Abstract
Background
Calcineurin B-like protein (CBL)-interacting protein kinases (CIPKs) are the primary components of calcium sensors, and play crucial roles in plant developmental processes, hormone signaling transduction, and in the response to exogenous stresses.
Results
In this study, 48 CIPK genes (SsCIPKs) were identified from the genome of Saccharum spontaneum. Phylogenetic reconstruction suggested that the SsCIPK gene family may have undergone six gene duplication events from the last common ancestor (LCA) of SsCIPKs. Whole-genome duplications (WGDs) served as the driving force for the amplification of SsCIPKs. The Nonsynonymous to synonymous substitution ratio (Ka/Ks) analysis showed that the duplicated genes were possibly under strong purifying selection pressure. The divergence time of these duplicated genes had an average duplication time of approximately 35.66 Mya, suggesting that these duplication events occurred after the divergence of the monocots and eudicots (165 Mya). The evolution of gene structure analysis showed that the SsCIPK family genes may involve intron losses. Ten ScCIPK genes were amplified from sugarcane (Saccharum spp. hybrids). The results of real-time quantitative polymerase chain reaction (qRT-PCR) demonstrated that these ten ScCIPK genes had different expression patterns under abscisic acid (ABA), polyethylene glycol (PEG), and sodium chloride (NaCl) stresses. Prokaryotic expression implied that the recombinant proteins of ScCIPK3, − 15 and − 17 could only slightly enhance growth under salinity stress conditions, but the ScCIPK21 did not. Transient N. benthamiana plants overexpressing ScCIPKs demonstrated that the ScCIPK genes were involved in responding to external stressors through the ethylene synthesis pathway as well as to bacterial infections.
Conclusions
In generally, a comprehensive genome-wide analysis of evolutionary relationship, gene structure, motif composition, and gene duplications of SsCIPK family genes were performed in S. spontaneum. The functional study of expression patterns in sugarcane and allogenic expressions in E. coli and N. benthamiana showed that ScCIPKs played various roles in response to different stresses. Thus, these results improve our understanding of the evolution of the CIPK gene family in sugarcane as well as provide a basis for in-depth functional studies of CIPK genes in sugarcane.
Supplementary Information
The online version contains supplementary material available at 10.1186/s12864-020-07264-9.
Keywords: Sugarcane, CIPK, Genome-wide, Evolution, Biotic stress, Abiotic stress
Background
Throughout the life cycle, plants are often subjected to various environmental situations, including saline soil damage, drought, extreme temperature, and pathogens. To date, plants have evolved complex physiological and genetic mechanisms to cope with these adverse environmental conditions for their growth and development [1, 2]. For instance, when plants respond and adapt to stresses, many stress-related genes are induced [3–5], and a variety of stress resistance-related functional proteins accumulate [6–10]. Calcium has emerged as a ubiquitous second messenger that is involved in multiple physiological, developmental, and signal transduction pathways [11–13]. In plants, the levels of intracellular calcium are modulated in response to a diverse array of signals, including abiotic stresses, biotic stresses, exogenous stimuli, and perform physiological activities [14–17]. The level of regulation in calcium signaling can be achieved via calcium-binding proteins [18–20]. These sensor proteins recognize specific calcium signatures and relay these signals to downstream responses, such as phosphorylation cascades, which in turn regulate gene expression [19].
CIPKs specifically target CBLs to transduce the perceived calcium signal, which belongs to the Ca2+-mediated CBL-CIPK network, and respond to diverse stimuli [21, 22]. CIPKs are also designated as SNF1-related protein kinases 3 (SnRK3), which is a group of SnRK belonging to the Ser/Thr protein kinase superfamily CDPK-SnRKs [23]. CIPKs contain three domains, including an N- terminal kinase domain, variable auto-inhibitory domain, and a C-terminal regulatory domain [24, 25]. The N-terminal kinase domain consists of a putative activation loop between the DFG (Asp, Phe, Gly) and APE (Ala, Pro, Glu) motifs. The C-terminal regulatory domain, which consists of 24-amino acid motif, is designated as the NAF/FISL domain (protein families database accession no. PF03822) [11]. The NAF/FISL domain plays a vital role in mediating interactions with CBLs [26].
