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Wang et al. BMC Plant Biology (2020) 20:128 https://doi.org/10.1186/s12870-020-02342-2 RESEARCH ARTICLE Open Access Overexpression of PpSnRK1α in tomato enhanced salt tolerance by regulating ABA signaling pathway and reactive oxygen metabolism Wen-Ru Wang, Jia-Hui Liang, Gui-Fang Wang, Mao-Xiang Sun, Fu-Tian Peng* and Yuan-Song Xiao* Abstract Background: SNF-related Kinase 1 (SnRK1) is a key component of the cell signaling network. SnRK1 is known to respond to a wide variety of stresses, but its exact role in salt stress response and tolerance is still largely unknown. Results: In this study, we reported that overexpression of the gene encoding the α subunit of Prunus persica SnRK1 (PpSnRK1α) in tomato could improve salt stress tolerance. The increase in salt stress tolerance in PpSnRK1αoverexpressing plants was found to correlate with increased PpSnRK1α expression level and SnRK1 kinase activity. And PpSnRK1α overexpression lines exhibited a lower level of leaf damage as well as increased proline content and reduced malondialdehyde (MDA) compared with wild-type (WT) lines under salt stress. Furthermore, PpSnRK1α enhanced reactive oxygen species (ROS) metabolism by increasing the expression level of antioxidase genes and antioxidant enzyme activities. We further sequenced the transcriptomes of the WT and three PpSnRK1α overexpression lines using RNA-seq and identified about 1000 PpSnRK1α-regulated genes, including many antioxidant enzymes, and these genes were clearly enriched in the MAPK signaling pathway (plant), plant-pathogen interactions and plant hormone signaling transduction and can respond to stimuli, metabolic processes, and biological regulation. Furthermore, we identified the transcriptional levels of several salt stress-responsive genes, SlPP2C37, SlPYL4, SlPYL8, SlNAC022, SlNAC042, and SlSnRK2 family were altered significantly by PpSnRK1α, signifying that SnRK1α may be involved in the ABA signaling pathway to improve tomato salt tolerance. Overall, these findings provided new evidence for the underlying mechanism of SnRK1α conferment in plant salt tolerance phenotypes. Conclusions: Our findings demonstrated that plant salt stress resistance can be affected by the regulation of the SnRK1α. Further molecular and genetic approaches will accelerate our knowledge of PpSnRK1α functions, and inform the genetic improvement of salt tolerance in tomato through genetic engineering and other related strategies. Keywords: PpSnRK1α, ROS metabolism, ABA signaling, Salt tolerance * Correspondence: pfruit@163.com; ysxiao@sdau.edu.cn College of Horticulture Science and Engineering; State Key Laboratory of Crop Biology, Shandong Agricultural University, Tai’an 271000, Shandong, China © The Author(s). 2020 Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data. Wang et al. BMC Plant Biology (2020) 20:128 Background Currently, salt stress affects over 6% of the global area (more than 800 million hectares of land), and the infected area continues to increase [1]. In plants, high salt can affect the absorption of water and nutrients and reduce photosynthesis, thereby inhibiting plant growth and causing yield loss. And at the cellular level, high salt can disturb normal metabolism and cause “physiological drought”, ionic toxicity or causing complex secondary damages to proteins, nucleic acids, and other macromolecular substances [2]. Fundamentally, the salt tolerance of plants is conferred by tolerance genes. The isolation of novel tolerance genes and effective identification of salt-resistant germplasm are key strategies for improving salt tolerance in plants [3]. Recently, extensive genetic and molecular studies using loss-of-function mutants and overexpression lines have been carried out to investigate the molecular basis of salt tolerance in model plants and crop species. It has been reported that protein kinases of the mitogen activated protein kinase (MAPK), Calcineurin B-like-interacting protein kinase (CIPK) and SNF1related protein kinases family(SnRKs) families and many transcription factors (TFs), such as NAC(NAM, ATAF1, 2, and CUC2), AP2/ERF, MYB, WRKY, bZIP, were found to play important roles in environmental stress responses [4–12]. Therefore, screening for salt-tolerant genes via molecular studies is a necessity for