, 129, 129, 123, and 123 pathways were identified from the pairwise comparisons between CL6-vs-SL6, CR6-vs-SR6, CL24-vs-SL24, and CR24-vs-SR24, respectively. Based on the ranking of the top 30 pathways, “phenylpropanoid biosynthesis”, “plant hormone signal transduction”, “carotenoid biosynthesis”, and “glutathione metabolism” were significantly enriched in CL6-vs-SL6 and CR6-vs-SR6 (Figure 2C,D, Tables S3 and S4). In addition, “glycosaminoglycan degradation”, “peroxisome”, “glycerophospholipid metabolism”, and “arachidonic acid metabolism” were significantly enriched in CL24-vs-SL24 and CR24-vs-SR24 (Figure 3C,D, Tables S7 and S8). These results demonstrated that salt treatment significantly induced the expression of genes involved in stress response production.

2.3. DEGs Involved in the ROS Scavenging System

The ascorbate-glutathione (AsA-GSH) cycle, the glutathione peroxidase (GPX) pathway, the catalase (CAT) pathway, the peroxiredoxin/thioredoxin (PrxR/Trx) pathway, and superoxide dismutase (SOD) together constitute the ROS scavenging system of plants [24]. This powerful ROS scavenging system is one of the vital physiological traits of strong salt tolerance in A. canescens [22]. In this study, the related DEGs to the ROS scavenging system were first analyzed in A. canescens leaves and roots after 100 mM NaCl treatment. There were 91 and 45 upregulated DEGs as well as 49 and 30 downregulated DEGs related to the ROS scavenging system in leaves when A. canescens seedlings were treated with 100 mM NaCl for 6 and 24 h, respectively (Figure 4A,B, Figure S1A,B). In the four ROS scavenging pathways, GST genes were found to be involved in both the GPX pathway and the ASA-GSH pathway [25]. When plants were treated for 6 h, among the 91 upregulated DEGs, twenty-two, seventy-four, six, and four genes were classified into the AsA-GSH cycle, GPX pathway, CAT pathway, and PrxR/Trx pathway (Table S9), respectively. Moreover, up to one-third of the upregulated DEGs showed no expression under control conditions, including six GSTs, two GPXs, fourteen PODs, five GLPs, one CAT, two PEXs, and one SOD (Table 1). After seedlings were treated with 100 mM NaCl for 24 h, the upregulated DEGs were still mostly categorized into the AsA-GSH pathway (27 genes) and GPX pathway (35 genes) (Table S10), indicating that these two pathways might be important components of the ROS scavenging system in the adaptation to saline conditions in A. canescens leaves. Moreover, the expression of one GLR, one APX, four GSTs, two GPXs, seven PODs, two GLPs, and one PEX were significantly induced by salt treatment for 24 h, while they exhibited no expression in control seedlings (Table 2). Further analysis suggested that most of the upregulated DEGs were GLP, POD, and GST genes after salt treatment for 6 and 24 h (Figure 4A,B). More importantly, 18 DEGs were upregulated under salt treatment for both 6 and 24 h in leaves, and most of them were POD and GST genes; in particular, one POD (Unigene6725_All) and one GLP (Unigene5013_All) were almost never expressed under control conditions (Table 3).
After treatment with 100 mM NaCl for 6 h, the number of upregulated DEGs was lower than that of downregulated DEGs in the roots of A. canescens (Figure 4C). There were 65 upregulated DEGs, of which 14, 14, 15, and 21 genes belonged to the AsA-GSH cycle, GPX pathway, CAT pathway, and PrxR/Trx pathway, respectively, indicating that the PrxR/Trx pathway might be the primary means for A. canescens roots to adapt to salinity in the early period (Table S11, Figure S2A,B). The above upregulated DEGs included several genes encoding SOD, such as two Fe-SODs (CL5119.Contig3_All and Unigene5793_All) and three Cu/Zn-SODs (CL1360.Contig2_All, CL2699.Contig2_All, and Unigene3542_All) (Table S11). In addition, the upregulated DEGs included one GLR, two APXs, two GSTs, and one SOD, which were rarely expressed in control plants (Table 4). After salt treatment for 24 h, the number of upregulated genes was almost equal to that of downregulated genes in the roots of A. canescens seedlings (Figure 4C,D). There were 29 upregulated DEGs after salt treatment for 24 h, and most of them were mainly categorized into the AsA-GSH cycle and GPX pathway, indicating that the two pathways likely play important roles in adaptation to salinity in A. canescens roots over a long period (Table S12). There were two GPX, one GLP, and one SOD induced by salt treatment for 24 h, and the transcript abundance of these genes was not exhibited in control seedlings (Table 5). Furthermore, the greatest number of upregulated DEGs were Trxs in A. canescens roots under salt treatment for both 6 and 24 h (Figure 4C,D). Additionally, four DEGs were upregulated under salt treatment for both 6 and 24 h in roots, including one GLR, one GST, and two Trxs, indicating that these genes might take part in scavenging ROS in A. canescens roots under saline conditions (Table 6).
Flavonoids play a positive role in the ROS scavenging and stress signal transmission in plants [26]. In total, there were 43 upregulated DEGs and 32 downregulated DEGs categorized into the flavonoid synthesis pathway in the leaves under 100 mM NaCl for 6 h (Figure 5A). In addition, approximately a quarter of the upregulated DEGs exhibited no expression under control conditions, including one flavonol synthase (FLS), four chalcone synthase (CHS), one chalcone isomerase (CHI), one dihydroflavonol-4-reductase (DFR), and seven flavonoid 3-O-glucosyltransferase (FLG) (Table 7). After seedlings were treated with 100 mM NaCl for 24 h, a total of twenty-two upregulated and nine downregulated DEGs were found in the leaves (Figure 5B), and among the upregulated DEGs, seven showed no expression under control conditions, but were significantly induced by salt treatment for 24 h, including two flavonoid 3-O-glucosyltransferase (FLG), three chalcone synthase (CHS), one cinnamate 4-hydroxylase (C4H), and one flavanone 3-hydroxylase (F3H) (Table 8). Moreover, under 100 mM NaCl treatment, 30 upregulated DEGs and 49 downregulated DEGs were identified in the roots of A. canescens at 6 h (Figure 5C), including two flavonoid 3-O-glucosyltransferase (FLG), three dihydroflavonol-4-reductase (DFR), and one flavonol synthase (FLS), which were upregulated in the roots of plants but almost not expressed under control conditions (Table 9). In addition, there were three cinnamate 4-hydroxylase (C4H) and one phenylalanine ammonia-lyase (PAL) with downregulated expression at 6 h after 100 mM NaCl treatment. When plants were treated for 24 h, a total of 20 upregulated DEGs were identified (Figure 5D), including nine flavonoid 3-O-glucosyltransferase (FLG), three dihydroflavonol-4-reductase (DFR), two flavanone 3-hydroxylase (F3H), one cinnamate 4-hydroxylase (C4H), two flavonol synthase (FLS), two chalcone synthase (CHS), and one chalcone isomerase (CHI). Additionally, the transcript abundance of four flavonoid 3-O-glucosyltransferase (FLG), one dihydroflavonol-4-reductase (DFR), one chalcone isomerase (CHI), and one chalcone synthase (CHS) were not expressed in control conditions but were significantly upregulated in the roots of A. canescens after 100 mM NaCl treatment for 24 h (Table 10).

2.4. DEGs Related to Transcription Factors

The DEGs of the leaves and roots related to TFs in A. canescens after salt treatment were found to mainly belong to nine gene families: NAC (no apical meristem/Arabidopsis transcription activation factor/cup-shaped cotyledon), AP2/ERF (APETALA2 and ethylene-responsive element binding proteins), bHLH (basic helix-loop-helix), MYB (myeloblastosis), WRKY (WRKY-domain protein), ZF (zinc finger), HSF (heat shock transcription factor), bZIP (basic region-leucine zip-per/homeodomain-leucine zipper), and MAD box (Figure 6). TFs can respond rapidly to salt stress, and we mainly analyzed the DEGs of the leaves and roots related to the above TFs in A. canescens at 6 h.
In A. canescens leaves, as many as 286 TF genes were differentially expressed after exposure to 100 mM NaCl for 6 h, including 226 upregulated DEGs and 60 downregulated DEGs (Figure 6A; Figure S3A). The transcripts predicted to encode WRKY1, WRKY20, WRKY56, and NAC29 were identified as upregulated, which were proved to play definite and key roles in plant salt tolerance (CL3186.Contig1_All, Unigene6298_All, Unigene1538_All, and Unigene3810, respectively) (Table S13). The largest proportion of upregulated DEGs were ZFs, containing some C2H2-type ZFs (CL647.Contig3_All, CL7175.Contig1_All, Unigene1480_All, and Unigene251_All) (Figure 6A, Table S13). DREBs (dehydration-responsive element binding proteins) belonged to the subfamily of AP2/ERF TFs [27]. Although few DREBs were identified in A. canescens leaves after salt treatment for 6 h, all of them were upregulated, including two DREB2As (CL5907.Contig1_All and Unigene3588_All) (Figure 6A; Table S13). Moreover, the transcript abundance of five WRKYs, seven MYBs, four bZIPs, three AP2/ERFs, one NAC, seven bHLHs, three MADS-boxes, one ZF, and two HSFs exhibited significant upregulations which were not found in control plants; most of them were MYB proteins, particularly MYB12 (Table 11). In addition, the transcription of six MADS-boxes was considerably induced by salt treatment, indicating their possible involvement in the process of salt adaptation in A. canescens leaves (Table S13).
In A. canescens roots, there were 53 upregulated DEGs and 292 downregulated DEGs associated with TFs when the plants were treated with 100 mM NaCl for 6 h (Figure 6B; Figure S3B). In general, the number of upregulated DEGs in the roots was much lower than those in the leaves of A. canescens, probably indicating that the TFs in A. canescens leaves play a more prominent role in its adaptation to saline conditions (Figure 6, Table S14). The transcripts for one MYB, three bZIP, five ZF, one bHLH, one MADS-box, and one HSF genes showed no expression in control seedlings but were still significantly induced by salt, implying their important functions in A. canescens handling of saline conditions (Table 12). For instance, the transcript level of HsfA2 (CL3871.Contig2_All) was upregulated more than 7-fold under 100 mM NaCl treatment, but its transcript was not found in control plants (Table 12).

