Abstract
Salinity is a critical abiotic stress, which significantly impacts the agricultural yield worldwide. Identification of the molecular mechanisms underlying the salt tolerance in euhalophyte Suaeda salsa is conducive to the development of salt-resistant crops. In the present study, high-throughput RNA sequencing was performed after S. salsa leaves were exposed to 300 mM NaCl for 7 days, and 7,753 unigenes were identified as differently expressed genes (DEGs) in S. salsa, including 3,638 increased and 4,115 decreased unigenes. Moreover, hundreds of pathways were predicted to participate in salt stress response in S. salsa by Gene Ontology (GO), MapMan and Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analyses, including ion transport and sequestration as well as photoprotection of photosystem (PS) II. The GO enrichment analysis indicated that genes related to ion transport, reactive oxygen species (ROS) scavenging and transcriptional factors were highly expressed upon NaCl treatment. The excessive Na+ and Cl− ions were supposed to be absorbed into the vacuole for ion sequestration and balance adjustment by potassium transporters (such as KEA3) with high expressions. Moreover, we predicted that mutiple candidate genes associated with photosynthesis (such as PSB33 and ABA4), ROS (such as TAU9 and PHI8) and transcriptional regulation (HB-7 and MYB78) pathways could mitigate salt stress-caused damage in S. salsa.
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Introduction
Salt stress, one of the most important abiotic factors, greatly affects global agricultural productivity. It is estimated that about 6.0% of the land worldwide, more than 800 million ha, is either salt affected or has been subjected to soil salinization1,2. The food production is increased at a rate of 1.8% per year, the world population is expected to exceed 9.5 billion people by 2050 (http://www.fao.org/wsfs/world-summit/en), and 30% of the cultivable soils will become unusable due to salt stress, all of which pose serious challenges to salt alleviating technologies for agricultural research3.
Plants can be divided into halophytes and glycophytes according to the ability of salt tolerance. External salt concentration of 86 mM NaCl has been taken as a general limit, above which the plant yield of glycophytes is severely reduced4,5. Nevertheless, halophytes can grow in a surrounding containing even 200 mM NaCl or more, and they are further categorized into euhalophytes, recretohalophytes and pseudo-halophytes6,7,8,9. Salt-diluting halophytes, such as sea beet and other succulent halophytes, are able to balance low external water potential and generate turgor by accumulating high contents of internal Na+ and Cl− ions in their vegetative tissues10,11,12. Recretohalophytes are typical halophytes, which have developed a series of adaptive secretory structures, including salt glands and salt bladders, for salt excretion2,4,5,13,14,15. These characteristic visible structures of recretohalophytes play a crucial role in excreting excess salt out of the plants to avoid ionic damage13,14,16,17,18,19,20.
Euhalophytes with salt-diluting ability accumulate high concentrations of salt in their cells and tissues and overcome salt toxicity by developing succulence6,8,13,21,22,23,24. These euhalophytes include Excoecaria agallocha, Limnitzera racemosa, Sonneratia acida, Salvadora persica, S. nudiflra, S. nudiflra, S. maritima, S. salsa and Pentatropis sianshoides7,14,25,26. The excessive Na+ and Cl− ions in the vacuole can be compartmentalized by euhalophytes, which helps to lower the water potential of the cells and tissues and subsequently enhance water absorbance from the saline soil to attenuate the ion concentration in the cytoplasm that is detrimental for enzyme activity and biological substances27,28,29. Besides, accumulation of compatible solutes has been regarded as one of basic strategies for the protection and survival of euhalophytes under salt stress, including soluble carbohydrates, glycocoll betaine, polyols and proteins. These compatible solutes protect plants against stress by adjusting cellular osmotic pressure, detoxifiation of reactive oxygen species (ROS), maintaining membrane integrity, and stabilizing enzyme and protein complex30,31,32,33,34,35.
In our current work, we examined the responses of S. salsa to salt stress using Illumina sequencing. This species is a leaf-succulent C3 halophytic herb and becomes one of the most important halophytes in China because of its ability of high salt tolerance21,36,37,38. Besides, the species is of great economical value, because its seeds not only contain 40% oil, but are rich in unsaturated fatty acids, which can be easily converted to chemical compounds for industrial uses21,36,37,39,40,41. S. salsa has adapted to the high salinity in northern China, and it is native to saline soils. The optimal NaCl concentration for its growth is 350 mM, making it well-suited for studies on the response to salt stress as well as for the physiological and molecular characterization of salt tolerance in plants37,38. Genes important for the vacuolar compartmentalization of Na+ have been cloned, and their functions have been tested in S. salsa, such as NHX Na+/H+ antiporters SsNHX, vacuolar H+-ATPase (V-H+-ATPase) genes, SsVHA-H and SsVHA-B23,29,33,42,43,44,45. Many previous studies have shown the responses of S. salsa under salt stress. However, the underlying mechanisms of salt deposition via ion compartmentalization, osmotic adjustment and transcriptional regulation remain largely unknown.
As an effective strategy, transcriptome sequencing can be used to detect candidate participants of stress response on a genome-wide scale. A great deal of attention has been paid to salt stress responses in halophytes using sequencing technologies2,46,47,48,49,50,51,52,53,54,55,56. Full-genome transcriptome analysis through deep sequencing seems to be the most promising strategy to identify candidate genetic determinants of salt tolerance in S. salsa. Therefore, we attempted to explore the essential salt responding genes and their modulators in S. salsa in the present study.
Results
Transcriptome profiling of S. salsa
A total of 474,575,48, 431,877,04, 445,313,26, 434,315,68, 536,186,10 and 405,137,42 paired-end reads were obtained from three control and three salt-treated leaf samples of S. salsa through sequencing by the Illumina HiSeq X platform (Table 1). In addition, de novo transcriptome assembly generated 86,255 unigenes, the average length and N50 of which were 1,647 nt and 2,243, respectively. Generally speaking, 79.16% of the reads were mapped to the reference genome (Table 1).