protecting the plants against salt stress. The structure and function of SnRK1 are similar to those of the yeast SNF1 and mammalian AMPK [13]. SnRK1 holoenzyme is a heterotrimer comprising a catalytic α subunit, a regulatory γ or βγ subunit, and β subunit as a scaffold connecting α and γ subunits [13]. Phosphorylation of the conserved threonine on the Tloop of the catalytic α subunit is required for SNF1/ AMPK/SnRK1 to remain active [14–17]. SnRK1 is involved in sucrose and lipid metabolism in plants and can respond to stress signals under stress conditions, thereby regulating plant growth and development [18]. For example, increased SNF1 catalytic activity and phosphorylation of the conserved Thr-210 in the activation loop occur in yeast cells exposed to sodium or oxidative stress, indicating that similar to AMPK, SNF1 is activated in response to these stresses [19]. Moreover, it has been reported that SnRK1 activity is required for flooding resistance in Arabidopsis [20]. Likewise, SnRK1 is an essential kinase induced by autophagy under various stress conditions in Arabidopsis [21]. The sucrose nonfermenting-1-related protein kinases(SnRKs)family can respond to stress through regulating multiple signaling pathways via cascade amplification of the stress signal and initiate a stress response. The Page 2 of 15 SnRKs family can be further subdivided into three subfamilies—SnRK1, SnRK2, and SnRK3—according to the differences in tertiary structures [22]. In Arabidopsis, SnRK2.2/SnRK2.4/SnRK2.6 are important regulators of ABA signaling in response to abiotic stress [23], and SnRK3 indirectly participates in ABA signaling by interacting with the regulatory factors in the ABA signaling pathway, thereby enhancing stress tolerance in plants. For example, ABI2 interacts strongly with SnRK3.11/ SnRK3.13/SnRK3.15 to regulate the expression of salt stress-related genes, rendering the plants more sensitive to the stress signal and enhancing salt tolerance [24, 25]. In Arabidopsis, SnRK1 is negatively regulated by the ABA-insensitive 1 (ABI1) and protein phosphatase 2C A group (PP2CA) [26]. Therefore, we speculate that SnRK1 is involved in abiotic stress response via ABA signaling or other pathways. Peach (Prunus persica) is a unique plant species, probably originated from China. It contains abundant valuable genetic resources that can be used to study and improve stress tolerance in plants [27]. In this study, the full-length Prunus persica SnRK1α (PpSnRK1α) sequence was obtained from Prunus persica (Linn.) Batsch. The wild-type (WT) and three transgenic tomato seedlings overexpressing PpSnRK1α (OE-1, OE-4, and OE-7) in WT were used. In order to study the possible regulatory mechanism of SnRK1 under salt stress, we compared the phenotype of the WT and transgenic tomato plants under salt stress and analyzed the physiological indexes, including the metabolic capacity of ROS, and ability to resist osmotic stress. Moreover, we sequenced the transcriptomes of the WT and three PpSnRK1α overexpression lines using RNA-seq and identified approximately 1000 differentially expressed genes (DEGs). We further examined the expression levels of salt stressrelated genes that significantly correlated with SnRK1 and validated the interactions between SnRK1 and known ABA receptors, which provide evidence for a role of SnRK1 in salt stress response, signifying that SnRK1α may be involved in the ABA signaling pathway or reactive oxygen (ROS) metabolism to improve tomato salt tolerance. Overall, our results demonstrate that the overexpression of PpSnRK1α is beneficial for enhancing salt tolerance in plants. Results PpSnRK1α overexpression lines have higher SnRK1 activity and increased salt tolerance In order to further identify the difference between WT and PpSnRK1α-overexpressing tomatoes lines (PpSnRK1αoe), firstly we measured the expression levels of PpSnRK1α in overexpression lines (OE-1, OE-4, and OE-7) and WT. The results are shown in Fig. 1a. PpSnRK1αoe showed Wang et al. BMC Plant Biology (2020) 20:128 Page 3 of 15 Fig. 1 PpSnRK1α overexpression lines had higher SnRK1 activity and increased salt tolerance. a Relative expression level of SnRK1 (PCR was performed using homologous and specific fragments of PpSnRK1 (Prunus persica) and SlSnRK1 (Solanum lycopersicum) between WT plants and PpSnRK1α overexpressing