2.5. DEGs Involved in Protein Kinases

Among protein kinases, RLKs (receptor-like protein kinases) are the main classes involved in signal perception, including LRR-RLKs (leucine-rich repeat receptor-like kinases), WAKs (cell wall-associated kinases), LecRLKs (lectin-domain-containing receptor kinases), and RLCKs (receptor-like cytoplasmic kinases) [28]. Moreover, CDPKs (calcium-dependent protein kinases) and MAPKs (mitogen-activated protein kinases) are also main classes of protein kinases, which are primarily responsible for signal transduction [25]. Therefore, the DEGs of leaves and roots related to protein kinases in A. canescens under 100 mM NaCl at 6 and 24 h were analyzed.
In leaves, up to 265 DEGs associated with protein kinases were identified, of which the number of upregulated DEGs was more than 2.5-fold larger than that of downregulated DEGs when A. canescens seedlings were treated with 100 mM NaCl for 6 h (Figure 7A, Figure S4A). In particular, 46 upregulated DEGs showed no expression in the control plants, including eleven RLKs, five WAKs, seven LecPLKs, nineteen LRR-RLKs, one MAPK, one LysM, and one casein kinase (Table 13). After treatment with 100 mM NaCl for 24 h, there were 82 upregulated DEGs and 57 downregulated DEGs related to protein kinases in A. canescens leaves (Figure 7A, Figure S4B). Among them, the transcripts levels of 23 genes were obviously upregulated under NaCl treatment but not under control conditions, and most of them were LRR-RLKs, LecPLKs, other RLKs, and WAKs (Table 14). A large proportion of the upregulated DEGs were genes predicted to encode LRR-RLK, LecRLK, RLK, and WAK proteins under salt treatment for 6 and 24 h (Figure 7A,B). Furthermore, several upregulated genes encoding different RLKs with definite roles in plant salt tolerance were found after salt treatment for either 6 or 24 h. Examples include one FERRONIA (Unigene13978_All), one RLK1 (CL3313.Contig6_All), and two CLAVATA1s (Unigene7507_All and Unigene12732_All) (Tables S15 and S16).
In the roots, there were 59 upregulated DEGs and 49 downregulated DEGs at 6 h after salt treatment in A. canescens seedlings (Figure 7A, Figure S5A). Some of them were not identified in control plants but showed substantial upregulation after salt treatment, such as one RLK, five WAKs, seven LecRLKs, eight LRR-RLKs, two MAPKs, one Casein, and, especially, five RLK1s (Table 15). Compared with salt treatment for 6 h, under treatment with salt for 24 h the number of DEGs was sharply increased, of which 73 DEGs were upregulated and 247 DEGs were downregulated (Figure S5B). In particular, the transcript levels of two other RLKs, five WAKs, four LecRLKs, six LRR-RLKs, and two CDPKs were evidently induced by salt, while they showed no expression under control conditions (Table 16). Then, we compared DEGs in the leaves and roots of A. canescens under saline conditions. The results suggested that the number of genes encoding LRR-RLK was the highest under salt treatment for 6 and 24 h whether in A. canescens leaves or roots, and many of them were not expressed in control plants (Figure 7, Table 13, Table 14, Table 15, Table 16 and Table 17). Moreover, many transcripts of MAPK- and CDPK-encoding DEGs were induced by salt treatment in A. canescens leaves and roots (Figure 7). One transcript encoding CTR1 (CONSTITUTIVE TRIPLE RE-SPONSE1, CL4515.Contig1_All) was downregulated in both the leaves and roots of A. canescens under salt treatment for 24 h (Tables S17 and S18). In addition, several LysM and casein-encoding genes that were not previously reported to be involved in abiotic stress were also found to be upregulated in A. canescens leaves and roots under salt treatment (Figure 7).

2.6. Validation of Sequencing Data by Quantitative Real-Time PCR

To check the reproducibility of the RNA-seq results used in this study, seven DEGs were randomly selected from the leaves and roots of A. canescens to subsequently conduct random quantitative real-time PCR analysis. The results indicated that the fold changes in the relative expression of genes measured by quantitative reverse transcription polymerase chain reaction (qRT-PCR) were basically in agreement with the corresponding transcription abundance changes in the RNA-seq value (Table S19). Meanwhile, the linear regression analysis of the fold changes between the RNA-seq and qRT-PCR results exhibited a high positive correlation, with R2 = 0.8718 in leaves and R2 = 0.9036 in roots under 100 mM NaCl for 6 h (Figure 8), indicating the reliability of the RNA-seq profiling data.

3. Discussion

Soil salinity is a global issue threatening plant growth [29]. Plants can regulate their growth in many ways to adapt to stress conditions, such as regulation of ion balance, phytohormone signaling, and the cell wall [30]. According to our previous study, a total of 36,800 DEGs were identified in four groups (CL6-vs-SL6, CR6-vs-SR6, CL24-vs-SL24, and CR24-vs-SR24), and more genes were activated efficiently in the roots and leaves at 6 h compared with 24 h of treatment to cope with salinity in A. canescens. Moreover, the genes related to ion transport, organic osmolyte accumulation, water transport, and photosynthesis had significant transcriptional changes in A. canescens under salt treatment [12]. To more comprehensively understand the potential molecular mechanisms of A. canescens for adapting to salinity, we analyzed the previous transcriptome data of leaves and roots in A. canescens. Functional analysis indicated that DEGs in the leaves and roots at 6 h were mainly involved in biological processes such as “response to oxidative stress”, “oxidoreductase activity”, “response to oxygen-containing compound”, and “oxidation-reduction process”, while DEGs mainly took part in “signal transduction”, “protein kinase activity”, and “cell communication processes” at 24 h. Given the importance of the ROS scavenging system and regulatory genes in plant responses to abiotic stress [31], we mainly focused on the ROS, TF, protein kinases, and related signaling pathways in the DEG analysis.

3.1. ROS Scavenging Systems Are Important for the Adaptation of A. canescens to Salinity

Saline conditions lead to ROS overproduction and subsequent oxidative stress and membrane damage in plant cells. Fortunately, plants can reduce these negative effects caused by accumulation of excessive ROS via activating efficient antioxidative defense mechanisms [32]. A previous study demonstrated that the increased activity of a variety of scavengers, including SOD, POD, and CAT, is a crucial strategy in adapting to saline conditions in A. canescens [20]. In the present study, many DEGs related to the ROS scavenging system were upregulated in A. canescens leaves and roots after 6 and 24 h of salt treatment, suggesting that A. canescens possesses a powerful antioxidative ability to reduce the harm triggered by ROS under 100 mM NaCl treatment. SOD acts as the first line of defense against elevated levels of ROS, taking the lead in converting superoxide anion radicals into oxygen and hydrogen peroxide (H2O2) [32]. In general, SODs can be classified into three types by their metal cofactors: copper/zinc (Cu/Zn-SOD), manganese (Mn-SOD), and iron (Fe-SOD) [33]. The activities of multiple SODs showed a significant increase when plants were exposed to saline conditions, and overexpression of several Cu/Zn-SOD and Mn-SOD genes were demonstrated to improve the salt tolerance of various plant species, such as Nicotiana tabacum, Oryza sativa, and Arabidopsis, hinting at their vital roles in plant abiotic stress [34,35,36]. In the present study, we found that the upregulation of several SOD-encoding genes might reduce the harmful effect of ROS in a saline environment in A. canescens. After the action of SOD, free oxygen radicals and hydrogen peroxide are subsequently scavenged by the AsA-GSH cycle, GPX pathway, CAT pathway, and the PrxR/Trx pathway [32]. Among all the antioxidant enzymes, the turnover rate of CAT in converting H2O2 into H2O and O2 was the highest in plant cells [37,38]. In this study, the transcript levels of three genes encoding CAT (CL9179.Contig1_All, CL9309.Contig1_All, and CL9179.Contig2_All) were increased in A. canescens leaves under salt treatment for either 6 or 24 h, implying that these genes might regulate the ROS homeostasis in A. canescens’ response to salt treatment. GSH functions as a redox sensor and plays a vital role in maintaining lower levels of ROS. However, only when GSH is catalyzed by GST can it be used as an antioxidant [32,39]. Meanwhile, overexpression of the GST/GPX gene reduced oxidative damage in transgenic tobacco seedlings under salt treatment by increasing GSH-dependent peroxide scavenging and altering the metabolism of GSH and ASH. The above results indicated that GST might have a significant function in plant salt tolerance [40]. The present study found that many transcripts of GST in A. canescens were induced by salt, implying that these genes may play important roles in the adaptation to salinity of A. canescens, helped by GSH-dependent peroxide scavenging and metabolism of GSH and ASH. Trx is a vital member of the PrxR/Trx pathway, coupling with Prx to scavenge H2O2 [41,42]. It not only acts as an ROS scavenger but also as a vital regulator through protein–protein interactions in response to oxidative stress [24,43]. In our study, the significantly enhanced transcription level of many Trxs implies their essential roles in maintaining ROS homeostasis in A. canescens under salt treatment. PrxR is another key member of the PrxR/Trx pathway; interestingly, under 100 mM NaCl treatment, the genes encoding PrxR were merely expressed after 6 h salt treatment, but almost not at all after 24 h salt treatment, whether in the leaves or roots, indicating that PrxRs mainly contributed to reducing ROS during the short-term salt treatment of A. canescens. In addition, compared with the control, the enzyme activities of MDA, SOD, and POD in A. canescens seedlings were increased under salt stress [20].
In order to respond rapidly to stress conditions, plants have also developed non-enzymatic (antioxidant) systems in addition to the above enzymatic systems [18]. Flavonoids act as the major non-enzymatic antioxidants, becoming the secondary ROS scavenging system in plants suffering from severe stress conditions [44]. A high level of flavonoids can enhance the tolerance to abiotic stresses by inhibiting the ROS-producing enzyme and recycling several antioxidants [19]. The pathway of flavonoid biosynthesis is a deeply studied metabolic pathway, and the chalcone synthase (CHS) and chalcone isomerase (CHI) have been found to be the key enzymes of the flavonoid biosynthesis pathway. CHS was the entry point of the flavonoid pathway and catalyzed 4-Coumaroy-CoA and Malonlyl-CoA to chalcone, leading the phenylpropanoid pathway to flavonoid biosynthesis. Furthermore, CHI catalyzed chalcone to flavanone, which was further transformed into many other enzymes such as isoflavone synthase (IFS), flavanone 3-hydroxyalse (F3H), and flavonol synthase (FLS) [45]. Several key genes related to flavonoid biosynthesis, such as CHS, CHI, F3H, and FLS, were proved to enhance the accumulation of flavonoids under salt and drought stress in some plants [46]. In the present study, 11 flavonoid biosynthesis-related genes (e.g., FLS, CHI, CHS, and F3H) were identified from the transcriptome data, and most of them were markedly upregulated in the leaves and roots of A. canescens after salt treatment, indicating that A. canescens may enhance its antioxidant system by facilitating the accumulation of flavonoids. However, the role of flavonoids in the salt tolerance of A. canescens remains to be confirmed in the future.