With the completion of genome-wide sequencing, a number of genes in multigene families have been identified. Based on the available genomic data, 25 CIPKs in Arabidopsis thaliana [11], 34 CIPKs in Oryza sativa [13], 43 CIPKs in Zea mays [27], and 25 CIPKs in Manihot esculenta [12] have been identified. As reported, CIPK genes are important in responding to various biotic and abiotic stresses, such as low-temperature, drought, and salt stresses. Luo et al. [28] discovered that the ectopic expression of BdCIPK31 can enhance low-temperature tolerance in tobacco. BdCIPK31 also plays a role in regulating plant responses to drought and salt stresses [29]. ZmCIPK16 is believed to be involved in the CBL-CIPK signaling network that is associated with maize responses to salt stress [30]. The CBL-CIPK signaling pathway also plays an important role in response to environmental stress in plants [31]. The salt overly sensitive (SOS) pathway is the first identified CBL-CIPK signaling pathway, and the CBL-CIPK complex contains CBL4 (SOS3) and CIPK24 (SOS2) [32]. CBL4 interacts with CIPK24 and recruits it to the plasma membrane, where it activates the H+/Na+ (SOS1) reverse transporter to enhance salt tolerance [33]. By phosphorylating and activating the K+ channel (AKT1), AtCIPK23 could directly interact with CBL1 to promote K+ uptake under low K+ conditions in A. thaliana and O. sativa [34, 35]. Under salt stress, CIPK21 participates in the regulation of response to osmotic stress in A. thaliana by interacting with the vacuolar Ca2+ sensors CBL2 and CBL3 [36]. To date, only a few CIPK have been studied in sugarcane. CIPK14 has been shown to play a role in conferring drought tolerance in sugarcane [37]. Farani et al. [38] found that CIPK8 is not only induced by drought stress but also related to sucrose content.
Sugarcane is the world’s most important sugar crop and an important feedstock for the biofuel industry [39]. Various factors, such as susceptibility to biotic and abiotic stresses, complex genome, narrow genetic base, and poor fertility, restrict sugarcane production [40]. The ancestry of current cultivated sugarcane mainly comprise two taxa: the domesticated sugar-producing species Saccharum officinarum and the wild relative S. spontaneum [41]. Breeding elite cultivars of sugarcane generally requires several years. Hence, using biotechnologies and genetic engineering may accelerate process and improve the quality of sugarcane cultivar. To empirically address the evolution and function of the CIPK gene family, we here analyzed comparative genomics analysis with an emphasis on the functional divergence of the CIPK gene family in Saccharum. In this study, sequence and evolution analysis of the SsCIPK genes were conducted using the available sugarcane genome data [42]. In addition, the expression patterns of the CIPK gene family in the presence of abscisic acid (ABA), polyethylene glycol (PEG), and sodium chloride (NaCl) were detected by qRT-PCR. The allogenic expressions of ScCIPKs were also explored. Under salinity stress, the growth status of E. coli cells expressing ScCIPKs was analyzed. Furthermore, their transient overexpression in Nicotiana benthamiana were also investigated. The present study provides new insights into the evolution of the CIPK gene family as well as highlight its functional divergence in Saccharum.