plants). This picture was cropped for simplicity and intuitiveness, the original pictures were in Additional file 1 b Determination of SnRK1 activity c REC of the WT and PpSnRK1α overexpression lines d Evans blue stain. Note: in b and c, the data are represented as means ± standard error (S.E.) of three biological replicates significant higher SnRK1α expression levels than WT, and SnRK1α expression levels were relatively higher in OE-1 and OE-4 than that of OE-7 (Fig. 1a, Additional file 1). Secondly, the SnRK1 activity of three PpSnRK1αoe significantly increased following two hours of the salt treatment and was 11.9–17.8% higher than that of the WT (Fig. 1b). However, SnRK1 activity declined after 24 h of high-salinity treatment both WT and PpSnRK1αoe. Thirdly, the relative electronic conductance of OE-1, OE-4, OE-7, and WT were 64.84, 60.43, 64.17, and 88.49%, respectively, after 12 days of salt treatment (Fig. 1c). In general, PpSnRK1α overexpression lines exhibited a lower level of cell damage than the WT. These observations were further validated by the Evans blue staining experiment (Fig. 1d). Thus, overexpression of PpSnRK1α increased the salt tolerance of plants, and the level of improvement was proportional to the level of PpSnRK1α gene expression and SnRK1 activity. Together, these results evidenced the role of PpSnRK1α overexpression in enhancing salt tolerance in tomato. PpSnRK1α regulates membrane lipid peroxidation and proline accumulation in response to salt stress To further determine if overexpression of PpSnRK1α attenuate the degree of peroxidation of the cell membrane and accumulate proline [28] to resist salt stress, we monitored changes in the MDA content and proline content in both WT and PpSnRK1αoe before and after the salt treatment. No significant difference in MDA Wang et al. BMC Plant Biology (2020) 20:128 content was observed between the PpSnRK1αoe and WT plants under normal condition, Whereas, the MDA content in PpSnRK1αoe was obviously lower than that in the WT after 12 days of high salinity treatment (Fig. 2a). On the other hand, PpSnRK1αoe exhibited a more significant increase of proline content than the WT plants after 12 days of control treatment (Fig. 2b). Furthermore, proline contents accumulated to higher levels in PpSnRK1αoe than in WT under salt stress (Fig. 2b). However, the total soluble sugar content also was determined and found that there was a limited difference in soluble sugar levels between PpSnRK1αoe and WT (Fig. 2c). Overall, these results indicate that PpSnRK1α overexpression leads to a decrease in the degree of cell membrane peroxidation and the accumulation of proline in response to salt stress. Page 4 of 15 PpSnRK1α overexpression lines exhibit reduced ROS content and higher antioxidant enzyme activities under salt stress To further investigate the mechanism of how PpSnRK1α overexpression lines enhances salt tolerance in tomato, the correlation between overexpression of PpSnRK1α and reactive oxygen metabolism in plants and the differences in antioxidant enzyme activities as well as ROS content between the WT and transgenic plants were studied. After 12 days of the salt treatment, the overexpression of PpSnRK1α resulted in a significant decrease (17–26%) in the O2− content, compared with the level in WT plants (Fig. 2a). Consistent with these observations, NBT staining revealed that the transgenic leaves were less damaged than those of the WT under salt stress (Fig. 2b). Fig. 2 MDA, soluble sugar and proline contents in the WT and PpSnRK1α overexpression lines with and without the salt treatment. a MDA content b proline content c soluble sugar content. Three biological replicates were analyzed for each sample, and the data are represented as means ± S.E. of three technical repeats Wang et al. BMC Plant Biology (2020) 20:128 Under the normal growth condition, Superoxide dismutase (SOD), Catalase (CAT), Peroxisome (POD) activities of the transgenic lines were higher than those of the WT (Fig. 2c, e, f). Furthermore, the increases of SOD and POD activities in PpSnRK1α overexpression lines were much more evident, 62.9–96.7% and 8.0–15.8% increases than WT after 12 days of high salinity treatment (Fig. 2e, f). What’s more, PpSnRK1αoe exhibited higher CAT activity than the WT plants under salt stress. This result was consistent