Functional annotations of unigenes in S. salsa
Similarity test was carried out to annotate unigenes against different databases by BLASTX. All 86,255 (100%) unigenes were annotated in at least one database. A total of 64,872 (75.20%) (Online Resource 1), 49,254 (57.10%) and 48,351 (56.05%) unigenes showed demonstrated similarity to sequences in NT, NR and PFAM databases, respectively, with an E-value threshold of 1e−5 (Fig. 1A). Moreover, we assigned 48,463 (56.18%) unigenes, with an E-value cutoff of 1e−6, in Gene Ontology (GO) database using Blast2GO v2.5. Besides, 59,738 unigenes of the S. salsa were assigned to A. thaliana gene IDs for GO annotation mapping by BLASTX with an E-value cutoff of 1e−5 and categorized into GO terms for GO analysis.
(A) Venn diagram of functional annotations of unigenes in nt (NCBI non-redundant protein sequences), nr (NCBI non-redundant protein sequences), kog (Clusters of Orthologous Groups of proteins), go (Gene Ontology) and pfam (Protein family) databases. (B) Expression patterns of differentially expressed genes (DEGs) identified between 300 mM NaCl treated and control. Red and green dots represent DEGs, grey dots indicate genes that were not differentially expressed. In total, 7,753 unigenes were identified as DEGs (padj <0.05) between NaCl treated and control samples, including 3,638 upregulated genes and 4,115 downregulated genes.
Identification of differentially expressed genes (DEGs) in S. salsa
The relative expression levels of genes in S. salsa under control or salt stress condition were evaluated based on the fragment per kilobase of exon model per million mapped read (FPKM) values, which were calculated based on the uniquely mapped reads. The FPKM values for different genes in six samples ranged from 0 to 74,138.71, with a mean value of 12.47. Furthermore, 3,638 unigenes were filtered as up-regulated genes, and the expressions of 4,115 unigenes were decreased in NaCl-treated samples by comparative analysis when a cutoff of adjusted P value (Padj) <0.05 and |log2fold change [L2fc]|> 1 were used (Fig. 1B; Table S1).
GO, MapMan and KEGG enrichment results of DEGs in S. salsa
To uncover the molecular mechanisms underlying the salt tolerance of S. salsa leaves, the DEGs were characterized with GO databases. Consequently, 171 biological process (BP) terms were enriched by 3,638 up-regulated unigenes with the cutoff of P value < 0.05, including “calcium ion transmembrane transport” (GO: 0070588), “phosphate ion homeostasis” (GO: 0055062) and “cellular protein catabolic process” (GO: 0044257) (Tables 2; S2). The 4,115 genes with decreased expressions were identified to be enriched in 208 BP terms, such as “translation” (GO: 0006412), “polyamine catabolic process” (GO: 0006598) and “photosynthesis, light harvesting in photosystem I” (GO: 0009768) (Tables 2; S2). The DEGs were dispatched to 1,595 and 2,328 homologs in Arabidopsis, respectively. We assigned these genes to 905 pathways by MapMan. Among these pathways, the dysregulated genes were enriched in 55 pathways, with a cutoff of P value < 0.05.
Due to the large numbers and complex branch structures of GO categories, REVIGO was used to find representative subgroups of the terms using a simple clustering algorithm that relies on semantic similarity measures. The 171 BP terms enriched by genes with increased expressions were integrated into 10 groups (Fig. 2A), 37 terms were dispatched to “ribonucleoside monophosphate biosynthesis” subset, and 32 terms were classified to “response to absence of light” group. Moreover, 208 BP terms enriched by genes with decreased expressions were dispatched into 10 subsets (Fig. 2B), such as “translation” (including 52 terms) and “cellular response to sulfate starvation” (including 27 terms).
(A) REVIGO analysis results for genes up-regulated in S. salsa under salt stress. (B) REVIGO analysis results for genes down-regulated in S. salsa under salt stress. Each rectangle is a single cluster representative. The representatives are joined into “superclusters” of loosely related terms, visualized with different colors. Size of the rectangles was adjusted to reflect the P value of the GO term calculated by TopGO. In this study, 171 up-regulated processes were integrated into 10 groups, 13 subsets were summarized for 208 biological processes enriched by down-regulated genes.
Figure 3 illustrates the metabolism result of MapMan analysis. The KEGG pathway “plant hormone signal transduction” (ko04075) was enriched by 23 up-regulated unigenes, of which the cell enlargement-related sub-pathway “tryptophan metabolism” was enriched by auxin-responsive protein (AUXIAA, Cluster-12522.63856, L2fc = 1.341), auxin response factor (ARF, Cluster-12522.18986, L2fc = 5.928) and SAUR family protein (SAUR, Cluster-1,512.0, L2fc = 6.226); the stomatal closure regulation sub-pathway “carotenoid biosynthesis” was enriched by four up-regulated unigenes, including abscisic acid receptor PYR/PYL family protein (PYR, Cluster-12522.12070, L2fc = 4.312), protein phosphatase (PP2C, Cluster-12522.20854, L2fc = 9.005) and ABA responsive element binding factor (ABF, Cluster-12522.47885, L2fc = 2.532).
Global view of differently expressed genes (DEGs) involved in diverse metabolic pathways. DEGs genes were selected for the metabolic pathway analysis using the MapMan software (3.5.1 R2). The colored boxes indicate the Log2 of expression ratio of DEGs genes. The dys-regulated unigenes were assigned to 1,595 and 2,328 homologs in Arabidopsis, respectively. These genes were mapped to 905 pathways by MapMan, of which, 55 pathways were filtered enriched by the dys-regulated genes with the cutoff p-value <0.05.
The differentially expressed transcription factors (TFs)
In the present study, we found that 2,656 unigenes were dispatched to 47 TF families (Table S3), and 293 differentially expressed TFs were found in NaCl-treated leaf samples, including 145 genes with increased expressions and 148 gens with decreased expressions (Table S3). Of the up-regulated TFs, the largest number of up-regulated genes was found in HB (18 unigenes), followed by MYB (13 unigenes) and bZIP families (10 unigenes). Conversely, the largest number of down-regulated genes was found in MYB (20 unigenes), followed by the bHLH and AP2/ERF families, which contained 13 and 10 unigenes with decreased expressions, respectively (Table 3).