3.2. Transcription Factors Play Significant Roles in A. canescens Response to Salt Stress by Regulating Salt Responsive Genes

TFs are vital regulators at the transcriptional level, which can directly activate or repress downstream genes by interacting with the specific cis-elements of their promoter region [47]. A series of TF proteins were found to play critical roles in plant salt tolerance. The WRKY family is the largest family of TFs in plants, and many of them allow plants to endure saline conditions by means of effecting multiple approaches [48]. For instance, overexpression of Reaumuria trigyna WRKY1 in Arabidopsis activated a wide range of functional genes related to the antioxidant system, proline biosynthesis, osmotic balance, and ion transport, such as AtAPX1, AtCAT1, AtSOD1, AtP5CS1, AtP5CS2, AtPRODH1, AtPRODH2, and AtSOS1, thus enhancing plant salt tolerance [49]. Similarly, the salt tolerance of transgenic plants was enhanced when GsWRKY20 and PsWRKY56 were overexpressed by regulating Na+/K+ homeostasis, osmoregulation, and antioxidant capacity [50,51]. In our study, the upregulation of A. canescens WRKY1, WRKY20, and WRKY56 in leaves under salt treatment likely played indispensable roles in the salt adaptation process of A. canescens by mediating the regulation of stress-related genes involved in ion transport, antioxidants, and synthesis of free proline and soluble sugars. MYB proteins were also demonstrated to be key regulators in plant response to abiotic stress; MYB12 conferred salt tolerance in A. thaliana by upregulating genes associated with flavonoid biosynthesis, abscisic acid (ABA) biosynthesis, proline biosynthesis, and ROS scavenging [52]. In the present study, the significant upregulation of MYB12 likely played a crucial role in adaptation to salt in A. canescens by controlling the expression of genes related to flavonoid biosynthesis, ABA biosynthesis, proline biosynthesis, and ROS scavenging. In addition to the above WRKY and MYB genes, other less studied WRKYs and MYBs were also obviously upregulated, such as WRKY72, WRKY53, and MYB48, suggesting that these genes might also play key and novel roles in A. canescens’ salt response. C2H2-type zinc finger ZFs were also identified as important regulators in plant response to salt stress, because their promoter sequence contains many stress-related cis-acting elements [53]. In this study, the upregulation of several C2H2-type ZFs under saline conditions in A. canescens leaves suggests their possible roles in the transcriptional regulatory network in the salt-induced adaptation of A. canescens. Previous research has demonstrated that HSPs act as protein chaperones to alleviate the harm caused by multiple abiotic stresses in plants [54,55]. In particular, it was reported that AtHsfA2 overexpression in Arabidopsis improved seedling salt tolerance [56]. In our data, the expression of a HsfA2 was substantially upregulated under saline conditions in A. canescens roots, suggesting that the gene might be a key member of the regulatory network responding to salinity shock for A. canescens, because of its role as a protein chaperone. DREB-type TFs can be classified into two major subgroups: DREB1/C repeat binding factor (DREB1/CBF) and DREB2; of these, DREB2 genes, especially DREB2As, were found to play a pivotal role in plant response to abiotic stress, including salt stress [4]. In this study, three transcripts of genes encoding DREB2A were induced by salt treatment of the leaves of A. canescens, implying the important roles of these genes in salt tolerance of A. canescens. In addition to the above TFs, NACs are also key genes in a plants’ adaptation to saline environments, especially NAC29, whose overexpression has been reported to enhance the salt tolerance of Arabidopsis by boosting the activity of antioxidant enzymes, including SOD and CAT [57,58]. The present study found that the transcription abundance of A. canescens NAC29 was increased in leaves, suggesting that AcNAC29 might influence A. canescens’ salt tolerance through controlling the ROS scavenging capacity. The above results suggested that A. canescens has evolved a strong transcriptional regulatory network when encountering a saline environment, thus enhancing its ability to adapt to salinity.

3.3. Protein Kinases Are Crucial in the Response to Salt of A. canescens

Currently, it is generally accepted that the transmission of stress-related signaling pathways is divided into three steps: signal perception, signal transduction, and stress-responsive gene expression [47,59]. In the above process, protein kinases control the perception and transduction of stress-related signals, many of which are key factors in plants’ response to stress [60]. Many RLKs, the largest gene family in protein kinases, were demonstrated to be important nodes in a variety of pathways of abiotic stresses [61]. For instance, recent research has indicated that overexpression of the receptor-like kinase FERONIA (FER), an RLK member in the CrRLK subfamily in Arabidopsis, improved plants’ salt tolerance by interacting with ABI2-type and other ABI2-like phosphatases [62]. Meanwhile, under saline conditions, Antarctic moss Pohlia nutans PnRLK 1, a LecRLK gene, increased sensitivity to ABA and reduced ROS accumulation in plants, ultimately reducing the harm caused by salt stress [63]. In our data, the expression levels of several transcripts for FER and RLK1 were increased under 100 mM NaCl treatment in A. canescens leaves or roots, suggesting that these genes likely play an important role in the process of salt adaptation in A. canescens by regulating the ABA-related signal or activity of ROS scavenging. Additionally, research has shown that Glycine max NARK, a homolog to A. thaliana CLAVATA1, participates in a plant’s salt tolerance as a result of its effect on the transcription abundance of some ABA response genes [64]. In the present study, the transcripts of two CLAVATA1s were upregulated in the leaves under salt treatment in A. canescens, indicating that the two genes might confer salt tolerance on A. canescens through the regulation of the ABA-dependent pathway. In addition to RLK genes, other protein kinases are involved in the perception of stress signals in plants. For instance, CTR1 is a negative regulator of the gaseous hormone ethylene (ET) signaling, attributed to the involvement of proteasome-mediated degradation in key signaling components in ET. In particular, the knockout mutant ctr1 increased the ability to tolerate salt, implying a negative correlation between CTR and plant salt tolerance [65]. In the current study, the transcription abundance of one CTR1 was downregulated in A. canescens leaves and roots, indicating that the gene might also be a key factor in the salt adaptation of A. canescens by negatively regulating ET signaling. In the process of stress-related signal transduction, CDPK and MAPK are important participants and regulators [24]. Some CDPK genes alter plant salt tolerance, such as CDPK6, whose overexpression lines in Arabidopsis exhibited stronger tolerance to salt than wild-type [66,67]. MAPK pathways were also highly related to plant salt stress response. For example, a stronger capacity for coping with saline conditions emerged in Oryza sativa MAPK5 and MAPK44-overexpressing lines compared with wild-type [68]. The present data illustrated that the transcript levels of many MAPK and CDPK genes were upregulated in salt-treated A. canescens seedlings, implying the important roles of MAPK and CDPK in signaling transduction in A. canescens under saline conditions. In addition, the transcripts of numerous protein kinases with uncertain roles in plant salt tolerance were also upregulated, suggesting that these genes might play novel and key roles in the mechanisms of A. canescens’ salt tolerance. These results indicated that A. canescens has developed an effective signal perception and transduction pathway when confronting saline environments.

4. Materials and Methods

4.1. Data Acquisition and Differentially Expressed Genes Analysis

Seeds of A. canescens were collected from plants cultivated in Lingwu County (37°78′ N, 106°25′ E; elevation 1250 m) in Ningxia Autonomous Region, China. Germination and cultivation of seedlings were carried out according to previous methods [9]. Four-week-old seedlings were divided into two groups and irrigated by the following solutions: (i) control group: 1/2 Hoagland nutrient solution; and (ii) salt treatment: 1/2 Hoagland nutrient solution with 100 mM NaCl added [12]. Data from transcriptomic analysis and eight independent gene expression libraries (CL6, SL6, CL24, SL24, CR6, SR6, CR24, and SR24) used in this study were generated as described previously [12]. In eight libraries, ‘C’ and ‘S’ denotes the control group and salt treatment group, respectively; ‘L’ and ‘R’, denote leaves and roots of seedlings, respectively, and ‘6’ and ‘24’ denote treatment for 6 and 24 h, respectively [12]. Equal amounts of total RNA were taken, pooled and were isolated from each of the four leaf tissues and each of the four root tissues and used for reverse transcription to gain a cDNA library of leaves and roots, then they were sequenced on an Illumina HiSeq™ 2000 sequencing platform in BGI Shenzhen (Shenzhen, China) [69]. After removing the low-quality tags in each library, high-quality tags were de novo assembled and clustered [70]. Eight cDNA libraries were constructed using a tag-based digital gene expression system and were further sequenced on an Illumina HiSeq™ 2000 sequencing platform (Shenzhen, China) [12,71]. All resulting clean reads were mapped to our transcriptome reference database [12]. To identify differentially expressed genes (DEGs), the number of fragments per kb per million reads (FPKM) method was used to calculate the transcript levels of all assembled unigenes [11]. Then, genes were defined as DEGs with a false discovery rate (FDR) adjusted value of p value < 0.001 and an absolute value of log2 ratio >1 as the threshold [69].

4.2. Regulatory Pathways Analysis of DEGs and Quantitative Real-Time PCR Validation

The BLASTX tool, with an E value ≤ 10−5 threshold, was used to obtain Gene Ontology (GO) annotations for unigenes, and the pathways were investigated by matching A. canescens genes to putative orthologs in the Kyoto Encyclopedia of Genes and Genomes (KEGG) protein database (www.genome.jp/dbget/ accessed on 10 September 2022) [11]. The GO and KEGG enrichment results were visualized using the ggplot2 package in Rstudio.
The reliability of the transcriptome analysis results in this study was verified by determining the transcript level of seven randomly selected DEGs using qRT-PCR analysis. Total RNA was extracted from control and treated samples using the TaKaRa Mini BEST Plant RNA Extraction Kit (TaKaRa, Beijing, China), and the NanoDrop ND-1000 instrument (Thermo Scientific, Waltham, MA, USA) was used to quantify the extracted RNA [12]. A total of 2 μg of DNase-treated RNA isolated from each of the four samples was further used to synthesize first-strand cDNA, in accordance with the manufacturer’s protocol (TaKaRa Biotechnology, China). qRT-PCR was performed using SYBR Green Real-Time PCR Master mix (TaKaRa Biotechnology, China) and conducted in a StepOnePlus Real-Time PCR Thermocycler (Thermo Scientific, Waltham, MA, USA). The reaction system comprised 20 μL, containing 2 μL cDNA, 10 μL SYBR Premix EX Taq II, 0.4 μL ROX Reference Dye II, 0.8 μL each of primers (10 mM), and 6 μL ddH2O. A. canescens ACTIN internal control gene and primer sequences used in qRT-PCR are presented in Table S20. The relative expression levels of seven randomly selected genes were calculated using the 2–ΔΔCt method [69].

5. Conclusions

This study presented a further and deeper analysis of the transcriptional changes in A. canescens in its adaptation to salt environments. The transcript levels of many DEGs associated with the ROS scavenging system were significantly upregulated, probably contributing to the effective scavenging of excessive ROS under saline conditions in A. canescens. Meanwhile, the upregulation of many transcription factors at the transcriptional level possibly promoted A. canescens’ salt tolerance by regulating the expression of downstream salt stress-responsive genes. In addition, the alteration in the transcription of many candidate genes related to protein kinase might regulate the response of A. canescens to a saline environment by a complex network of signal transduction. This research expands our knowledge of the molecular mechanisms of salt tolerance in the halophyte species and provides a useful foundation for the genetic improvement in salt resistance of forages and crops.

Supplementary Materials

The supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/ijms24010242/s1.