with those of the DAB staining assay, which indicated that transgenic plants have lower hydrogen peroxide content and higher CAT activity than WT (Fig. 2c, d). These results indicated that PpSnRK1α may play a role in antioxidant systems to protect plants under salt stress. Overexpression of PpSnRK1α alter the expression level of SnRK2 family genes (SnRK2.1-SnRK2.7) and antioxidase genes (SOD, POD, and CAT1) in tomato The expression levels of SOD, POD, and CAT1 by Quantitative Real-Time PCR (qRT-PCR) were detected both in PpSnRK1αoe and WT to further understand whether SnRK1 alters the expression of superoxide gene at the genetic level. According to Fig. 4, the transcript levels of genes encoding antioxidant enzymes (SOD, POD, and CAT) were the highest (6.839, 4.705 and 4.421 times than WT, respectively) among others in PpSnRK1α overexpression plants under high salinity condition (Fig. 4). Therefore, it can be seen that the overexpression of PpSnRK1α increased the expression level of the antioxidant enzyme genes at the genetic or transcriptional level. There are seven Solanum lycopersicum SnRK2 genes (SlSnRK2s) that are homologous to the Arabidopsis SnRK2.2/SnRK2.3/SnRK2.6 genes in tomato [29]. In PpSnRK1α overexpression plants, the expression level of SnRK2.1 is not significantly changed, and the expression of SlSnRK2.2, SlSnRK2.3 and SlSnRK2.5 were inhibited regardless of whether the salt stress was present or not (Fig. 4). By contrast, the expression level of SlSnRK2.4 was increased in PpSnRK1αoe under both conditions (Fig. 4). However, the expression level of SlSnRK2.7 was inhibited under normal conditions but increased under salt stress (Fig. 4). Therefore, the overexpression of PpSnRK1α complexly affects the expression level of SlSnRK2. Transcriptomic analysis of WT and PpSnRK1α overexpression plants To further evaluate the molecular mechanism of how PpSnRK1α overexpression confers salt tolerance on a broader scale, the differences in gene expression profile between three PpSnRK1αoe (OE-1, OE-4, and OE-7) and WT plants under normal condition were analyzed. Page 5 of 15 Three biological replicates of the WT and three transgenic lines were sequenced using the Illumina platform, and approximately 40 to 51 million high-quality reads (with Fast QC quality score > 36) were obtained for each biological replicate (Additional file 2). Of all reads obtained, 92 to 94% could be mapped to a unique chromosomal position. The expression level of each transcript in the sample was represented by Fragments Per Kilobase of transcript per Million fragments mapped (FPKM). A high linear correlation was observed among the three replicates of the same sample, suggesting small differences among replicates (Additional file 3). Differentially expressed genes (DEGs) were identified by comparing the transcriptomes of the WT and transgenic plants [30, 31]. We identified a total of 1009 DEGs, among which 668 were upregulated and 341 were downregulated, in PpSnRK1α overexpression plants compared with the WT (Fig. 5a). These results revealed that the expression of a large number of genes was altered upon PpSnRK1α overexpression, and these genes are either directly or indirectly regulated by SnRK1. To test whether SnRK1α overexpression relieves severe effects of salt by modulating the expression of saltresponsive genes, functional annotations of both upregulated and down-regulated genes and KEGG pathway enrichment analysis in PpSnRK1αoe were performed (Additional file 4; Fig. 5b; Additional file 5). MAPK (mitogen activated protein kinase) signaling pathway– plant, plant-pathogen interaction, and plant hormone signal transduction were main KEGG pathways that were regulated in PpSnRK1αoe. Then GO terms were assigned to the DEGs. A number of genes were involved in various cellular component, molecular function, and biological processes (Fig. 5c), of which 1714 GO terms were enriched among the upregulated DEGs and 1334 GO terms among the downregulated DEGs (Additional file 6). Among the DEGs, response to stimuli, metabolic processes and biological regulation in biological process and antioxidant activity in molecular function were the obvious enriched GO terms (Fig. 5c). It is noteworthy that expression levels of 17 peroxidase genes were significantly regulated in PpSnRK1α overexpression plants, especially