Results
Identification of the CIPK gene family in S. spontaneum
A total of 93 CIPK gene sequences were identified in the S. spontaneum genome (Supplementary Table S1). Excluding alleles, 48 CIPK genes were detected in the S. spontaneum genome. The distribution of these 48 SsCIPK genes was uneven on the 20 chromosomes (Supplementary Fig. S1). Most of SsCIPK genes were located on the proximal regions or distal ends of chromosomes. Chromosomes 1B, 3C, 4A, 5A, 5C, 6A, 8A, and 8B each contained signal CIPK gene. Chromosome 2B had the highest number of SsCIPK genes (N = 6). However, no SsCIPK gene was mapped to Chromosomes 1C, 3D, 4B, 4D, 5B, 5D, 6B, 6C, 6D, 7C, 8C, and 8D. According to the different gene coordinate orders on sugarcane chromosomes, 48 SsCIPK genes were named from SsCIPK1 to 33 [genes that were duplicated [42] were designated the same name followed by the letters “a”, “b”, “c”, “d” and “e”). These SsCIPK proteins were 356–621 amino acid (aa) residues in length. The molecular weight (MW) of the SsCIPKs ranged from 38.72 kDa (SsCIPK9) to 69.04 kDa (SsCIPK12), however, their isoelectric points (pI) varied from 5.19 (SsCIPK20) to 9.88 (SsCIPK27b). The subcellular locations, palmitoylation sites, and myristoylation sites have also been predicted in this study. Twenty-eight of 48 SsCIPKs were predicted to be located in the chloroplast, indicating that these SsCIPKs may take part in maintaining Ca2+ homeostasis in the chloroplast (Table 1). Twenty-two SsCIPKs, including SsCIPK2a, 2b, 3, 4c, 4e, 6, 8a, 8b, 10, 11, 12, 13, 14, 15, 16, 19, 22a, 22b, 23a, 30, 31a, and 33 have palmitoylation sites (Supplementary Table S2). Seventeen CIPKs, including SsCIPK2a, 4b, 4d, 4e, 8b, 10, 17, 18, 19, 20, 22b, 25a, 25b, 28, 30, 32, and 33 have myristoylation sites (Supplementary Table S2).
Table 1.
Gene name | Genome ID | AA size | MW (kDa) | pI | Predicted locationa |
---|---|---|---|---|---|
SsCIPK1 | Sspon.01G0001600-1A | 458 | 51.43 | 8.00 | chlo |
SsCIPK2a | Sspon.01G0008500-1A | 409 | 46.21 | 7.60 | chlo |
SsCIPK2b | Sspon.01G0008500-1P | 405 | 44.73 | 5.19 | chlo |
SsCIPK3 | Sspon.01G0009190-1A | 482 | 54.95 | 9.21 | chlo |
SsCIPK4a | Sspon.01G0023830-1A | 363 | 39.42 | 9.19 | cyto |
SsCIPK4b | Sspon.01G0023830-1P | 433 | 47.33 | 8.83 | cyto |
SsCIPK4c | Sspon.01G0023830-2P | 411 | 44.72 | 9.43 | E.R. |
SsCIPK4d | Sspon.01G0023830-3P | 433 | 47.12 | 9.09 | cyto |
SsCIPK4e | Sspon.01G0023830-4P | 432 | 58.24 | 8.89 | E.R. |
SsCIPK5 | Sspon.01G0034400-1B | 421 | 47.28 | 7.62 | chlo |
SsCIPK6 | Sspon.01G0009200-3D | 575 | 64.14 | 8.77 | plas |
SsCIPK7a | Sspon.02G0001070-1A | 432 | 46.49 | 7.68 | chlo |
SsCIPK7b | Sspon.02G0001070-1T | 434 | 46.64 | 7.71 | chlo |
SsCIPK8a | Sspon.02G0024240-1A | 562 | 63.13 | 9.45 | chlo |
SsCIPK8b | Sspon.02G0024240-1P | 449 | 50.67 | 9.22 | chlo |
SsCIPK9 | Sspon.02G0030610-1A | 356 | 38.72 | 9.44 | cyto |
SsCIPK10 | Sspon.02G0033090-1B | 438 | 49.85 | 9.16 | chlo |
SsCIPK11 | Sspon.02G0037890-1B | 469 | 51.29 | 8.95 | E.R. |
SsCIPK12 | Sspon.02G0042500-1B | 621 | 69.04 | 9.54 | chlo |