Author Contributions

A.-K.B. conceived and designed the study; H.G. performed the experiment; S.F., B.W., C.L., and H.G. collected and analyzed the data; S.F. and B.W. wrote the manuscript; A.-K.B. revised the manuscript. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Natural Science Foundation of China (31971761, 31670405), the Natural Science Foundation of Gansu Province, China (20JR5RA241), and the Fundamental Research Funds for the Central Universities (lzujbky-2022-ct03).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data are contained within the article and Supplementary Materials.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Flowers, T.J.; Colmer, T.D. Plant salt tolerance: Adaptations in halophytes. Ann. Bot. 2015, 115, 327–331. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  2. Zhang, J.-L.; Shi, H. Physiological and molecular mechanisms of plant salt tolerance. Photosynth. Res. 2013, 115, 1–22. [Google Scholar] [CrossRef] [PubMed]
  3. Shabala, S. Learning from halophytes: Physiological basis and strategies to improve abiotic stress tolerance in crops. Ann. Bot. 2013, 112, 1209–1221. [Google Scholar] [CrossRef] [PubMed]
  4. Wang, H.; Wang, H.; Shao, H.; Tang, X. Recent advances in utilizing transcription factors to improve plant abiotic stress tolerance by transgenic technology. Front. Plant Sci. 2016, 7, 67. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  5. Sanchez, D.H.; Pieckenstain, F.L.; Szymanski, J.; Erban, A.; Bromke, M.; Hannah, M.A.; Kraemer, U.; Kopka, J.; Udvardi, M.K. Comparative functional genomics of salt stress in related model and cultivated plants identifies and overcomes limitations to translational genomics. PLoS ONE 2011, 6, e17094. [Google Scholar] [CrossRef]
  6. Tuberosa, R.; Salvi, S. Genomics-based approaches to improve drought tolerance of crops. Trends Plant Sci. 2006, 11, 405–412. [Google Scholar] [CrossRef]
  7. Hao, G.-Y.; Lucero, M.E.; Sanderson, S.C.; Zacharias, E.H.; Holbrook, N.M. Polyploidy enhances the occupation of heterogeneous environments through hydraulic related trade-offs in Atriplex canescens (Chenopodiaceae). New Phytol. 2013, 197, 970–978. [Google Scholar] [CrossRef]
  8. Glenn, E.P.; Olsen, M.; Frye, R.; Moore, D.; Miyamoto, S. How much sodium accumulation is necessary for salt tolerance in subspecies of the halophyte Atriplex canescens. Plant Cell Environ. 1994, 17, 711–719. [Google Scholar] [CrossRef]
  9. Pan, Y.-Q.; Guo, H.; Wang, S.-M.; Zhao, B.; Zhang, J.-L.; Ma, Q.; Yin, H.-J.; Bao, A.-K. The Photosynthesis, Na+/K+ Homeostasis and Osmotic Adjustment of Atriplex canescens in Response to Salinity. Front. Plant Sci. 2016, 7. [Google Scholar] [CrossRef] [Green Version]
  10. Ma, D.K.; He, Z.B.; Bai, X.; Wang, W.; Zhao, P.; Lin, P.; Zhou, H. Atriplex canescens, a valuable plant in soil rehabilitation and forage production. A review. Sci. Total Environ. 2022, 804, 150287. [Google Scholar] [CrossRef]
  11. Wang, Z.; Gerstein, M.; Snyder, M. RNA-Seq: A revolutionary tool for transcriptomics. Nat. Rev. Genet. 2009, 10, 57–63. [Google Scholar] [CrossRef] [PubMed]
  12. Guo, H.; Zhang, L.; Cui, Y.-N.; Wang, S.-M.; Bao, A.-K. Identification of candidate genes related to salt tolerance of the secretohalophyte Atriplex canescens by transcriptomic analysis. BMC Plant Biol. 2019, 19, 213. [Google Scholar] [CrossRef] [PubMed]
  13. Zhu, J.-K. Genetic analysis of plant salt tolerance using Arabidopsis. Plant Physiol. 2000, 124, 941–948. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  14. Xu, P.; Guo, Q.; Meng, S.; Zhang, X.; Shen, X. Genome-wide association analysis reveals genetic variations and candidate genes associated with salt tolerance related traits in Gossypium hirsutum. BMC Genom. 2021, 22, 26. [Google Scholar] [CrossRef]
  15. Jaleel, C.-A.; Riadh, K.; Gopi, R.; Manivannan, P.; Ines, J.; Al-Juburi, H.-J.; Zhao, C.-X.; Shao, H.-B.; Panneerselvam, R. Antioxidant defense responses: Physiological plasticity in higher plants under abiotic constraints. Acta Physiol. Plant. 2009, 31, 427–436. [Google Scholar] [CrossRef]
  16. Mittler, R.; Vanderauwera, S.; Gollery, M.; Van Breusegem, F. Reactive oxygen species homeostasis and signalling during drought and salinity stresses. Plant Cell Environ. 2010, 33, 453–467. [Google Scholar]
  17. Petrov, V.; Hille, J.; Mueller-Roeber, B.; Gechev, T.-S. ROS-mediated abiotic stress-induced programmed cell death in plants. Front. Plant. Sci. 2015, 6, 69. [Google Scholar] [CrossRef] [Green Version]
  18. Pang, C.-H.; Wang, B.-S. Oxidative Stress and Salt Tolerance in Plants. In Progress in Botany; Springer: Berlin/Heidelberg, Germany, 2008; pp. 231–245. [Google Scholar]
  19. Baskar, V.; Venkatesh, R.; Ramalingam, S. Flavonoids (antioxidants systems) in higher plants and their response to stresses. In Antioxidants and Antioxidant Enzymes in Higher Plants; Springer: Cham, Switzerland, 2018; pp. 253–268. [Google Scholar]
  20. Zhang, Z.-Z.; Zhan, T.; Li, Q.; Tang, D.; Li, S.-S.; Wang, C.-Y.; He, K.-N. Physiological and biochemical responses of Atriplex canescens seedlings to salt stress. Acta Bot. Boreali Occident. Sin. 2017, 37, 2435–2443. [Google Scholar]
  21. Charu, L.; Manoj, P. Role of DREBs in regulation of abiotic stress responses in plants. J. Exp. Bot. 2011, 62, 4731–4748. [Google Scholar]
  22. Zhu, J.-K. Abiotic Stress Signaling and Responses in Plants. Cell 2016, 167, 313–324. [Google Scholar] [CrossRef] [Green Version]
  23. Liu, D.; Zhao, H.; Jin, Z.; Zhou, T.; Xiao, C. RNA-seq reveals the salt tolerance of Ipomoea pes-caprae, a wild relative of sweet potato. J. Plant Physiol. 2020, 255, 153276. [Google Scholar] [CrossRef] [PubMed]
  24. Sevilla, F.; Camejo, D.; Ortiz-Espin, A.; Calderon, A.; Lazaro, J.J.; Jimenez, A. The thioredoxin/peroxiredoxin/sulfiredoxin system: Current overview on its redox function in plants and regulation by reactive oxygen and nitrogen species. J. Exp. Bot. 2015, 66, 2945–2955. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  25. Ma, Q.; Bao, A.-K.; Chai, W.-W.; Wang, W.-Y.; Zhang, J.-L.; Li, Y.-X.; Wang, S.-M. Transcriptomic analysis of the succulent xerophyte Zygophyllum xanthoxylum in response to salt treatment and osmotic stress. Plant Soil 2016, 402, 343–361. [Google Scholar] [CrossRef]
  26. Mierziak, J.; Kostyn, K.; Kulma, A. Flavonoids as important molecules of plant interactions with the environment. Molecules 2014, 19, 16240–16265. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  27. Dubouzet, J.G.; Sakuma, Y.; Ito, Y.; Kasuga, M.; Dubouzet, E.G.; Miura, S.; Seki, M.; Shinozaki, K.; Yamaguchi-Shinozaki, K. OsDREB genes in rice, Oryza sativa L., encode transcription activators that function in drought-, high-salt- and cold-responsive gene expression. Plant J. 2003, 33, 751–763. [Google Scholar] [CrossRef] [PubMed]
  28. Yin, H.; Li, M.; Li, D.; Khan, S.-A.; Hepworth, S.R.; Wang, S.-M. Transcriptome analysis reveals regulatory framework for salt and osmotic tolerance in a succulent xerophyte. BMC Plant Biol. 2019, 19, 88. [Google Scholar] [CrossRef]
  29. Zhao, S.; Zhang, Q.; Liu, M.; Zhou, H.; Ma, C.; Wang, P. Regulation of plant responses to salt stress. Int. J. Mol. Sci. 2021, 22, 9. [Google Scholar] [CrossRef]
  30. Quan, R.; Lin, H.; Mendoza, I.; Zhang, Y.; Cao, W.; Yang, Y.; Shang, M.; Chen, S.; Pardo, J.M.; Guo, Y. SCABP8/CBL10, a Putative Calcium Sensor, interacts with the Protein Kinase SOS2 to Protect Arabidopsis Shoots from Salt Stress. Plant Cell 2007, 19, 1415–1431. [Google Scholar] [CrossRef] [Green Version]
  31. Bhaskara, G.B.; Nguyen, T.T.; Verslues P, E. Unique Drought Resistance Functions of the Highly ABA-Induced Clade A Protein Phosphatase 2Cs. Plant Physiol. 2012, 160, 379–389. [Google Scholar] [CrossRef] [Green Version]
  32. Gill, S.S.; Tuteja, N. Reactive oxygen species and antioxidant machinery in abiotic stress tolerance in crop plants. Plant Physiol. Biochem. 2010, 48, 909–930. [Google Scholar] [CrossRef]
  33. Mittler, R. Oxidative stress, antioxidants and stress tolerance. Trends Plant Sci. 2002, 7, 405–410. [Google Scholar] [CrossRef] [PubMed]
  34. Prashanth, S.R.; Sadhasivam, V.; Parida, A. Overexpression of cytosolic copper/zinc superoxide dismutase from a mangrove plant Avicennia mayina in indica Rice var Pusa Basmati-1 confers abiotic stress tolerance. Transgenic Res. 2008, 17, 281–291. [Google Scholar] [CrossRef] [PubMed]
  35. Badawi, G.-H.; Yamauchi, Y.; Shimada, E.; Sasaki, R.; Kawano, N.; Tanaka, K.; Tanaka, K. Enhanced tolerance to salt stress and water deficit by overexpressing superoxide dismutase in tobacco (Nicotiana tabacum) chloroplasts. Plant Sci. 2004, 166, 919–928. [Google Scholar] [CrossRef]
  36. Wang, Y.-H.; Ying, Y.; Chen, J.; Wang, X.-C. Transgenic Arabidopsis overexpressing Mn-SOD enhanced salt-tolerance. Plant Sci. 2004, 167, 671–677. [Google Scholar] [CrossRef]
  37. Polidoros, A.N.; Scandalios, J.G. Role of hydrogen peroxide and different classes of antioxidants in the regulation of catalase and glutathione S-transferase gene expression in maize (Zea mays L.). Physiol. Plant. 1999, 106, 112–120. [Google Scholar] [CrossRef] [Green Version]
  38. Cui, Y.-N.; Wang, F.-Z.; Yang, C.-H.; Yuan, J.-Z.; Guo, H.; Zhang, J.-L.; Wang, S.-M.; Ma, Q. Transcriptomic profiling identifies candidate genes involved in the salt tolerance of the xerophyte pugionium cornutum. Genes 2019, 10, 1039. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  39. Dixon, D.P.; Lapthorn, A.; Edwards, R. Plant glutathione transferases. Genome Biol. 2002, 3, reviews3004.1. [Google Scholar] [CrossRef] [Green Version]