peroxidase 21 was upregulated 6 times and may improve the ability of transgenic plants to remove ROS under salt conditions (Additional file 4). This hypothesis was supported by the patterns of ROS accumulation in the various lines (Fig. 3). PpSnRK1α overexpression alters the expression of several transcription factors and downstream genes, especially the transcript levels of stress-related genes Of all the DEGs, we identified 101 transcription factors (TFs) that belong to 37 families (Additional files 7 and 8). Wang et al. BMC Plant Biology (2020) 20:128 Page 6 of 15 Fig. 3 Antioxidant enzyme activities and the contents of O2− in WT and PpSnRK1α overexpression lines. a Comparison of the O2− content between the WT and PpSnRK1α overexpression lines, b NBT staining for superoxide in the leaves c Comparison of the CAT activity between the WT and PpSnRK1α overexpression lines d DAB staining for H2O2 in the leaves e, f Comparison of the SOD (e) and POD (f) activity between the WT and PpSnRK1α overexpression lines. Note: in a, c, e and f, each sample has three biological replicates. The data are shown as means ± S.E. of three technical repeats Interestingly, the expression levels of TFs from the B3, GARP-G2-like, LOB, and WRKY families were upregulated, whereas those of TFs from other families, such as GRF (growth-regulating factors) and HSF (heat shock transcription factors), were suppressed. Given that over 100 TFs had altered expression levels upon PpSnRK1α Wang et al. BMC Plant Biology (2020) 20:128 overexpression, we concluded that the TFs were directly or indirectly affected by PpSnRK1α, and PpSnRK1α may regulate the expression of some genes or TFs by directly binding to their promoters. To further investigate the role of SnRK1 in stress response, the expression levels of six stress-responsive genes between the WT and PpSnRK1αoe both two conditions were compared. Of the DEGs, there were genes encoding the stress-responsive protein, including phosphatase 2C (solyc03g096670.3), PYL (pyrabactin resistance(PYR)like) /PYR (pyrabactin resistance)(solyc06g050500.2 and solyc01g095700.3) involved in ABA signaling pathway [32].Surprisingly, the regulated TFs also included saltrelated genes, such as NAC (No apical meristem domaincontaining protein) family, some members of which have been shown to enhance the tolerance of rice and Arabidopsis to various abiotic stresses. As shown in Fig. 6a, RNA-seq showed that SlPP2C37, a member of the abiotic stress tolerance-related PP2C family, was significantly down-regulated under normal condition, and the expression levels of SlPP2C37 was upregulated in PpSnRK1αoe and WT under salt stress, whereas the expression level of SlPP2C37 was 1.3-fold lower than that in the WT plants (Fig. 6a, b). Furthermore, the expression levels of ABAreceptors SlPYL4 (solyc06g050500.2) and SlPYL8 (solyc01g095700.3) in PpSnRK1α overexpression plants were also altered (Fig. 6c, d, e, f). For example, the SlPYL4 transcript level increased by 11 to 13-fold in PpSnRK1αoe under both normal condition and salt stress, which was consistent with the result of RNA-seq (Fig. 6c, d); whereas PYL8 expression declined in the transgenic lines under normal condition consistent with the result of RNA-seq and slightly increased under salt stress (Fig. 6e, f). Interestingly, SlNAC022 and SlNAC042 were significantly upregulated higher in PpSnRK1αoe than that in WT under both normal condition and salt stress, and the up-regulated expression levels of SlNAC022 and SlNAC042 in the PpSnRK1αoe were 359.1-fold and 52.0-fold, respectively, higher than those in the WT under salt stress (Fig. 6g, h, i, j). These data indicated that the overexpression of SnRK1α could alter the expression of stress-related genes, and had the potential for improving the salt tolerance of tomato plants. Discussion When plant responses to salt stress, some protein kinases are activated, which then regulates a large number of defense-related genes, and these changes are conducive to the establishment of defense mechanisms in plants. The response of plants to salt stress is closely related to the SnRKs family, which can be through the SOS (Salt Overly Sensitive) signaling pathway and ABA signal transduction [2]. Although it is unclear how plants respond specifically to stress, there is ample evidence Page 7 of 15 that SnRKs