Real-time quantitative PCR (RT-qPCR) validation
To verify the RNA-Seq results, an alternative strategy was selected for the dysregulated unigenes. Four up-regulated and four down-regulated unigenes were selected for RT-qPCR validation with the same RNA samples used for RNA-Seq. Primers spanning exon-exon junctions were designed (Table S4). Figure 4 reveals that these two methods demonstrated similar gene expression profiling in most cases. For example, the ortholog of salt stress responding gene ITN1, Cluster-12522.40169, was significantly increased by RT-qPCR method (Fig. 4), and it was also an up-regulated unigene in the salt-treated samples by RNA-Seq (L2fc = 1.573).
Validation of RNA-Seq results by qRT-PCR using ten S. salsa dys-regulated genes. The expression levels of ten selected differentially expressed genes under control and salt stress are shown. A red color indicates that the gene is highly expressed under the corresponding treatment. Log2(FPKM) means Log2() value of FPKM for unigenes.
Discussion
Among the most serious environmental factors, salt stress greatly affects the development and yield of crops worldwide. External salt concentrations severely inhibit photosynthesis in glycophytes1,5,57,58, while halophytes maintain or have enhanced photosynthesis and ion balance at these salt concentrations36,37,59. S. salsa, a euhalophyte plant with salt-diluting ability, can adapt to high salinity, and its photosystem (PS) II shows high resistance to salt stress41,44,60,61,62,63. Many previous studies have shown the responses of S. salsa under salt stress. However, the underlying mechanisms of salt deposition via ion compartmentalization, osmotic adjustment and transcriptional regulation remain largely unclear. Therefore, we attempted to explore the essential salt responding genes and their modulators in S. salsa. Our transcriptome analysis provided valuable insights into the molecular mechanisms of salt tolerance and insulation of photosynthesis in S. salsa leaves.
Salt stress induces damage primarily through osmotic and ion stresses. Therefore, halophytes can resist to salt stress due to their ability to adjust osmotic state and ion balance14,28,64. The excess Na+, Cl− and oxidative stress in the intracellular or extracellular environment activate the osmotic adjustment or homeostasis regulating salt stress responses27,28. In salt-diluting halophyte, the vacuole is supposed to absorb excessive Na+ and Cl− for ion sequestration and balance adjustment. Na+ generally enters cells via ion transporters, such as potassium transporter (KT)27,28,29. Guo et al.65 have shown that the expression levels of Na+/H+ exchanger, V-H+ ATPase, choline monooxygenase, potassium and chloride channels are up-regulated in S. salsa leaves upon 500-mM saline treatment, which can reduce the over-accumulation of Na+ and Cl−. Our transcriptomic data showed that the expressions of KT-encoding genes were increased to enhance protein yield to absorb more ions, such as K+ efflux antiporter 3 (Cluster-12522.45367, L2fc = 7.991). Furthermore, calcium ion transmembrane transport participating cation exchanger 3 (Cluster-12522.69849, L2fc = 6.425) and 5 (Cluster-12522.41534, L2fc = 3.393) were found to be highly expressed under salt stress, indicating their functions in transporting ions in S. salsa. Besides, excess Cl- was predicted to be transported by chloride channel B (Cluster-12522.3333, L2fc = 3.546) and C (Cluster-12522.30526, L2fc = 3.828).
In plants, salt stress-triggered ion injury and osmotic stress usually affect a set of basic biosynthetic functions27,28. As one of the most sensitive physiological indices, photosynthesis is susceptible to salt stress7,44,49,50. Although S. salsa shows significant resistance not only to salinity stress but also to photoinhibition even when exposed to 400 mM NaCl or full sunlight41,60,61, the photosynthesis rate is decreased by Cl− treatments66. In this study, the BP term “photosynthesis, light harvesting in photosystem I” (GO: 0009768) was enriched by 19 down-regulated genes. For example, photosystem I light harvesting complex gene 1 (Cluster-12522.54286, L2fc = −3.698), gene 3 (Cluster-12522.42577, L2fc = −2.321) and chlorophyll A/B binding protein 1 (Cluster-12522.36469, L2fc = −3.821) were down-regulated under salt stress, indicating the impairment of PSI light harvesting systems in S. salsa. Furthermore, photosystem b protein 33 (PSB33) is associated with the chloroplast thylakoid membrane and provides stability to PSII in Arabidopsis39,67. In the present study, homolog of PSB33 (Cluster-12522.32409, L2fc = 9.833) was up-regulated in NaCl-treated leaves in S. salsa. Besides, neoxanthin acts as an antioxidant within the PSII supercomplex in thylakoids, involving in the photoprotection of PSII67. In this study, the expressions of neoxanthin biosynthesis-required gene abscisic acid-deficient 4 (ABA4, Cluster-12522.63197, L2fc = 1.103) was increased when exposed to salt stress. Our transcriptomic data provided solid evidence supporting the tolerance of PSII to salt stress for euhalophyte S. salsa68.
Saline stress inevitably results in the ROS overproduction in plants. Therefore, the activation of the ROS scavenging system is necessary for the plant to avoid additional oxidative stress69,70. An effective enzymatic antioxidant defense system has been evolved by plants for scavenging ROS71,72,73. In this study, the expressions of ascorbate peroxidase (APX), glutathione S-transferase (GST) and glutathione peroxidase (GPX) were increased to varying degrees to avoid oxidative stress induced by salinity, including ascorbate peroxidase 1 (Cluster-12522.1335, L2fc = 9.348), glutathione S-transferase TAU9 (Cluster-12522.44190, L2fc = 4.923), glutathione S-transferase PHI8 (Cluster-12522.25968, L2fc = 8.422) and glutathione peroxidase 4 (Cluster-12522.20682, L2fc = 8.949). Our transcriptomic data showed that S. salsa leaves could resist the oxidative stress caused by high salinity by recruiting the ROS scavenging system.