  40. Roxas, V.P.; Lodhi, S.A.; Garrett, D.K.; Mahan, J.R.; Allen, R.D. Stress tolerance in transgenic tobacco seedlings that overexpress glutathione S-transferase/glutathione peroxidase. Plant Cell Physiol. 2000, 41, 1229–1234. [Google Scholar] [CrossRef]
  41. Balmer, Y.; Vensel, W.H.; Tanaka, C.K.; Hurkman, W.J.; Gelhaye, E.; Rouhier, N.; Jacquot, J.P.; Manieri, W.; Schuurmann, P.; Droux, M.; et al. Thioredoxin links redox to the regulation of fundamental processes of plant mitochondria. Proc. Natl. Acad. Sci. USA 2004, 101, 2642–2647. [Google Scholar] [CrossRef] [Green Version]
  42. Barranco-Medina, S.; Krell, T.; Finkemeier, I.; Sevilla, F.; Lazaro, J.-J.; Dietz, K.-J. Biochemical and molecular characterization of the mitochondrial peroxiredoxin PsPrxII F from Pisum sativum. Plant Physiol. Biochem. 2007, 45, 729–739. [Google Scholar] [CrossRef]
  43. Zhang, C.-J.; Zhao, B.-C.; Ge, W.-N.; Zhang, Y.-F.; Song, Y.; Sun, D.-Y.; Guo, Y. An apoplastic h-type thioredoxin is involved in the stress response through regulation of the apoplastic reactive oxygen species in rice. Plant Physiol. 2011, 157, 1884–1899. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  44. Fini, A.; Brunetti, C.; Di Ferdinando, M.; Ferrini, F.; Tattini, M. Stress-induced flavonoid biosynthesis and the antioxidant machinery of plants. Plant Signal. Behav. 2011, 6, 709–711. [Google Scholar] [CrossRef] [PubMed]
  45. Vu, T.T.; Chan, Y.J.; Nguyen, H.N.; Lee, D.; Lee, S.A.; Kim, J.H. Characterization of Brassica napus flavonol synthase involved in flavonol biosynthesis in Brassica napus L. J. Agric. Food Chem. 2015, 63, 7819–7825. [Google Scholar] [CrossRef]
  46. Ben, A.S.; Aung, B.; Amyot, L.; Lalin, L.; Lachâal, M.; Karray-Bouraoui, N.; Hannoufa, A. Salt stress (NaCl) affects plant growth and branch pathways of carotenoid and flavonoid biosyntheses in Solanum nigrum. Acta Physiol. Plant. 2016, 38, 72. [Google Scholar]
  47. Yamaguchi-Shinozaki, K.; Shinozaki, K. Transcriptional regulatory networks in cellular responses and tolerance to dehydration and cold stresses. Annu. Rev. Plant Biol. 2006, 57, 781–803. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  48. 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] [CrossRef]
  49. Du, C.; Zhao, P.; Zhang, H.; Li, N.; Zheng, L.; Wang, Y. The Reaumuria trigyna transcription factor RtWRKY1 confers tolerance to salt stress in transgenic Arabidopsis. J. Plant Physiol. 2017, 215, 48–58. [Google Scholar] [CrossRef]
  50. Tang, L.; Cai, H.; Zhai, H.; Luo, X.; Wang, Z.; Cui, L.; Bai, X. Overexpression of Glycine soja WRKY20 enhances both drought and salt tolerance in transgenic alfalfa (Medicago sativa L.). Plant Cell Tissue Organ Cult. 2014, 118, 77–86. [Google Scholar] [CrossRef]
  51. Wang, L.; Yao, W.; Sun, Y.; Wang, J.; Jiang, T. Association of transcription factor WRKY56 gene from Populus simonii × P. nigra with salt tolerance in Arabidopsis thaliana. PeerJ 2019, 7, e7291. [Google Scholar] [CrossRef] [Green Version]
  52. Wang, F.; Kong, W.; Wong, G.; Fu, L.; Peng, R.; Li, Z.; Yao, Q. AtMYB12 regulates flavonoids accumulation and abiotic stress tolerance in transgenic Arabidopsis thaliana. Mol. Genet. Genom. 2016, 291, 1545–1559. [Google Scholar] [CrossRef]
  53. 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] [CrossRef] [PubMed] [Green Version]
  54. Sun, X.; Sun, C.; Li, Z.; Hu, Q.; Han, L.; Luo, H. AsHSP17, a creeping bentgrass small heat shock protein modulates plant photosynthesis and ABA-dependent and independent signalling to attenuate plant response to abiotic stress. Plant Cell Environ. 2016, 39, 1320–1337. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  55. Swindell, W.R.; Huebner, M.; Weber, A.P. Transcriptional profiling of Arabidopsis heat shock proteins and transcription factors reveals extensive overlap between heat and non-heat stress response pathways. BMC Genom. 2007, 8, 125. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. Ogawa, D.; Yamaguchi, K.; Nishiuchi, T. High-level overexpression of the Arabidopsis HsfA2 gene confers not only increased themotolerance but also salt/osmotic stress tolerance and enhanced callus growth. J. Exp. Bot. 2007, 58, 3373–3383. [Google Scholar] [CrossRef]
  57. Huang, Q.; Wang, Y.; Li, B.; Chang, J.; Chen, M.; Li, K.; Yang, G.; He, G. TaNAC29, a NAC transcription factor from wheat, enhances salt and drought tolerance in transgenic Arabidopsis. BMC Plant Biol. 2015, 15, 268. [Google Scholar] [CrossRef] [Green Version]
  58. Saad, A.S.I.; Li, X.; Li, H.-P.; Huang, T.; Gao, C.-S.; Guo, M.-W.; Cheng, W.; Zhao, G.-Y.; Liao, Y.-C. A rice stress-responsive NAC gene enhances tolerance of transgenic wheat to drought and salt stresses. Plant Sci. 2013, 203, 33–40. [Google Scholar] [CrossRef] [PubMed]
  59. Perez-Clemente, R.M.; Vives, V.; Zandalinas, S.I.; Lopez-Climent, M.F.; Munoz, V.; Gomez-cadenas, A. Biotechnological approaches to study plant responses to stress. Biomed Res. Int. 2013, 2013, 654120. [Google Scholar] [CrossRef] [Green Version]
  60. Ye, Y.; Ding, Y.; Jiang, Q.; Wang, F.; Sun, J.; Zhu, C. The role of receptor-like protein kinases (RLKs) in abiotic stress response in plants. Plant Cell Rep. 2017, 36, 235–242. [Google Scholar] [CrossRef]
  61. Marshall, A.; Aalen, R.B.; Audenaert, D.; Beeckman, T.; Broadley, M.R.; Butenko, M.A.; Cano-Delgado, A.I.; de Vries, S.; Dresselhaus, T.; Felix, G.; et al. Tackling drought stress: Receptor-like kinases present new approaches. Plant Cell 2012, 24, 2262–2278. [Google Scholar] [CrossRef]
  62. Chen, J.; Yu, F.; Liu, Y.; Du, C.; Li, X.; Zhu, S.; Wang, X.; Lan, W.; Rodriguez, P.L.; Liu, X.; et al. FERONIA interacts with ABI2-type phosphatases to facilitate signaling cross-talk between abscisic acid and RALF peptide in Arabidopsis. Proc. Natl. Acad. Sci. USA 2016, 113, e5519–e5527. [Google Scholar] [CrossRef] [Green Version]
  63. Zhang, P.; Zhang, Z.; Wang, J.; Cong, B.; Chen, K.; Liu, S. A novel receptor-like kinase (PnRLK-1) from the Antarctic Moss Pohlia nutans enhances salt and oxidative stress tolerance. Plant Mol. Biol. Rep. 2015, 33, 1156–1170. [Google Scholar] [CrossRef]
  64. Cheng, C.; Li, C.; Wang, D.; Zhai, L.; Cai, Z. The soybean GmNARK affects aba and salt responses in transgenic Arabidopsis thaliana. Front. Plant Sci. 2018, 9, 514. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  65. Kazan, K. Diverse roles of jasmonates and ethylene in abiotic stress tolerance. Trends Plant Sci. 2015, 20, 219–229. [Google Scholar] [CrossRef] [PubMed]
  66. Xu, J.; Tian, Y.-S.; Peng, R.-H.; Xiong, A.-S.; Zhu, B.; Jin, X.-F.; Gao, F.; Fu, X.-Y.; Hou, X.-L.; Yao, Q.-H. AtCPK6, a functionally redundant and positive regulator involved in salt/drought stress tolerance in Arabidopsis. Planta 2010, 231, 1251–1260. [Google Scholar] [CrossRef] [PubMed]
  67. de Zelicourt, A.; Colcombet, J.; Hirt, H. The role of MAPK modules and ABA during abiotic stress signaling. Trends Plant Sci. 2016, 21, 677–685. [Google Scholar] [CrossRef]
  68. Xiong, L.-Z.; Yang, Y.-N. Disease resistance and abiotic stress tolerance in rice are inversely modulated by an abscisic acid-inducible mitogen-activated protein kinase. Plant Cell 2003, 15, 745–759. [Google Scholar] [CrossRef] [Green Version]
  69. Dang, Z.H.; Zheng, L.L.; Wang, J.; Gao, Z.; Wu, S.B.; Qi, Z.; Wang, Y.C. Transcriptomic profiling of the salt-stress response in the wild recretohalophyte Reaumuria trigyna. BMC Genom. 2013, 14, 29. [Google Scholar] [CrossRef] [Green Version]
  70. Grabherr, M.G.; Haas, B.J.; Yassour, M.; Levin, J.Z.; Thompson, D.A.; Amit, I.; Adiconis, X.; Fan, L.; Raychowdhury, R.; Zeng, Q.; et al. Full-length transcriptome assembly from RNA-Seq data without a reference genome. Nat. Biotechnol. 2011, 29, 644–652. [Google Scholar] [CrossRef] [Green Version]
  71. Xue, J.; Bao, Y.-Y.; Li, B.-L.; Cheng, Y.-B.; Peng, Z.-Y.; Liu, H.; Xu, H.J.; Zhu, Z.-R.; Lou, Y.-G.; Cheng, J.-A.; et al. Transcriptome analysis of the brown planthopper Nilaparvata lugens. PLoS ONE 2010, 5, e14233. [Google Scholar] [CrossRef]
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Figure 1. Venn diagrams showing DEGs in A. canescens under salt treatments. Blue and yellow colors represent leaf and root transcripts under 100 mM NaCl treatment for (A) 6  h and (B) 24  h, respectively. C and S represent the control conditions and 100 mM NaCl treatment, respectively; L and R denote the leaves and roots, respectively; and 6 and 24 denote the treatment durations.
Figure 1. Venn diagrams showing DEGs in A. canescens under salt treatments. Blue and yellow colors represent leaf and root transcripts under 100 mM NaCl treatment for (A) 6  h and (B) 24  h, respectively. C and S represent the control conditions and 100 mM NaCl treatment, respectively; L and R denote the leaves and roots, respectively; and 6 and 24 denote the treatment durations.
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Figure 2. GO terms and KEGG pathways involved in the leaves and roots at 6 h in A. canescens under 100 mM NaCl treatment. (A) Biological process GO terms of CL6-vs-SL6 and CR6-vs-SR6. (B) Molecular function GO terms of CL6-vs-SL6 and CR6-vs-SR6. (C) Top 30 significantly enriched KEGG pathways in CL6-vs-SL6. (D) Top 30 significantly enriched KEGG pathways in CR6-vs-SR6. C and S represent the control conditions and 100 mM NaCl treatment, respectively; L and R denote the leaves and roots, respectively; and 6 denotes the treatment duration. The x-axis in (A,B) indicates the percentage of DEG numbers in each GO term; the x-axis in (C,D) indicates the percentage of DEG numbers vs. background gene numbers in each KEGG pathway.