can participate in resistance to salt stress in many species [18, 33, 34]. As a key component of the cell signaling network, SnRK1 can interact with sugar molecules of different forms and energy states, regulate the activities of other kinases, and interact with TFs to maintain energy balance within the cell under stress conditions [18]. To our knowledge, AKIN10(homologous with PpSnRK1α) can negatively regulate the accumulation of AtMYC2 protein via AKIN10 kinase activity-dependent protein modification, thereby responding to abiotic stress [35]. SnRK1 also controls Na+ flux and maintains Na/K homeostasis under high salinity stress [36]. Moreover, SnRK1 can respond to high or low glucose levels in the dark as well as under hypoxia and saline conditions, and regulate energy metabolism in plants under stress [37]. In this study, we identified PpSnRK1α and showed that ectopically expressing it in tomato enhanced salt tolerance phenotypes (Fig. 1). Consistent with previous studies, overexpressing PpSnRK1α lines had higher cell viability and grew better under salt stress, which was accompanied by higher PpSnRK1α expression level and SnRK1 activity (Fig. 1), indicating that SnRK1 is a positive regulator of salt tolerance in tomato. Therefore, PpSnRK1α may have potential additional mechanisms in addition to its role in salt tolerance. Accumulation of reactive oxygen species is one of the main responses of plants to salt stress. Excessive ROS will destroy biological macromolecules and produce toxic effects on cells. Several antioxidant enzymes in plants, such as antioxidant dismutase, peroxidase, and catalase, play critical roles in the process of scavenging ROS [38]. It was reported that ROS could also be used as a signaling molecule to mediate plant responses to different stresses [39, 40]. Some protein kinases in the cell can sense the stimulation of exogenous ROS or the production of ROS, and respond to stress through a series of phosphorylation and dephosphorylation signals. For example, NADPH oxidase can rapidly increase the intracellular ROS level, and the stimulus signal quickly enters the nucleus from the plasma membrane of the cell [41]. Szymańska, P. Katarzyna et al. found that two SNF1releted protein kinases 2 (SnRK2), SnRK2.4 and SnRK2.10, could regulate ROS homeostasis and respond to salinity in Arabidopsis [42]. In our investigation, overexpressing PpSnRK1α lines had increased ROS scavenging capacity, low degree of cell membrane damage, and remarkably higher expression of antioxidant enzyme genes under salt stress, which could partially explain the mechanism responsible for the improved salt tolerance of the transgenic plants and suggest a role of PpSnRK1α in regulating the expression of antioxidase genes (Figs. 2, 3, 4, and 7). In Wang et al. BMC Plant Biology (2020) 20:128 Page 8 of 15 Fig. 4 qRT-PCR analysis of the relative expression levels of SlSOD, SlPOD, SlCAT1 and SlSnRK2 genes (SlSnRK2.1- SlSnRK2.7) in the WT and PpSnRK1α overexpression lines general, proline is considered to be one of the osmotic regulators in wheat to resist salt stress, and the accumulation of proline help maintain the integrity and function of the cellular vacuolar membrane, thereby enhancing its ability to resist salt damage [43, 44]. It is apparent that PpSnRK1α helps to maintain the integrity and function of cell membranes, thus enhancing the plant’s ability to resist salt damage (Fig. 2). Therefore, we think that these may have contributed, at least partially, to the observed salt tolerance. The SnRKs represent a large family that can be further divided into the SnRK1, SnRK2, and SnRK3 subfamilies. Many members of the SnRKs family have been shown to play key roles in abiotic stress responses. AREB1/ABF2, AREB2/ABF4, and ABF3 are activated by SnRK2.2, SnRK2.6 andSnRK2.3 in ABA signaling in response to osmotic stress during vegetative growth [45]. SnRK2.2 and the closely related SnRK2.3 are known to play roles in ABA inhibition of seed germination in Arabidopsis [46]. Additionally, SnRK2.6 can interact with ABAR/ CHLH and response to abscisic acid in guard cell signaling [23], The results showed that when plants were under salt stress, the overexpression of PpSnRK1α significantly affected the expression levels of seven SnRK2 family genes in tomato (Fig. 4). Moreover, the research about