TFs play critical roles in salt tolerance in plants via transcriptional regulation of the downstream genes responsible for response to salt challenges. Members of several TF families were verified to control and modulate salt stress adaptive pathways, as bZIP, WRKY, ERF/AP2, HB, MYB and bHLH74,75,76,77. The HB family TFs with homeodomain-leucine zipper domain are transcriptionally regulated in an ABA-dependent manner and may act in a signal transduction pathway which mediates abiotic stress response. In the present study, 18 and one HB TFs were up-regulated and down-regulated in NaCl-treated samples, respectively, including homeobox 7 (Cluster-12522.23710, L2fc = 2.558) and BEL1-like homeodomain 2 (Cluster-12522.57518, L2fc = 3.612). The MYB family members have been proved to be key factors in regulatory networks of abiotic stresses75,77. In our current study, 13 and 20 MYB family TFs were up-regulated and down-regulated in NaCl-treated samples, respectively, including MYB domain protein 78 (Cluster-10,720.0, L2fc = 3.050) and Reveille 8 (Cluster-12522.18843, L2fc = 3.777). Numbers of bZIP proteins isolated from diverse species, including Arabidopsis, rice, tomato and halophytes, can enhance the salt tolerance ability77. Moreover, 10 bZIP family members were up-regulated in salt-treated samples in this analysis, such as unfertilized embryo sac 12 (Cluster-12522.12729, L2fc = 8.992) and iaa-leucine resistant 3 (Cluster-12,694.1, L2fc = 2.701). The spatio-temporal gene expression patterns of these TFs and novel genes involved in RNA processing in S. salsa could be helpful in understanding the transcriptional regulation in euhalophytes under salt stress.
Plant hormones, especially auxin, ethylene and jasmonic acid signaling transduction pathways, were all up-regulated in response to saline treatment in S. salsa, which are important to gene regulations of ion transport and antioxidation65. It has been well documented that as an endogenous signaling molecule, ABA enables plants to survive under salt stress78,79. In the present study, we investigated the ABA signaling pathway in response to saline stress in the leaves of S. salsa, and found that a part of molecular mechanism responding to NaCl could be attributed to the ABA-dependent signaling pathway. The osmotic stress-induced ABA signaling component aldehyde dehydrogenase 7B4 (Cluster-12522.47012, L2fc = 7.613) and aldehyde dehydrogenase 3H1 (Cluster-12522.7455, L2fc = 1.033)80 are dramatically activated in NaCl-treated leaves. Besides, the expressions of MYB/NAC TF family members were increased when exposed to salt stress in this study, including ABA-induced MYB domain protein 78 (Cluster-10,720.0, L2fc = 3.050) and NAC domain-containing protein 83 (Cluster-12522.39867, L2fc = 1.533). Thus, ABA might exert direct effects on MYB/NAC TFs and modulate salt-resistance in S. salsa under salt stress.
Conclusions
In the present study, a transcriptome analysis was carried out to assess the salt stress responses in S. salsa leaves. RNA-Seq revealed that the expressions of 3,638 unigenes were increased when exposed to salt stress, while 4,115 unigenes were down-regulated in S. salsa. Moreover, GO, MapMan and KEGG enrichment analyses supported that hundreds of pathways were involved in salt stress response in S. salsa, such as ion transport and sequestration as well as photoprotection of PSII. The GO enrichment analysis indicated that genes associated with ion transport, ROS scavenging and TFs were highly expressed under salt stress. The excessive Na+ and Cl− were transported into the vacuole for ion sequestration and balance adjustment by highly expressed potassium transporters (such as KEA3). In addition, various candidate genes associated with photosynthesis (such as PSB33 and ABA4), ROS (such as TAU9 and PHI8) and transcriptional regulation (HB-7 and MYB78) pathways were predicted to ameliorate salt stress-induced damage in S. salsa.
Materials and Methods
Plant material and stress treatments
Seeds of S. salsa were collected at the Yellow River Delta, Dongying, China (37 °7′38″N; 118 °41′28″E), in October 2017. The plump seeds were firstly screened, disinfected with 75% alcohol for 2 min, and then washed by water. After vernalization at low temperature (4 °C) for 3 days and germination for 2 days, the seedlings of S. salsa were grown in plastic pots (14 cm in diameter and 13 cm in height) filled with sands in a greenhouse under the conditions of 15/9-h light/dark cycle at temperature (28 ± 3/20 ± 3 °C, day/night) with illumination of 600 μmol m−2 s−1, and half-strength Hoagland nutrient solution was given daily.
No physiological interpretation of the data was included in this study because the design of this study referenced several existing studies demonstrating the changes/regulations of S. salsa under salt stress at the morphological and physiological levels. Lu et al.60 and Sui et al.81 have demonstrated the physiological meaning of salt treatment/absence for S. salsa. Compared with the control (0 mM NaCl treatment) group, the growth of S. salsa is significantly increased by salt treatment. Sui et al.81 have shown that seedlings with 2–3 branches are subjected to 300 mM NaCl treatment, and the growth of S. salsa is significantly increased. PSII is rather tolerant to NaCl, and salt stress has no effect on PSII photochemistry in dark-adapted leaves. Photosynthetic electron transport is increased under salt stress. Although 400–500 mM NaCl is regarded as high salinity for S. salsa, 300 mM NaCl is the inflection point of the growth, ion accumulation and enzymatic antioxidant defense system for scavenging of ROS81. Given these above-mentioned physiological evidence, 300 mM NaCl was selected for salt stress treatment.
Vigorous seedlings were selected and transferred into plastic pots containing well-washed river sand (three plants per pot) when the sixth leaf emerged. NaCl was dissolved in the full-strength Hoagland nutrient solution Plants of control group was irrigated with full-strength Hoagland nutrient solution (0 mM NaCl), while others were exposed to 300 mM NaCl. The NaCl level was gradually increased by 50 mM per day to avoid osmotic shock. After 7 days, the seedlings were selected to determine the indices. Three replicates of each treatment were sampled for transcriptome sequencing.