Figure 2. GO terms and KEGG pathways involved in the leaves and roots at 6 h in A. canescens under 100 mM NaCl treatment. (A) Biological process GO terms of CL6-vs-SL6 and CR6-vs-SR6. (B) Molecular function GO terms of CL6-vs-SL6 and CR6-vs-SR6. (C) Top 30 significantly enriched KEGG pathways in CL6-vs-SL6. (D) Top 30 significantly enriched KEGG pathways in CR6-vs-SR6. C and S represent the control conditions and 100 mM NaCl treatment, respectively; L and R denote the leaves and roots, respectively; and 6 denotes the treatment duration. The x-axis in (A,B) indicates the percentage of DEG numbers in each GO term; the x-axis in (C,D) indicates the percentage of DEG numbers vs. background gene numbers in each KEGG pathway.
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Figure 3. GO terms and KEGG pathways involved in the leaves and roots at 24 h in A. canescens under 100 mM NaCl treatment. (A) Biological process GO terms of CL24-vs-SL24 and CR24-vs-SR24. (B) Molecular function GO terms of CL24-vs-SL24 and CR24-vs-SR24. (C) Top 30 significantly enriched KEGG pathways in CL24-vs-SL24. (D) Top 30 significantly enriched KEGG pathways in CR24-vs-SR24. C and S represent the control conditions and 100 mM NaCl treatment, respectively; L and R denote the leaves and roots, respectively; and 24 denotes the treatment duration. The x-axis in (A,B) indicates the percentage of DEG numbers in each GO term; the x-axis in (C,D) indicates the percentage of DEG numbers vs. background gene numbers in each KEGG pathway.
Figure 3. GO terms and KEGG pathways involved in the leaves and roots at 24 h in A. canescens under 100 mM NaCl treatment. (A) Biological process GO terms of CL24-vs-SL24 and CR24-vs-SR24. (B) Molecular function GO terms of CL24-vs-SL24 and CR24-vs-SR24. (C) Top 30 significantly enriched KEGG pathways in CL24-vs-SL24. (D) Top 30 significantly enriched KEGG pathways in CR24-vs-SR24. C and S represent the control conditions and 100 mM NaCl treatment, respectively; L and R denote the leaves and roots, respectively; and 24 denotes the treatment duration. The x-axis in (A,B) indicates the percentage of DEG numbers in each GO term; the x-axis in (C,D) indicates the percentage of DEG numbers vs. background gene numbers in each KEGG pathway.
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Figure 4. Number of DEGs related to the ROS scavenging system under 100 mM NaCl treatment for 6 and 24 h in leaves (A,B, respectively) and in roots (C,D, respectively) of A. canescens. SOD: superoxide dismutase, PrxR: peroxiredoxin, Trx: thioredoxin, PEX: peroxisome biogenesis, CAT: catalase, GLP: germin-like protein, GLR: glutaredoxin, POD: peroxidase, GPX: glutathione peroxidase, GST: glutathione s-transferase, GR: glutathione reductase, DHAR: dehydroascorbate reductase, MDAR: monodehydroascorbate reductase, APX: ascorbate peroxidase. The red upward arrows and black downward arrows show the total number of upregulated DEGs and downregulated DEGs, respectively.
Figure 4. Number of DEGs related to the ROS scavenging system under 100 mM NaCl treatment for 6 and 24 h in leaves (A,B, respectively) and in roots (C,D, respectively) of A. canescens. SOD: superoxide dismutase, PrxR: peroxiredoxin, Trx: thioredoxin, PEX: peroxisome biogenesis, CAT: catalase, GLP: germin-like protein, GLR: glutaredoxin, POD: peroxidase, GPX: glutathione peroxidase, GST: glutathione s-transferase, GR: glutathione reductase, DHAR: dehydroascorbate reductase, MDAR: monodehydroascorbate reductase, APX: ascorbate peroxidase. The red upward arrows and black downward arrows show the total number of upregulated DEGs and downregulated DEGs, respectively.
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Figure 5. Number of DEGs related to flavonoids under 100 mM NaCl treatment for 6 h and 24 h in leaves (A,B, respectively) and in roots (C,D, respectively) of A. canescens. FLG: flavonoid 3-O-glucosyltransferase, DFR: dihydroflavonol-4-reductase, FLS: flavonol synthase, F3H: flavanone 3-hydroxylase, CHI: chalcone isomerase, CHS: chalcone synthase, 4CL: 4-coumarate-CoA ligase, C4H: cinnamate 4-hydroxylase, PAL: phenylalanine ammonialyase. The red upward arrows and black downward arrows indicate the total number of upregulated DEGs and downregulated DEGs, respectively.
Figure 5. Number of DEGs related to flavonoids under 100 mM NaCl treatment for 6 h and 24 h in leaves (A,B, respectively) and in roots (C,D, respectively) of A. canescens. FLG: flavonoid 3-O-glucosyltransferase, DFR: dihydroflavonol-4-reductase, FLS: flavonol synthase, F3H: flavanone 3-hydroxylase, CHI: chalcone isomerase, CHS: chalcone synthase, 4CL: 4-coumarate-CoA ligase, C4H: cinnamate 4-hydroxylase, PAL: phenylalanine ammonialyase. The red upward arrows and black downward arrows indicate the total number of upregulated DEGs and downregulated DEGs, respectively.
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Figure 6. Number of DEGs related to transcription factors under 100 mM NaCl treatment for 6 h in leaves and roots (A,B, respectively) of A. canescens. HSF: heat shock transcription factor, ZF: zinc finger, bHLH: basic helix-loop-helix, NAC: no apical meristem/Arabidopsis transcription activation factor/cup-shaped cotyledon, DREB: dehydration responsive element binding protein, AP2/ERF: APETALA2 and ethylene-responsive element binding proteins, bZIP: basic region-leucine zip-per/homeodomain-leucine zipper, MYB: myeloblastosis, WRKY: WRKY-domain protein. The red upward arrows and black downward arrows show the total number of upregulated DEGs and downregulated DEGs, respectively.
Figure 6. Number of DEGs related to transcription factors under 100 mM NaCl treatment for 6 h in leaves and roots (A,B, respectively) of A. canescens. HSF: heat shock transcription factor, ZF: zinc finger, bHLH: basic helix-loop-helix, NAC: no apical meristem/Arabidopsis transcription activation factor/cup-shaped cotyledon, DREB: dehydration responsive element binding protein, AP2/ERF: APETALA2 and ethylene-responsive element binding proteins, bZIP: basic region-leucine zip-per/homeodomain-leucine zipper, MYB: myeloblastosis, WRKY: WRKY-domain protein. The red upward arrows and black downward arrows show the total number of upregulated DEGs and downregulated DEGs, respectively.
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Figure 7. Number of DEGs related to protein kinases under 100 mM NaCl treatment for 6 and 24 h in leaves (A,B, respectively) and in roots (C,D, respectively) of A. canescens. CTR1: high-affinity K+ transporter, MAPK: mitogen-activated protein kinase, CDPK: calcium-dependent protein kinase, LysM: lysine motif, LRR-RLK: leucine-rich repeat receptor-like kinase, LecRLK: lectin-domain-containing receptor kinase, WAK: cell-wall associated kinases, RLK: receptor-like protein kinase. The red upward arrows and black downward arrows indicate the total number of upregulated DEGs and downregulated DEGs, respectively.
Figure 7. Number of DEGs related to protein kinases under 100 mM NaCl treatment for 6 and 24 h in leaves (A,B, respectively) and in roots (C,D, respectively) of A. canescens. CTR1: high-affinity K+ transporter, MAPK: mitogen-activated protein kinase, CDPK: calcium-dependent protein kinase, LysM: lysine motif, LRR-RLK: leucine-rich repeat receptor-like kinase, LecRLK: lectin-domain-containing receptor kinase, WAK: cell-wall associated kinases, RLK: receptor-like protein kinase. The red upward arrows and black downward arrows indicate the total number of upregulated DEGs and downregulated DEGs, respectively.
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Figure 8. Correlation analysis for expression pattern validation of seven randomly selected DEGs under 100 mM NaCl for 6 h in leaves and in roots (A,B, respectively) by qRT-PCR. The x-axes and y-axes show the gene transcript level changes obtained by qRT-PCR and RNA-seq, respectively. R2 indicates the correlation.
Figure 8. Correlation analysis for expression pattern validation of seven randomly selected DEGs under 100 mM NaCl for 6 h in leaves and in roots (A,B, respectively) by qRT-PCR. The x-axes and y-axes show the gene transcript level changes obtained by qRT-PCR and RNA-seq, respectively. R2 indicates the correlation.
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Table
Table 1. The upregulated DEGs related to the ROS scavenging system in the leaves of A. canescens under 100 mM NaCl but not under the control condition for 6 h.
Table 1. The upregulated DEGs related to the ROS scavenging system in the leaves of A. canescens under 100 mM NaCl but not under the control condition for 6 h.
Gene IDFold ChangeHomologous Gene
GST
Unigene39828_All5.17GST-U2
Unigene40891_All8.79GST ω-2
CL1984.Contig1_All7.81GST L2
CL2520.Contig2_All9.82GSTU8
Unigene13885_All10.68GST-U2
CL1382.Contig5_All9.01GST-L
GPX
CL8077.Contig1_All8.16GPX8
CL9800.Contig2_All8.09GPX
POD
Unigene8100_All8.72POD57
CL8547.Contig1_All9.44POD60
Unigene12967_All9.58POD60
Unigene4101_All10.01POD57-like
CL9189.Contig2_All10.64POD2-like
Unigene27160_All11.00POD12
Unigene13832_All11.34POD39-like
Unigene6922_All11.80POD26
Unigene3299_All11.98POD57-like
Unigene6725_All12.86POD57-like
CL1702.Contig1_All13.37POD25
CL2372.Contig2_All10.39POD60
CL4649.Contig1_All7.81POD21
CL7743.Contig2_All10.01POD57-like
GLP
Unigene7967_All9.36GLP
CL3077.Contig3_All11.58GLPT2
Unigene12529_All11.69GLP
Unigene1703_All11.88GLP2
Unigene5013_All14.63GLP
CAT
CL9179.Contig1_All8.62CAT
PEX
CL2792.Contig2_All7.43PEX1
CL8785.Contig4_All7.27
SOD
Unigene35175_All7.58SOD
Table
Table 2. The upregulated DEGs related to the ROS scavenging system in the leaves of A. canescens under 100 mM NaCl but not under the control condition for 24 h.