SsCIPK13 | Sspon.02G0044920-1B | 403 | 43.98 | 9.41 | E.R. |
SsCIPK14 | Sspon.02G0000740-2C | 448 | 50.60 | 7.13 | chlo |
SsCIPK15 | Sspon.03G0003630-1A | 581 | 65.21 | 6.94 | chlo |
SsCIPK16 | Sspon.03G0006080-1A | 512 | 56.30 | 9.02 | chlo |
SsCIPK17 | Sspon.03G0015890-1A | 463 | 51.96 | 6.38 | nucl |
SsCIPK18 | Sspon.03G0023620-1A | 517 | 57.18 | 8.36 | chlo |
SsCIPK19 | Sspon.03G0028160-1B | 440 | 48.73 | 8.56 | mito |
SsCIPK20 | Sspon.03G0013670-2B | 405 | 45.24 | 5.30 | cyto |
SsCIPK21 | Sspon.03G0023630-3C | 495 | 55.00 | 9.25 | chlo |
SsCIPK22a | Sspon.04G0017790-1A | 574 | 64.49 | 9.02 | chlo |
SsCIPK22b | Sspon.04G0017790-1P | 556 | 62.37 | 9.08 | chlo |
SsCIPK22c | Sspon.04G0017790-2P | 423 | 48.12 | 9.10 | chlo |
SsCIPK23a | Sspon.05G0020210-1A | 615 | 68.91 | 5.34 | plas |
SsCIPK23b | Sspon.05G0020210-1P | 434 | 49.77 | 8.54 | chlo |
SsCIPK23c | Sspon.05G0020210-2P | 400 | 45.84 | 8.11 | chlo |
SsCIPK24 | Sspon.05G0036030-1C | 440 | 50.40 | 7.15 | chlo |
SsCIPK25a | Sspon.06G0005650-1A | 451 | 48.86 | 9.09 | plas |
SsCIPK25b | Sspon.06G0005650-1P | 447 | 48.32 | 8.99 | plas |
SsCIPK26 | Sspon.07G0004410-1A | 567 | 64.05 | 8.67 | chlo |
SsCIPK27a | Sspon.07G0010390-1A | 440 | 48.24 | 8.35 | nucl |
SsCIPK27b | Sspon.07G0010390-1P | 414 | 44.63 | 9.88 | nucl |
SsCIPK28 | Sspon.07G0013900-1A | 437 | 49.32 | 6.55 | chlo |
SsCIPK29a | Sspon.07G0022730-1B | 478 | 53.70 | 8.66 | chlo |
SsCIPK29b | Sspon.07G0022730-1P | 505 | 56.71 | 7.71 | chlo |
SsCIPK30 | Sspon.07G0026860-1B | 459 | 51.64 | 6.48 | chlo |
SsCIPK31a | Sspon.05G0021220-2B | 482 | 54.75 | 9.22 | plas |
SsCIPK31b | Sspon.05G0021220-2P | 445 | 50.49 | 9.36 | chlo |
SsCIPK32 | Sspon.08G0006260-1A | 397 | 45.07 | 9.30 | cyto |
SsCIPK33 | Sspon.08G0020630-1B | 481 | 53.19 | 8.86 | nucl |
Legends: AA Amino acid, MW Molecular weight, pI Isoelectric point. achlo Chloroplast, E.R. Endoplasmic reticulum, mito Mitochondria, plas Plasma membrane, cyto Cytoplasmic, nucl Nuclear
Motif composition and gene structure of CIPK gene family in S. spontaneum
To investigate the structural features of CIPK genes and their encoded proteins in S. spontaneum, the conserved motifs and intron/exon organization were analyzed (Fig. 1 and Supplementary Fig. S2). Figure 1B showed that 20 motifs were identified in SsCIPK proteins. Motif 2 contained the DFG residues and motif 5 had APE residues. Usually, a conserved kinase domain with a putative activation loop in N-terminal of CIPK proteins appeared between the DFG and APE residues. Motif 7 can be annotated as NAF/FISL motif in this study. As shown in Fig. 1, motif 7 was widely distributed in all of the SsCIPK proteins, except for SsCIPK11. SsCIPK2b, 4a, 4b, 4c, 4d, 4e, 7a, 7b, 9, 13, 16, 19, 25b, 26, 27a, 27b, 29a, 29b, and 33 appeared to lost motif 8, which was annotated as a protein-phosphatase interaction (PPI) domain. Some motifs have been found to be unique to several SsCIPKs. For example, motif 18 was specific to SsCIPK17, 28, and 30, but motif 19 was unique to SsCIPK19 and SsCIPK33. Interestingly, SsCIPK22a and SsCIPK22b contained two motif 16.