Illumina library construction and sequencing
Sequencing libraries were generated using the NEBNext® UltraTM RNA Library Prep Kit for Illumina® (NEB, USA) based on the manufacturer’s instructions, and index codes were added to attribute sequences to each sample. Briefly, mRNA was purified from total RNA using poly-T oligo-attached magnetic beads. The first-strand cDNA was synthesized using random hexamer primer and M-MuLV Reverse Transcriptase (RNase H−). Second-strand cDNA was synthesized using DNA polymerase I and RNase H. The AMPure XP system (Beckman Coulter, Beverly, USA) was employed to purify cDNA fragments of 150~200-bp. The size-selected, adaptor-ligated fragments were purified and enriched by PCR amplification. The resulting products were used for sequencing analysis. The Illumina HiSeq X platform (Illumina, San Diego, CA, USA) was used to perform high-throughput sequencing. The full assembly data were submitted to the NCBI Sequence Read Archive (SRA) database (https://www.ncbi.nlm.nih.gov/sra), SRA accession: PRJNA527358. The processed data files including the assembled sequences and abundance measurements were uploaded to the Gene Expression Omnibus (GEO) database (https://www.ncbi.nlm.nih.gov/geo/), GEO accession: GSE145366.
De novo assembly of the S. salsa transcriptome
RNA sequencing and de novo transcriptome assembly were conducted to create reference sequence libraries for S. salsa. For each species, an RNA sample of every accession was separately sequenced. cDNA library construction and Illumina paired-end 150 bp sequencing (PE150) were performed at Novogene Co., LTD. (http://www.novogene.com/) according to instructions provided by Illumina Inc. Raw reads of FASTQ format were firstly processed through in-house perl scripts. In this step, clean reads were obtained by removing adapter-containing reads, ploy-N-containing reads and low-quality reads from raw data. Meanwhile, Q20, Q30, GC content and sequence duplication level of the clean data were calculated. All the downstream analyses were carried out based on high-quality clean data. The remaining high-quality reads were used for transcriptome assembly using the Trinity software pipeline with default parameters82. Clean data sets of three accessions were pooled for de novo assembly and comprehensive sequence library construction in each studied species. De novo assembled unigene sequences were used for BLAST searches and annotation against public databases (NR, NT, Swiss-Prot, Pfam, KOG/COG, Swiss-Prot, KEGG Ortholog database and Gene Ontology) with an E-value threshold of 1e−5.
Determination of gene expression in S. salsa
Six independent transcript libraries were generated for three accessions of S. salsa by a PE150 sequencing analysis. Gene expression levels for all samples were estimated by RSEM83. The clean reads were aligned to the de novo assembled transcriptome. Gene expression levels in leaf samples of S. salsa were calculated by the FPKM method84. The expression levels between salt-treated and control samples were compared according to the FPKM values, with a cutoff of Padj <0.05 and L2fc >1.
GO, MapMan and KEGG annotation and enrichment
The unigenes of S. salsa were mapped to A. thaliana gene IDs by sequence similarity searching against the genome of A. thaliana with an E-value cutoff of 1e−5. The topGO package of R85 was used to perform the GO enrichment analysis for DEGs in NaCl-treated samples. The DEGs in S. salsa were annotated onto metabolic pathways using MapMan (version 3.5.1 R2)86. The DEGs of S. salsa unigene IDs were transferred to the Arabidopsis TAIR locus IDs during the MapMan analysis. The software KOBAS was used to test the statistical enrichment of DEGs in KEGG pathways in S. salsa87.
RT-qPCR verification
The expression patterns revealed by the RNA-Seq analysis were validated using the RT-qPCR. The extracted RNA samples were treated with DNaseI and reversely transcribed into cDNA using the PrimeScript RT Reagent Kit with gDNA Eraser (Takara, Dalian, China). Five up-regulated and five down-regulated unigenes in S. salsa were selected for the RT-qPCR assay, including Cluster-12522.45367 (L2fc = 7.991), Cluster-12522.53520 (L2fc = 4.528), Cluster-12522.17737 (L2fc = 3.142), Cluster-12522.41761 (L2fc = 2.866), Cluster-12522.40169 (L2fc = 1.573), Cluster-12522.20378 (L2fc = −12.625), Cluster-12522.23459 (L2fc = −7.392), Cluster-12522.35873 (L2fc = −4.763), Cluster-12522.35661 (L2fc = −4.545) and Cluster-12522.33399 (L2fc = −3.283). Ortholog of the A. thaliana member of actin gene family ACT7 in S. salsa (Cluster-12522.36997) was used as the housekeeping gene. Premier 5.0 software was employed to design gene-specific qRT-PCR primers (18–20 bp) (Table S4). qPCR was performed using SYBR Green qPCR Master Mix (DBI, Germany) on an ABI7500 Real-Time PCR System (ABI, USA). Three replicates were performed for each experiment, and the amplification specificity was evaluated by melting curve analysis. Relative expressions of target genes were calculated using the 2−ΔΔCt method. All values were presented as the mean ± standard deviation (SD). Significant differences were determined using GraphPad software (version: 5.0). The t-test was used to analyze the relationship between the expressions of control and NaCl-treated samples.
Data archiving statement
All genetic data have been submitted to the NCBI Sequence Read Archive (SRA) database (https://submit.ncbi.nlm.nih.gov/subs/sra), PRJNA527358 and the Gene Expression Omnibus (GEO) database (https://www.ncbi.nlm.nih.gov/geo/), GSE145366.
Consent for publication
We have carefully read and adhered to editorial policies for manuscripts. We declare that the content of this manuscript has not been published or submitted for publication elsewhere.
Data availability
We declare that the all data and materials of this manuscript including the supplementary datasets are available to the journal and all readers.
References
Munns, R. & Tester, M. Mechanisms Salinity Tolerance. Annu. Rev. Plant. Biol. 59, 651–681 (2008).
Yuan, F. et al. Comparative transcriptome analysis of developmental stages of the Limonium bicolor leaf generates insights into salt gland differentiation. Plant. Cell. Environ. 38, 1637–1657 (2015).
Kafkafi, U. & Xu, G. Encyclopedia of Soil Science. Taylor & Francis (2006).
Chapman, V. J. The New Perspective in the Halophytes. Q. Rev. Biol. 17, 291–311 (1942).