Table 2. The upregulated DEGs related to the ROS scavenging system in the leaves of A. canescens under 100 mM NaCl but not under the control condition for 24 h.
Gene IDFold ChangeHomologous Gene
GLR
CL3957.Contig2_All6.60GLR
APX
CL2142.Contig1_All7.52L-APX6
GST
CL338.Contig1_All4.09GST-Like
Unigene30938_All8.72GST-L2
Unigene16620_All3.46GST-Like
CL1382.Contig1_All3.58GST-Like
GPX
CL8077.Contig2_All8.86GPX8
CL4674.Contig3_All8.73GPX2
POD
CL6405.Contig1_All8.76POD 46-like
CL279.Contig2_All7.87POD27
CL3665.Contig1_All4.32POD
CL5563.Contig2_All5.73POD 5-Like
Unigene31890_All6.60POD48
Unigene6725_All4.09POD
Unigene6747_All2.81POD
GLP
Unigene3088_All5.39GLP
Unigene5013_All4.46GLP1
PEX
CL8785.Contig7_All5.58PEX10
Table
Table 3. The upregulated DEGs related to the ROS scavenging system in the leaves of A. canescens under 100 mM NaCl for both 6 and 24 h.
Table 3. The upregulated DEGs related to the ROS scavenging system in the leaves of A. canescens under 100 mM NaCl for both 6 and 24 h.
Gene IDHomologous Gene
APX
CL6261.Contig2_AllAPX6
GST
CL7491.Contig3_AllGST U17-like
Unigene12753_AllGST
Unigene30938_AllGSTL2
Unigene7483_AllGST
Unigene16620_AllGST
CL338.Contig1_AllGST
GPX
CL4674.Contig3_AllGPX2
POD
CL3665.Contig1_AllPOD
Unigene15162_AllPOD4
Unigene17794_AllPOD
Unigene6747_AllPOD
Unigene6725_AllPOD
GLP
CL2975.Contig1_AllGLP2-1
Unigene3088_AllGLP
Unigene5013_AllGLP
Trx
Unigene1940_AllTTL1
Unigene5866_AllTTL1
Table
Table 4. The upregulated DEGs related to the ROS scavenging system in the roots of A. canescens under 100 mM NaCl, but not under the control conditions, for 6 h.
Table 4. The upregulated DEGs related to the ROS scavenging system in the roots of A. canescens under 100 mM NaCl, but not under the control conditions, for 6 h.
Gene IDFold ChangeHomologous Gene
GLR
CL3957.Contig2_All6.60GLR
APX
Unigene23148_All1.02APX6
CL2142.Contig1_All0.35L-APX6
GST
CL7491.Contig3_All1.40GST
Unigene39828_All0.13GST U2
SOD
CL5119.Contig2_All2.62SOD
Table
Table 5. The upregulated DEGs related to the ROS scavenging system in the roots of A. canescens under 100 mM NaCl, but not under the control conditions, for 24 h.
Table 5. The upregulated DEGs related to the ROS scavenging system in the roots of A. canescens under 100 mM NaCl, but not under the control conditions, for 24 h.
Gene IDFold ChangeHomologous Gene
GPX
CL4674.Contig4_All0.69GPX2
CL9800.Contig1_All6.58GPX
GLP
Unigene3091_All0.65GLP2
SOD
CL5119.Contig2_All5.78Fe-SOD
Table
Table 6. The upregulated DEGs related to the ROS scavenging system in the roots of A. canescens under 100 mM NaCl for both 6 and 24 h.
Table 6. The upregulated DEGs related to the ROS scavenging system in the roots of A. canescens under 100 mM NaCl for both 6 and 24 h.
Gene IDHomologous Gene
GLR
Unigene2548_AllGrx-S2
GST
CL7491.Contig3_AllGST
Trx
Unigene6798_AllTrx
CL2824.Contig1_AllTrx
Table
Table 7. The upregulated DEGs related to flavonoids in the leaves of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Table 7. The upregulated DEGs related to flavonoids in the leaves of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Gene IDFold ChangeHomologous Gene
CHS
Unigene32282_All6.67CHS
Unigene2677_All7.80CHS2
Unigene30245_All9.85CHS
CL5595.Contig2_All11.04CHS
CHI
CL990.Contig2_All6.11CHI
FLS
Unigene12627_All7.37FLS
DFR
Unigene17164_All7.88DFR-4-reductase isoform X2
FLG
CL6497.Contig2_All7.08tetrahydroxychalcone glucosyltransferase
Unigene6573_All7.96flavonoid 3-O-glucosyltransferase 7
Unigene2420_All8.73hydroquinone glucosyltransferase
Unigene32282_All6.67flavonoid 3-O-glucosyltransferase 7
Unigene6573_All7.96flavonoid 3-O-glucosyltransferase 7
Unigene29655_All8.10tetrahydroxychalcone glucosyltransferase
Unigene30587_All8.783-O-beta-glucosyltransferase
Table
Table 8. The upregulated DEGs related to flavonoids in the leaves of A. canescens under 100 mM NaCl, but not under control conditions, for 24 h.
Table 8. The upregulated DEGs related to flavonoids in the leaves of A. canescens under 100 mM NaCl, but not under control conditions, for 24 h.
Gene IDFold ChangeHomologous Gene
CHS
Unigene33578_All6.98CHS
Unigene4107_All5.78CHS
CL3755.Contig2_All4.17NAD(P)H-dependent 6-CHS
F3H
Unigene9407_All4.70F3H
C4H
CL3664.Contig1_All7.94C4H
FLG
CL1972.Contig1_All7.13Leucoanthocyanidin dioxygenase
CL275.Contig3_All5.913-O-beta-glucosyltransferase
Table
Table 9. The upregulated DEGs related to flavonoids in the roots of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Table 9. The upregulated DEGs related to flavonoids in the roots of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Gene IDFold ChangeHomologous Gene
DFR
Unigene19482_All5.09DFR4-isoform 2
CL521.Contig8_All10.20DFR4
CL1727.Contig3_All10.38DFR
FLS
Unigene19256_All7.46FLS
FLG
CL6497.Contig1_All9.66tetrahydroxychalcone glucosyltransferas
CL275.Contig3_All0.293-O-beta-glucosyltransferase
Table
Table 10. The upregulated DEGs related to flavonoids in the roots of A. canescens under 100 mM NaCl, but not under control conditions, for 24 h.
Table 10. The upregulated DEGs related to flavonoids in the roots of A. canescens under 100 mM NaCl, but not under control conditions, for 24 h.
Gene IDFold ChangeHomologous Gene
DFR
Unigene19482_All6.78DFR4-isoform 2
CHI
CL1980.Contig1_All10.78CHI
CHS
Unigene32282_All5.70CHS
FLG
Unigene12679_All3.73flavonoid 3-O-glucosyltransferase 7
Unigene33142_All6.14anthocyanidin 5,3-O-glucosyltransferase
CL7163.Contig1_All6.91fructosephosphate glucosyltransferase
CL275.Contig3_All6.463-O-beta-glucosyltransferase
Table
Table 11. The upregulated DEGs related to the transcription factors in the leaves of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Table 11. The upregulated DEGs related to the transcription factors in the leaves of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Gene IDFold ChangeHomologous Gene
WRKY
Unigene1538_All7.58WRKY56
Unigene40205_All8.55WRKY53
Unigene12958_All9.76WRKY65
Unigene5531_All10.47WRKY61
Unigene16243_All11.01WRKY72
MYB
Unigene10098_All7.73MYB 64-like
Unigene35460_All7.85PHL11-like
Unigene28181_All8.51MYB39-like
Unigene403_All9.71MYB59-like
CL8721.Contig1_All9.95MYB12
CL1223.Contig1_All12.14Myb48
CL4043.Contig2_All12.46MYB1R1
HD-ZIP/bZIP
Unigene36315_All5.52bZIPATHB-51 isoform X2
Unigene27471_All6.93bZIP61
Unigene16296_All9.08bZIP
Unigene14640_All10.45TGA10-like
AP2/ERF
Unigene1741_All7.56ERF091
CL1411.Contig1_All10.59BBM2
Unigene3750_All9.80PLT2
NAC
Unigene167_All10.44NAC18
bHLH
Unigene1766_All11.52bHLH118
Unigene16064_All11.30bHLH25
Unigene7013_All8.23bHLH086
CL9130.Contig1_All7.56bHLH25
Unigene27074_All6.75bHLH121
Unigene10520_All10.72bHLH20
Unigene4053_All8.05UPBEAT1-like
MAD-box
Unigene24561_All9.98MADS18
Unigene9423_All9.54MADS23
CL5411.Contig5_All10.95MADS23
ZF
CL7398.Contig3_All11.98ZF CCHC 10-like
HSF
CL3372.Contig2_All11.37HSF24
CL7682.Contig2_All9.95HSF B-3-like
Table
Table 12. The upregulated DEGs related to transcription factors in the roots of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Table 12. The upregulated DEGs related to transcription factors in the roots of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Gene IDFold ChangeHomologous Gene
MYB
Unigene13756_All8.22MYB98
bZIP
Unigene23519_All6.64bZIP HDG5-like
Unigene23520_All6.70bZIP HDG5-like
Unigene26257_All8.36bZIP HDG5-like
bHLH
CL7924.Contig1_All8.77bHLH20
MAD-box
CL1478.Contig3_All6.02AGL24-like
ZF
Unigene5674_All7.53ZF domain-containing protein 7
CL2069.Contig1_All10.85ZF
CL4799.Contig2_All7.33ZF-GIS2
CL37.Contig3_All7.58ZF
CL6690.Contig2_All12.96ZF16
HSF
CL3871.Contig2_All7.40HSF factor A2 isoform 4
Table
Table 13. The upregulated DEGs related to protein kinases in the leaves of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Table 13. The upregulated DEGs related to protein kinases in the leaves of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Gene IDFold ChangeHomologous Gene
Other RLK
CL2170.Contig3_All4.39receptor-like protein kinase At3g47110
CL2893.Contig5_All6.00receptor-like protein kinase
Unigene38755_All6.08proline-rich receptor-like protein kinase PERK15
CL7451.Contig5_All6.13receptor-like protein kinase
Unigene33490_All6.70receptor-like protein kinase 2
CL6175.Contig1_All7.06serine/threonine-protein kinase PBL19
Unigene34019_All7.79receptor-like protein kinase
Unigene36094_All8.32receptor-like protein kinase
Unigene21989_All10.58receptor-like protein kinase HSL1
Unigene1080_All4.80receptor protein kinase TMK1
Unigene30353_All7.10receptor protein kinase
WAK
Unigene36859_All6.16wall-associated receptor kinase 3-like
Unigene29472_All6.95wall-associated receptor kinase-like 16
Unigene34082_All7.48wall-associated receptor kinase-like 9
CL8521.Contig2_All7.95wall-associated receptor kinase-like 1
Unigene35516_All8.47wall-associated receptor kinase-like 16
LecRLK
Unigene21219_All5.86L-type lectin-domain containing receptor kinase S.6
Unigene26968_All6.69G-type lectin S-receptor-like serine/threonine-protein kinase SD1-29 isoform X2
Unigene37389_All7.16G-type lectin S-receptor-like serine/threonine-protein kinase SD2-5
Unigene34574_All8.07L-type lectin-domain containing receptor kinase S.6-like
CL3763.Contig1_All8.31L-type lectin-domain containing receptor kinase IX.1
CL7452.Contig2_All9.60G-type lectin S-receptor-like serine/threonine-protein kinase At1g11330-like
Unigene18214_All12.12L-type lectin-domain containing receptor kinase S.5
LRR-RLK
Unigene38560_All6.32leucine-rich repeat receptor-like protein kinase IMK2-like
Unigene31266_All6.70leucine-rich repeat receptor protein kinase EXS precursor
Unigene36355_All7.11leucine-rich repeat receptor-like serine/threonine-protein kinase At2g24130-like
Unigene38082_All7.12leucine-rich repeat receptor-like protein kinase family protein isoform 1
Unigene2037_All8.74leucine-rich repeat receptor-like protein kinase family protein isoform 1