The exon-intron organization of all of these identified SsCIPK genes were examined to gain more insights into the evolution of the CIPK family in sugarcane. As indicated in Fig. 1C, the number of introns in SsCIPK genes varied from 0 to 15, and among the 48 SsCIPK genes, 31 SsCIPK genes were intron-poor with < 4 introns (19 out of 31 without introns), whereas the other 17 SsCIPK genes were intron-rich with > 10 introns.
Phylogenetic analysis of CIPK proteins from S. spontaneum, one green algae and six other angiospermaes
A phylogenetic tree consisting of 209 CIPK proteins from S. spontaneum, one green algae and six other angiospermaes was constructed using the Neighbor-Joining method (NJ) method to investigate the evolution of CIPK orthologs in different plant species. The eight representative species included one green algae (Chlorella variabilis) [43], three dicots (A. thaliana [11], Vitis vinifera [44] and Populus [45]) and four monocots (O. sativa [11], Z. mays [27], Sorghum bicolor [44] and S. spontaneum) (Supplementary Table S3).
As shown in Fig. 2, these angiosperms CIPKs were divided into two major groups (I and II), which could be further classified into 13 subgroups (A - M). The subgroups included 14 dicot subfamilies and 16 monocot subfamilies. Base on the results of Fig. 1, the SsCIPKs in group I were intron-rich and the SsCIPKs in group II were intron-poor. Each of the subgroups contained CIPKs from both dicots and monocots, suggesting that they had the last common ancestor (LCA) before the monocot-dicot split. In subgroup E, J, and M, CIPKs were distributed into three subfamilies, which could be further assorted into two kinds of subgroups with one consisting of monocot specific genes, and the other containing both dicot and monocot genes, suggesting that gene expansion occurred in monocot species before the divergence of dicots and monocots. The dicot subfamilies generally contained CIPKs from the three examined dicot species, except for D2 and D13. In monocot subfamilies, only M1, M6, M10 and M12 did not contain CIPKs from the four examined monocot species. These four monocot species were all Gramineae. Hence, we speculated that the progenitors of these CIPK genes in 12 subfamilies (M2–5, M7–9, M11, and M13–16) may have already existed prior to the divergence of Gramineae.
Divergence and duplication of the CIPK genes in S. spontaneum
After analyzing the duplication events of SsCIPK genes, 16 pairs of SsCIPKs were found (Fig. 3). On the basis of defined criteria, five pairs of SsCIPK genes (SsCIPK4d/SsCIPK4c, SsCIPK4d/SsCIPK13, SsCIPK8a/SsCIPK8b, SsCIPK22a/SsCIPK22b and SsCIPK29a/SsCIPK29b) which linked to each other by red lines were confirmed to be tandem duplicated genes. In addition, the other 11 pairs of SsCIPK genes were linked to each other by green lines.