Bose, J. et al. Chloroplast function and ion regulation in plants growing on saline soils: lessons from halophytes. J. Exp. Bot. 68, 3129 (2017).
Waisel, Y. Biology of Halophytes. Q. Rev. Biol. (1972).
Duan, H. M. et al. Effect of combined waterlogging and salinity stresses on euhalophyte Suaeda glauca. Plant. Physiol. Bioch. 127, 231–237 (2018).
Guo, J. R., Li, Y. D., Han, G. L., Song, J. & Wang, B. S. NaCl markedly improved the reproductive capacity of the euhalophyte Suaeda salsa. Funct. Plant. Biol. 45, 350–361 (2018).
Liu, R. R., Wang, L., Tanveer, M. & Song, J. Seed Heteromorphism: An Important Adaptation of Halophytes for Habitat Heterogeneity. Front. Plant. Sci. 9, 10 (2018).
Daoud, S., Harrouni, C., Huchzermeyer, B. & Koyro, H. W. Comparison of salinity tolerance of two related subspecies of Beta vulgaris: The sea beet (Beta vulgaris ssp. maritima) and the sugar beet (Beta vulgaris ssp. vulgaris). Biosaline Agriculture and High Salinity Tolerance 115–129 (2008).
Zhao, S. Z., Sun, H. Z., Chen, M. & Wang, B. S. Light-regulated betacyanin accumulation in euhalophyte Suaeda salsa calli. Plant. Cell. Tiss. Org. 102, 99–107 (2010).
Zhou, J. C. et al. The role of salinity in seed maturation of the euhalophyte Suaeda salsa. Plant. Biosyst. 150, 83–90 (2016).
Aslam, R. A critical review on halophytes: Salt tolerant plants. J. Med. Plants. Res. 5, 7108–7118 (2011).
Yuan, F., Guo, J. R., Shabala, S. & Wang, B. S. Reproductive Physiology of Halophytes: Current Standing. Front. Plant. Sci. 9, 13 (2019).
Leng, B. Y., Yuan, F., Dong, X. X., Wang, J. & Wang, B. S. Distribution pattern and salt excretion rate of salt glands in two recretohalophyte species of Limonium (Plumbaginaceae). S. Afr. J. Bot. 115, 74–80 (2018).
Luttge, U. Structure and Function of Plant Glands. Annu. Rev. Plant. Physiol. 22, 23–44 (1971).
Feng, Z. T. et al. Effects of NaCl stress on the growth and photosynthetic characteristics of Ulmus pumila L. seedlings in sand culture. Photosynthetica 52, 313–320 (2014).
Feng, Z. T. et al. Study on pathway and characteristics of ion secretion of salt glands of Limonium bicolor. Acta. Physiol. Plant. 36, 2729–2741 (2014).
Yuan, F., Leng, B. Y. & Wang, B. S. Progress in Studying Salt Secretion from the Salt Glands in Recretohalophytes: How Do Plants Secrete Salt? Front. Plant. Sci. 7 (2016).
Yuan, F., Liang, X., Li, Y., Yin, S. S. & Wang, B. S. Methyl jasmonate improves tolerance to high salt stress in the recretohalophyte Limonium bicolor. Funct. Plant. Biol. 46, 82–92 (2019).
Song, J. et al. The role of the seed coat in adaptation of dimorphic seeds of the euhalophyte Suaeda salsa to salinity. Plant. Spec. Biol. 32, 107–114 (2017).
Guo, J. R., Suo, S. S. & Wang, B. S. Sodium chloride improves seed vigour of the euhalophyte Suaeda salsa. Seed. Sci. Res. 25, 335–344 (2015).
Han, N. et al. Expression of a Suaeda salsa Vacuolar H+/Ca2+ Transporter Gene in Arabidopsis Contributes to Physiological Changes in Salinity. Plant. Mol. Biol. Rep. 30, 470–477 (2012).
He, M., He, C. Q. & Ding, N. Z. Abiotic Stresses: General Defenses of Land Plants and Chances for Engineering Multistress Tolerance. Front. Plant. Sci. 9, 18 (2018).
Hasanuzzaman, M. et al. Potential use of halophytes to remediate saline soils. (2015).
Liu, Q. Q., Liu, R. R., Ma, Y. C. & Song, J. Physiological and molecular evidence for Na+ and Cl− exclusion in the roots of two Suaeda salsa populations. Aquat. Bot. 146, 1–7 (2018).
Zhu, J. K. Regulation of ion homeostasis under salt stress. Curr. Opin. Plant. Biol. 6, 441–445 (2003).
Zhu, J. K. Plant salt tolerance. Trends. Plant. Sci. 6, 66–71 (2001).
Shao, Q., Han, N., Ding, T. L., Zhou, F. & Wang, B. S. SsHKT1;1 is a potassium transporter of the C-3 halophyte Suaeda salsa that is involved in salt tolerance. Funct. Plant. Biol. 41, 790–802 (2014).
Bai, B. et al. OsBBX14 delays heading date by repressing florigen gene expression under long and short-day conditions in rice. Plant. Sci. 247, 25–34 (2016).
Bose, J., Rodrigomoreno, A. & Shabala, S. ROS homeostasis in halophytes in the context of salinity stress tolerance. J. Exp. Bot. 65, 1241 (2014).
Han, G. L. et al. The CCCH zinc finger protein gene AtZFP1 improves salt resistance in Arabidopsis thaliana. Plant. Mol. Biol. 86, 237–253 (2014).
Han, N., Shao, Q., Bao, H. Y. & Wang, B. S. Cloning and Characterization of a Ca2+/H+ Antiporter from Halophyte Suaeda salsa L. Plant. Mol. Biol. Rep. 29, 449–457 (2011).
Zhao, Y. Q. et al. Utilisation of stored lipids during germination in dimorphic seeds of euhalophyte Suaeda salsa. Funct. Plant. Biol. 45, 1009–1016 (2018).
Zhao, Y. Q., Yang, Y., Song, Y. P., Li, Q. & Song, J. Analysis of storage compounds and inorganic ions in dimorphic seeds of euhalophyte Suaeda salsa. Plant. Physiol. Bioch. 130, 511–516 (2018).