Unigene12747_All9.39leucine-rich repeat receptor-like protein kinase At1g35710
CL2166.Contig3_All11.08leucine-rich repeat receptor-like protein kinase At1g35710-like
CL2166.Contig1_All11.64leucine-rich repeat receptor-like protein kinase At1g35710-like
Unigene39549_All6.57LRR receptor-like serine/threonine-protein kinase At3g47570-like
Unigene31458_All7.04LRR receptor-like serine/threonine-protein kinase At4g08850
CL1768.Contig6_All7.26LRR receptor-like serine/threonine-protein kinase At3g47570-like
Unigene30665_All8.03LRR receptor-like serine/threonine-protein kinase At3g47570-like
CL371.Contig3_All8.15LRR receptor-like serine/threonine-protein kinase FLS2
Unigene37147_All8.77LRR receptor-like serine/threonine-protein kinase At3g47570
Unigene14583_All9.16LRR receptor-like serine/threonine-protein kinase RCH1
CL6713.Contig2_All9.74LRR receptor-like serine/threonine-protein kinase At1g67720
Unigene450_All9.93LRR receptor-like serine/threonine-protein kinase FLS2
CL2166.Contig2_All11.39LRR receptor-like serine/threonine-protein kinase FLS2-like
Unigene12036_All12.68LRR receptor-like serine/threonine-protein kinase GSO1-like
LysM
Unigene28415_All8.22LysM domain containing receptor kinase
MAPK
Unigene30352_All8.79mitogen-activated protein kinase kinase kinase A-like
Casein
CL2804.Contig4_All8.75casein kinase I isoform delta-like
Table
Table 14. The upregulated DEGs related to protein kinases in the leaves of A. canescens under 100 mM NaCl, but not under control conditions, for 24 h.
Table 14. The upregulated DEGs related to protein kinases in the leaves of A. canescens under 100 mM NaCl, but not under control conditions, for 24 h.
Gene IDFold ChangeHomologous Gene
Other RLK
Unigene21989_All4.52receptor-like protein kinase HSL1
Unigene40680_All5.49receptor-like protein kinase HSL1
CL4830.Contig1_All6.85receptor protein kinase ZmPK1-like
Unigene1080_All8.42receptor protein kinase TMK1
WAK
Unigene850_All3.58BRASSINOSTEROID INSENSITIVE 1-associated receptor kinase 1
Unigene36213_All4.64wall-associated receptor kinase 2-like
Unigene4688_All8.25wall-associated receptor kinase-like 2-like
LecRLK
CL7452.Contig2_All4.86lectin S-receptor-like serine/threonine-protein kinase At1g11330-like
CL865.Contig6_All5.25S-locus lectin protein kinase
CL9743.Contig2_All6.04S-locus lectin protein kinase family protein
CL6802.Contig1_All7.52G-type lectin S-receptor-like serine/threonine-protein kinase At1g34300
Unigene26968_All7.92G-type lectin S-receptor-like serine/threonine-protein kinase SD1-29
Unigene3683_All8.41G-type lectin S-receptor-like serine/threonine-protein kinase At4g27290
LRR-RLK
CL8471.Contig1_All3.91leucine-rich repeat transmembrane protein kinase family protein isoform 1
Unigene39444_All5.88leucine-rich repeat receptor-like protein kinase At1g35710
CL7338.Contig1_All8.71CLV1-like LRR receptor kinase
CL2166.Contig2_All3.46LRR receptor-like serine/threonine-protein kinase FLS2-like
Unigene30007_All4.64LRR receptor-like serine/threonine-protein kinase At5g48740
Unigene35311_All5.39LRR receptor-like serine/threonine-protein kinase ERECTA
Unigene31462_All5.98LRR receptor-like serine/threonine-protein kinase At3g47570
LysM
Unigene40057_All6.66lysM domain-containing GPI-anchored protein 2-like
CDPK
CL8340.Contig2_All4.46CDPK-related kinase 4-like
MAPK
CL4776.Contig1_All6.29mitogen-activated protein kinase NTF6
CL7688.Contig1_All8.58mitogen-activated protein kinase
Casein
CL2804.Contig3_All9.28casein kinase I isoform delta-like
Table
Table 15. The upregulated DEGs related to protein kinases in the roots of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Table 15. The upregulated DEGs related to protein kinases in the roots of A. canescens under 100 mM NaCl, but not under control conditions, for 6 h.
Gene IDFold ChangeHomologous Gene
Other RLK
Unigene39455_All6.00receptor-like protein kinase At5g61350
WAK
CL342.Contig3_All6.04wall-associated kinase 2
CL219.Contig10_All6.82BRASSINOSTEROID INSENSITIVE 1-associated receptor kinase 1
Unigene22036_All7.68BRASSINOSTEROID INSENSITIVE 1-associated receptor kinase 1
Unigene4677_All7.73BRASSINOSTEROID INSENSITIVE 1-associated receptor kinase 1
Unigene2643_All8.99wall-associated kinase 2
LecRLK
CL7244.Contig1_All5.86G-type lectin S-receptor-like serine/threonine-protein kinase RLK1
CL3763.Contig2_All6.00L-type lectin-domain containing receptor kinase IX.1
CL4407.Contig2_All6.48G-type lectin S-receptor-like serine/threonine-protein kinase At1g11410
CL7244.Contig2_All7.86G-type lectin S-receptor-like serine/threonine-protein kinase RLK1
CL9096.Contig2_All8.31lectin S-receptor-like serine/threonine-protein kinase RLK1
Unigene9770_All9.45G-type lectin S-receptor-like serine/threonine-protein kinase RLK1
Unigene16277_All10.94L-type lectin-domain containing receptor kinase S.5-like
LRR-RLK
CL1231.Contig1_All8.00leucine-rich repeat receptor-like protein kinase isoform 8
Unigene26697_All8.37leucine-rich repeat receptor-like protein kinase At4g00330-like
CL1803.Contig4_All12.59leucine-rich repeat receptor-like protein kinase At1g35710
Unigene35311_All6.41LRR receptor-like serine/threonine-protein kinase ERECTA
Unigene32199_All6.75LRR receptor-like serine/threonine-protein kinase At4g36180-like
Unigene35817_All7.36LRR receptor-like serine/threonine-protein kinase At3g47570-like
Unigene31462_All7.55LRR receptor-like serine/threonine-protein kinase At3g47570
Unigene13207_All8.18LRR receptor-like serine/threonine-protein kinase ERECTA
MAPK
CL578.Contig2_All7.59Mitogen-activated protein kinase kinase kinase 5 isoform 2
CL1892.Contig2_All7.95serine/threonine-protein kinase STN8
casein
CL2804.Contig3_All6.95casein kinase I isoform delta-like
Table
Table 16. The upregulated DEGs related to protein kinases in the roots of A. canescens under 100 mM NaCl, but not under control conditions, for 24 h.
Table 16. The upregulated DEGs related to protein kinases in the roots of A. canescens under 100 mM NaCl, but not under control conditions, for 24 h.
Gene IDFold ChangeHomologous Gene
Other RLK
CL4830.Contig2_All5.73receptor protein kinase ZmPK1-like
Unigene38876_All6.83receptor-like protein kinase At5g61350
WAK
CL7712.Contig2_All5.55wall-associated receptor kinase 2-like
Unigene34082_All5.91wall-associated receptor kinase-like 9
Unigene3113_All6.23wall-associated receptor kinase-like 1
Unigene36859_All6.78wall-associated receptor kinase 3-like
Unigene23885_All6.82wall-associated receptor kinase-like 9-like
LecRLK
CL30.Contig6_All5.17G-type lectin S-receptor-like serine/threonine-protein kinase
Unigene2748_All6.19L-type lectin-domain containing receptor kinase IV.2
CL4407.Contig2_All7.22G-type lectin S-receptor-like serine/threonine-protein kinase
CL9743.Contig2_All7.72S-locus lectin protein kinase family protein
LRR-RLK
CL5423.Contig4_All5.78leucine-rich repeat receptor-like protein kinase At5g49770
CL1231.Contig3_All5.88leucine-rich repeat receptor-like protein kinase isoform 8
Unigene39444_All7.00leucine-rich repeat receptor-like protein kinase At1g35710
CL1803.Contig2_All4.25LRR receptor-like serine/threonine-protein kinase FLS2
Unigene13207_All5.09LRR receptor-like serine/threonine-protein kinase ERECTA
Unigene2487_All5.36LRR receptor-like serine/threonine-protein kinase GSO1
CDPK
CL280.Contig5_All1.58Calcium-dependent protein kinase 23 isoform 3
CL3423.Contig3_All4.32Calcium dependent protein kinase 3
Table
Table 17. The upregulated DEGs related to protein kinases in the roots of A. canescens under 100 mM NaCl for both 6 and 24 h.
Table 17. The upregulated DEGs related to protein kinases in the roots of A. canescens under 100 mM NaCl for both 6 and 24 h.
Gene IDHomologous Gene
Other RLK
Unigene9831_Allreceptor-like protein kinase HSL1
CL3685.Contig2_Allreceptor protein kinase
CL2893.Contig5_Allreceptor-like protein kinase
Unigene21989_Allreceptor-like protein kinase HSL1
Unigene1080_Allreceptor protein kinase TMK1
WAK
Unigene15340_Allwall-associated receptor kinase-like 1
Unigene4688_Allwall-associated receptor kinase-like 2-like
Unigene36213_Allwall-associated receptor kinase 2-like
Unigene850_AllBRASSINOSTEROID INSENSITIVE 1-associated receptor kinase 1 precursor
LecRLK
CL2927.Contig8_AllG-type lectin S-receptor-like serine/threonine-protein kinase At4g03230-like
Unigene14705_AllL-type lectin-domain containing receptor kinase IV.2
Unigene26968_AllG-type lectin S-receptor-like serine/threonine-protein kinase SD1-29 isoform X2
CL7452.Contig2_AllG-type lectin S-receptor-like serine/threonine-protein kinase At1g11330-like
LRR-RLK
Unigene30007_AllLRR receptor-like serine/threonine-protein kinase At5g48740
CL7967.Contig2_AllLRR receptor-like serine/threonine-protein kinase GSO1
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MDPI and ACS Style

Feng, S.; Wang, B.; Li, C.; Guo, H.; Bao, A.-K. Transcriptomic Analysis Provides Insight into the ROS Scavenging System and Regulatory Mechanisms in Atriplex canescens Response to Salinity. Int. J. Mol. Sci. 2023, 24, 242. https://doi.org/10.3390/ijms24010242

AMA Style

Feng S, Wang B, Li C, Guo H, Bao A-K. Transcriptomic Analysis Provides Insight into the ROS Scavenging System and Regulatory Mechanisms in Atriplex canescens Response to Salinity. International Journal of Molecular Sciences. 2023; 24(1):242. https://doi.org/10.3390/ijms24010242

Chicago/Turabian Style

Feng, Shan, Beibei Wang, Chan Li, Huan Guo, and Ai-Ke Bao. 2023. "Transcriptomic Analysis Provides Insight into the ROS Scavenging System and Regulatory Mechanisms in Atriplex canescens Response to Salinity" International Journal of Molecular Sciences 24, no. 1: 242. https://doi.org/10.3390/ijms24010242

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