Nonsynonymous to synonymous substitution ratio (Ka/Ks) was analyzed to investigate the duplication of SsCIPK genes in S. spontaneum, and 16 pairs of paralogous SsCIPK genes were calculated (Table 2). The divergence times among the 16 pairs of paralogous SsCIPK genes were based on the pairwise synonymous substitution rates (Ks). The results showed that, except for SsCIPK8a/SsCIPK12, the Ka/Ks ratios of other 15 gene pairs were < 1, suggesting that purifying selection was the main force for driving the gene duplication. Base on divergence time, the gene duplications of SsCIPK3/SsCIPK6, SsCIPK8a/SsCIPK8b, SsCIPK8a/SsCIPK12, SsCIPK22a/SsCIPK22c, and SsCIPK26/SsCIPK29a were ancient and divergent. However, the other 11 pairs of SsCIPKs underwent recent gene duplications in Saccharum.
Table 2.
Gene Name | Gene Name | Ka | Ks | Ka/Ks | Divergence time (Mya) | p-Value (Fisher) |
---|---|---|---|---|---|---|
SsCIPK3 | SsCIPK6 | 0.944043 | 1.26298 | 0.747473 | 103.522951 | 7.42E-12 |
SsCIPK4b | SsCIPK4d | 0.00800882 | 0.0448769 | 0.178462 | 3.67843443 | 0.000203751 |
SsCIPK4d | SsCIPK4c | 0.0240418 | 0.232162 | 0.103556 | 19.0296721 | 1.38E-20 |
SsCIPK4d | SsCIPK4e | 0.032968 | 0.217475 | 0.151594 | 17.8258197 | 4.34E-17 |
SsCIPK4d | SsCIPK13 | 0.00382849 | 0.251149 | 0.0741566 | 20.5859836 | 3.99E-23 |
SsCIPK7a | SsCIPK7b | 0.00358022 | 0.0622356 | 0.0575269 | 5.10127869 | 9.31E-08 |
SsCIPK8a | SsCIPK8b | 0.98452 | 1.05053 | 0.937162 | 86.1090164 | 0.0760462 |
SsCIPK8a | SsCIPK12 | 0.0760462 | 0.953689 | 1.06631 | 78.1712295 | 0.059028 |
SsCIPK22a | SsCIPK22b | 0.0191009 | 0.0471568 | 0.405051 | 3.86531148 | 0.00382849 |
SsCIPK22c | SsCIPK22b | 0.989297 | 1.03753 | 0.953515 | 85.0434426 | 0.226151 |
SsCIPK23b | SsCIPK23c | 0.0141958 | 0.0266145 | 0.533387 | 2.18151639 | 0.0965334 |
SsCIPK24 | SsCIPK23b | 0.0486279 | 0.337887 | 0.143918 | 27.6956557 | 8.30E-32 |
SsCIPK24 | SsCIPK23C | 0.0368104 | 0.349504 | 0.105322 | 28.6478689 | 1.01E-33 |
SsCIPK26 | SsCIPK29a | 0.984641 | 1.06169 | 0.927425 | 87.0237705 | 0.0916113 |
SsCIPK26 | SsCIPK29b | 0.00598476 | 0.0256282 | 0.233522 | 2.10067213 | 0.00148432 |
SsCIPK29a | SsCIPK29b | 2.82E-07 | 5.29E-07 | 0.532591 | 4.3396E-05 | 0 |
Cloning and identification of CIPK genes in Saccharum spp. hybrid (ROC22)
Through RT-PCR, 10 CIPK genes were successfully isolated from Saccharum spp. hybrid (ROC22). Phylogenetic tree analysis (Supplementary Fig. S3) and amino acid sequence comparison of CIPKs (Supplementary Table S4) between ROC22 and S. spontaneum identified the 10 CIPK genes in ROC22, which were designated as ScCIPK1, − 2, − 3, − 4, − 15, − 17, − 20, − 21, − 28, and − 31. Table 3 showed that the 10 ScCIPK genes encoded polypeptides of 369 (ScCIPK17) to 513 (ScCIPK15) amino acids. The MW of the ScCIPK proteins varied from 41.58 (ScCIPK17) to 57.90 (ScCIPK15) kDa. The pI of seven ScCIPKs (ScCIPK1, − 2, − 3, − 4, − 15, − 21, and − 31) were acidic proteins while ScCIPK17, ScCIPK20 and ScCIPK28 were basic protein. The predictions of palmitoylation and myristoylation sites showed that only ScCIPK2 had palmitoylation sites and in the N-terminal domain, both ScCIPK17 and ScCIPK28 had a myristoylation site. Besides, ScCIPK15 had two myristoylation sites, while ScCIPK20 had four myristoylation sites.