Song, J., Shi, G. W., Gao, B., Fan, H. & Wang, B. S. Waterlogging and salinity effects on two Suaeda salsa populations. Physiol. Plantarum. 141, 343–351 (2011).
Song, J. & Wang, B. S. Using euhalophytes to understand salt tolerance and to develop saline agriculture: Suaeda salsa as a promising model. Ann. Bot-London. 115, 541–553 (2015).
Song, J. et al. Effects of salinity and nitrate on production and germination of dimorphic seeds applied both through the mother plant and exogenously during germination in Suaeda salsa. Plant. Spec. Biol. 31, 19–28 (2016).
Li, K. et al. Overexpression of Suaeda salsa stroma ascorbate peroxidase in Arabidopsis chloroplasts enhances salt tolerance of plants. S. Afr. J. Bot. 78, 235–245 (2012).
Sui, N. Photoinhibition of Suaeda salsa to chilling stress is related to energy dissipation and water-water cycle. Photosynthetica 53, 207–212 (2015).
Sui, N., Li, M., Li, K., Song, J. & Wang, B. S. Increase in unsaturated fatty acids in membrane lipids of Suaeda salsa L. enhances protection of photosystem II under high salinity. Photosynthetica 48, 623–629 (2010).
Chen, M., Song, J. & Wang, B. S. NaCl increases the activity of the plasma membrane H+-ATPase in C-3 halophyte Suaeda salsa callus. Acta. Physiol. Plant. 32, 27–36 (2010).
Li, W. et al. Salt Tolerance is Conferred in Arabidopsis by Overexpression of the Vacuolar Na+/H+ Antiporter Gene SsNHX2, an Alternative Splicing Variant of SsNHX1, from Suaeda salsa. J. Integr. Plant. Biol. 52, 147 (2009).
Yang, M. F., Song, J. & Wang, B. S. Organ-Specific Responses of Vacuolar H+-ATPase in the Shoots and Roots of C-3 Halophyte Suaeda salsa to NaCl. J. Integr. Plant. Biol. 52, 308–314 (2010).
Yan-Yan, L. I., Ping-Hua, L. I. & Wang, B. S. Cloning and Expression of Subunit H of V-H+-ATPase in Vacuole Membrane in the Leaves of the Halophyte Suaeda salsa Under Salt Stress. Acta Botanica Boreali-Occidentalia Sinica 46, 93–99 (2006).
Xu, J. J. et al. Whole transcriptome analysis using next-generation sequencing of model species Setaria viridis to support C-4 photosynthesis research. Plant. Mol. Biol. 83, 77–87 (2013).
Yamamoto, N. et al. Comprehensive analysis of transcriptome response to salinity stress in the halophytic turf grass Sporobolus virginicus. Front. Plant. Sci. 6, 241 (2015).
Lin, J. et al. Transcriptome profiling of genes involved in photosynthesis in Elaeagnus angustifolia L. under salt stress. Photosynthetica 56, 998–1009 (2018).
Yang, S. et al. Transcriptome and Differential Expression Profiling Analysis of the Mechanism of Ca2+ Regulation in Peanut (Arachis hypogaea) Pod Development. Front. Plant. Sci. 8, 1609 (2017).
Yang, Z. et al. Transcription Profiles of Genes Related to Hormonal Regulations Under Salt Stress in Sweet Sorghum. Plant. Mol. Biol. Rep. 35, 586–599 (2017).
Yuan, F., Lyu, M. J. A., Leng, B. Y., Zhu, X. G. & Wang, B. S. The transcriptome of NaCl-treated Limonium bicolor leaves reveals the genes controlling salt secretion of salt gland. Plant. Mol. Biol. 91, 241–256 (2016).
Zhang, H. et al. Transcript profile analysis reveals important roles of jasmonic acid signalling pathway in the response of sweet potato to salt stress. Sci. Rep-Uk. 7, 40819 (2017).
Zhang, L. Y., Zhang, X. J. & Fan, S. J. Meta-analysis of salt-related gene expression profiles identifies common signatures of salt stress responses in Arabidopsis. Plant. Syst. Evol. 303, 757–774 (2017).
Cui, F. et al. Identification of Metabolites and Transcripts Involved in Salt Stress and Recovery in Peanut. Front. Plant. Sci. 9, 16 (2018).
Sui, N. et al. Transcriptomic and Physiological Evidence for the Relationship between Unsaturated Fatty Acid and Salt Stress in Peanut. Front. Plant. Sci. 9, 12 (2018).
Zhang, Z., Wang, J., Zhang, R. & Huang, R. The ethylene response factor AtERF98 enhances tolerance to salt through the transcriptional activation of ascorbic acid synthesis in Arabidopsis. Plant. Mol. Biol. 71, 273 (2012).
Percey, W. J. et al. Salinity effects on chloroplast PSII performance in glycophytes and halophytes1. Funct. Plant. Biol. 43 (2016).
Sergey, S., Jayakumar, B. & Rainer, H. Salt bladders: do they matter? Trends. Plant. Sci. 19, 687–691 (2014).
Flowers, T. J. & Colmer, T. D. Salinity tolerance in halophytes. New. Phytol. 179, 945–963 (2010).
Congming, L. U., Qiu, N., Qingtao, L. U., Wang, B. & Kuang, T. Does salt stress lead to increased susceptibility of photosystem II to photoinhibition and changes in photosynthetic pigment composition in halophyte Suaeda salsa grown outdoors? Plant. Sci. 163, 1063–1068 (2002).
Qiu, N., Lu, Q. & Lu, C. Photosynthesis, Photosystem II Efficiency and the Xanthophyll Cycle in the Salt-Adapted Halophyte Atriplex centralasiatica. New. Phytol. 159, 479–486 (2003).
Wang, F. X. et al. Salinity affects production and salt tolerance of dimorphic seeds of Suaeda salsa. Plant. Physiol. Bioch. 95, 41–48 (2015).
Cheng, S. et al. Salinity improves chilling resistance in Suaeda salsa. Acta. Physiol. Plant. 36, 1823–1830 (2014).