the SnRKs family revealed that there are also interactions between different genes in the family. For example, in Arabidopsis, SnRK3.15 can interact with SnRK1.1 and SnRK1.2, regulate the activity of them and participate in sugar metabolism [47]. Therefore, the direct or indirect interaction between members of different subfamilies of the plant SnRKs strengthens the plant’s ability to respond to stress. Abscisic acid is a key player in regulating abiotic stress response in plants. A previous study has evidenced the interaction between SnRK1.1 and ABA signaling—the crossing of an SnRK1.1 overexpression Arabidopsis line with the aba2 mutant, which was impaired in both ABA signaling transduction and sugar signaling pathway, led to glucose hyposensitivity [48]. In addition, defective Wang et al. BMC Plant Biology (2020) 20:128 kernel 33 (DEK33) is involved in the ABA synthesis process and can interact with SnRK1, suggesting that their interaction may regulate the stability of DEK33 and thus the ABA signal [49]. It was reported that inhibition of SnRK1 expression in peas resulted in pleiotropic maturation defects similar to those of the ABA insensitive mutants and SnRK1 can respond to ABA treatment in wheat roots, the level of which drops sharply, but the amount of phosphorylated (active) SnRK1 remains constant [50, 51]. In our study, we found that the expression of SlPP2C37 (a member of PP2C family) [26], SlPYL4, SlPYL8 (an ABA receptor in ABA signaling) and SnRK2 family genes were significantly regulated upon PpSnRK1α overexpression under the normal growth condition as revealed by the RNA-seq data (Figs. 5, 6 and 7). MAPK (mitogen activated protein kinase) cascades have been shown to be implicated in ABA signaling and abiotic stress as well [32]. The RNA-seq results Page 9 of 15 showed that the MAPK pathway was significantly regulated in the PpSnRK1α overexpression lines (Fig. 5, Additional file 4). These genes have been shown to be involved in the ABA signaling pathway [5]. According to these results, we presumed that SnRK1α may be involved in the ABA signal transduction pathway. Further verification is needed to illustrate the regulatory mechanism of SnRK1α under salt stress. NAC proteins, as one of the largest family of transcription factors unique to plants, are known to possess diverse roles in plant response to environmental stress [52]. It was reported that ANAC036 (NAC transcription factor family member in Arabidopsis) involved in inflorescence and leaf morphogenesis in Arabidopsis [53]. And Hong Y et al. found that ONAC22 (NAC transcription factor family member in rice) played a positive role in drought and salt stress tolerance through modulating an ABA-mediated pathway [54]. Our investigation Fig. 5 Identification and functional annotation of the DEGs. a DEG identification. b KEGG classification analysis of the DEGs c GO classification analysis of the DEGs Wang et al. BMC Plant Biology (2020) 20:128 Page 10 of 15 Fig. 6 IGV (Integrative Genomics Viewer) visualization of genes by RNA-seq and results of RT-qPCR analysis of related genes a, c, e, g and i IGV visualization of SlPP2C37 (a), SlPYL4 (c), SlPYL8(e), SlNAC022 (g)and SlNAC042(i) b, d, f, h and j Results of RT-qPCR analysis of SlPP2C37 (b), SlPYL4 (d), SlPYL8(f), SlNAC022 (h)and SlNAC042(j). Note: in b, d, f, h and j, error bars indicate SEs (n = 3, 3 biological replicates). All values for WT and PpSnRK1α overexpression plants are statistically significantly different from each other (Student’s t-test; p-value < 0.05) showed that SlNAC022, which has high homology with ANAC036 and ONAC22, was significantly regulated in PpSnRK1α overexpressing plants (Fig. 6). Overexpression of JUNGBRUNNEN1 (JUB1) can strongly delay senescence and enhanced tolerance to various abiotic stresses in Arabidopsis [55, 56]. Interestingly, the expression level of SlNAC42, which has high homology with JUB1, is also significantly higher than that in WT plants (Fig. 6). Here we hypothesize that the up-regulation of SlNAC022 and SlNAC42 in PpSnRK1α overexpressing leaves enhances plant salt tolerance in response to ABA signals. More work is required to further determine if SnRK1 and NAC022/ NAC42 interact directly to improve salt tolerance. Here we showed that over-expression of PpSnRK1α improved the salt tolerance of plants. These observations