Shabala, S. & Munns, R. Salinity stress: physiological constraints and adaptive mechanisms. Plant Stress Physiology (2012).
Guo, S. M., Tan, Y., Chu, H. J., Sun, M. X. & Xing, J. C. Transcriptome sequencing revealed molecular mechanisms underlying tolerance of Suaeda salsa to saline stress. Plos One 14(7), e0219979 (2019).
Li, Y. D., Guo, J. R. & Wang, B. S. Effects of sodium salt and chloride on vegetative growth of euhalophyte Suaeda salsa. Plant physiology journal 54, 421–428 (2018).
Rikard, F. et al. PHOTOSYSTEM II PROTEIN33, a protein conserved in the plastid lineage, is associated with the chloroplast thylakoid membrane and provides stability to photosystem II supercomplexes in Arabidopsis. Plant. Physiol. 167, 481–492 (2015).
Dall’Osto, L., Cazzaniga, S., North, H., Marion-Poll, A. & Bassi, R. The Arabidopsis aba4-1 mutant reveals a specific function for neoxanthin in protection against photooxidative stress. Plant. Cell. 19, 1048–1064 (2007).
Apel, K. & Hirt, H. REACTIVE OXYGEN SPECIES: Metabolism, Oxidative Stress, and Signal Transduction. Annu. Rev. Plant. Biol. 55, 373–399 (2004).
Sui, N., Tian, S. S., Wang, W. Q., Wang, M. J. & Fan, H. Overexpression of Glycerol-3-Phosphate Acyltransferase from Suaeda salsa Improves Salt Tolerance in Arabidopsis. Front. Plant. Sci. 8, 1337 (2017).
Liu, S. S., Wang, W. Q., Li, M., Wan, S. B. & Sui, N. Antioxidants and unsaturated fatty acids are involved in salt tolerance in peanut. Acta. Physiol. Plant. 39, 207 (2017).
Gill, S. S. & Tuteja, N. Reactive oxygen species and antioxidant machinery in abiotic stress tolerance in crop plants. Plant. Physiol. Bioch. 48, 909–930 (2010).
Blokhina, O., Virolainen, E. & Fagerstedt, K. V. Antioxidants, oxidative damage and oxygen deprivation stress: a review. Ann. Bot. 91, 179–194 (2003).
Jaradat, M. R., Feurtado, J. A., Huang, D., Lu, Y. & Cutler, A. J. Multiple roles of the transcription factor AtMYBR1/AtMYB44 in ABA signaling, stress responses, and leaf senescence. Bmc. Plant. Biol. 13, 192 (2013).
Golldack, D., Lüking, I. & Yang, O. Plant tolerance to drought and salinity: stress regulating transcription factors and their functional significance in the cellular transcriptional network. Plant. Cell. Rep. 30, 1383–1391 (2011).
Zhu, J. K. Salt and drought stress signal transduction in plants. Annu. Rev. Plant. Biol. 53, 247–273 (2002).
Hsieh, T. H. et al. A tomato bZIP transcription factor, SlAREB, is involved in water deficit and salt stress response. Planta 231, 1459–1473 (2010).
Raghavendra, A. S., Gonugunta, V. K., Christmann, A. & Grill, E. ABA perception and signalling. Trends. Plant. Sci. 15, 395–401 (2010).
Ryu, H. & Cho, Y. G. Plant hormones in salt stress tolerance. J. Plant. Biol. 58, 147–155 (2015).
Missihoun, T. D., Quancan, H. & Daniela, M. & Dorothea, B. Sequence and functional analyses of the aldehyde dehydrogenase 7B4 gene promoter in Arabidopsis thaliana and selected Brassicaceae: regulation patterns in response to wounding and osmotic stress. Chem-Asian J. 10, 1281–1298 (2014).
Sui, N., Li, M., Li, K., Song, J. & Wang, B. S. Increase in unsaturated fatty acids in membrane lipids of Suaeda salsa L. enhances protection of photosystem II under high salinity. Photosynthetica 48, 623–629 (2010).
Grabherr, M. G. et al. Full-length transcriptome assembly from RNA-Seq data without a reference genome. Nat. Biotechnol. 29, 644 (2011).
Bo, L. & Dewey, C. N. RSEM: accurate transcript quantification from RNA-Seq data with or without a reference genome. Bmc. Bioinformatics. 12(1), 323 (2011).
Haas, B. J. et al. De novo transcript sequence reconstruction from RNA-seq using the Trinity platform for reference generation and analysis. Nat. Protoc. 8, 1494–1512 (2013).
Alexa, A. & Rahnenfuhrer, J. topGO: Enrichment analysis for Gene Ontology. R Package Version (2006).
Thimm, O. et al. MAPMAN: a user-driven tool to display genomics data sets onto diagrams of metabolic pathways and other biological processes. Plant. J. 37, 914–939 (2010).
Chen, X. et al. KOBAS 2.0: a web server for annotation and identification of enriched pathways and diseases. Nucleic. Acids. Res. 39, 316–322 (2011).
Acknowledgements
This work was supported by National Natural Science Foundation of China (31800185, 31470298) and the Science and Technology Development Foundation of Shandong Province (2018LZGC038). A Project of Shandong Province Higher Educational Science and Technology Program (J18KA147), Shandong Forestry Science and Technology Innovation Project (LYCX01-2018-01) and Shandong Provincial Agricultural Elite Varieties Project (2019LZGC018).
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X.J.Z., Y.Y. and X.T.L., conceived and designed the study. X.J.Z., Y.Y. and X.T.L. performed the data collection and analysis. X.J.Z. and Y.Y. wrote the paper. L.Y.Z., S.J.F. and X.J.Z. reviewed and edited the manuscript. All authors read and approved the manuscript.
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Zhang, X., Yao, Y., Li, X. et al. Transcriptomic analysis identifies novel genes and pathways for salt stress responses in Suaeda salsa leaves. Sci Rep 10, 4236 (2020). https://doi.org/10.1038/s41598-020-61204-x
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DOI: https://doi.org/10.1038/s41598-020-61204-x
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