Table 3.
Gene name | GenBank Acc No. | AA size | MW (kDa) | pI | Predicted locationa | Palmitoylation sites AA (location) |
Myristoylation sites AA (location) |
---|---|---|---|---|---|---|---|
ScCIPK1 | KX013381 | 445 | 50.11 | 7.62 | chlo | – | – |
ScCIPK2 | KX013387 | 449 | 50.91 | 7.99 | chlo | C (71, 241) | – |
ScCIPK3 | KX013382 | 438 | 50.04 | 9.27 | chlo | – | – |
ScCIPK4 | KX013378 | 431 | 46.61 | 8.18 | E.R. | – | – |
ScCIPK15 | KX013384 | 513 | 57.90 | 7.58 | chlo | – | G (3, 10), |
ScCIPK17 | KX013386 | 369 | 41.58 | 5.31 | chlo | – | G (8) |
ScCIPK20 | KX013380 | 451 | 50.92 | 6.13 | cyto | – | G (3, 4, 5, 6) |
ScCIPK21 | KX013379 | 455 | 51.11 | 9.27 | chlo | – | – |
ScCIPK28 | KX013385 | 460 | 51.81 | 6.33 | chlo | – | G (5) |
ScCIPK31 | KX013383 | 445 | 50.48 | 9.25 | chlo | – | – |
Legends: AA Amino acids, MW Molecular weight, pI Isoelectric point, achlo Chloroplast, E.R. Endoplasmic reticulum, mito Mitochondria, plas Plasma membrane, cyto Cytoplastmic, nucl Nuclear, G represents the glycine residue, and C represents the cysteine residue
Sequence analysis of ten cloned ScCIPK proteins
DNAMAN 9 program was used to compare the amino acid sequences of 10 cloned ScCIPKs (Fig. 4). The activation loop between DFG and APE motifs and the Thr residue, may be phosphorylated by an upstream protein kinase [24]. The amino acid residues at the 5th, 6th, 7th, 10th, 18th, and 22nd sites of the NAF/FISL motif were completely conserved in the C-terminal regulatory domain. The NAF domain is a conserved CBL interaction module, which has been shown to mediate the interaction with all of the known AtCBL proteins [26]. The PPI motif is necessary and sufficient for the interaction with abscisic acid-insensitive 2 (ABI2) [46]. The fifth amino acid residue of the PPI motif in ScCIPK1 and ScCIPK3 was S (serine) and K (lysine), respectively. Whether the amino acid changes will affect the function of this module still needs to be further verified.
Expression of ScCIPK genes in response to ABA, PEG, and NaCl stress
The expression of ScCIPK genes under ABA, PEG and NaCl stress was detected by qRT-PCR (Fig. 5). Under ABA stress, only the expression of ScCIPK21 was upregulated at 3 h and 6 h. The mRNA expression of ScCIPK1, − 2, − 3, − 4, − 15, − 28, and − 31 was inhibited while that of ScCIPK17 and ScCIPK20 did not change. PEG treatment, resulted in the upregulation of ScCIPK1, − 2, − 15, − 20, − 21, and − 28 at 24 h, whereas the other four (ScCIPK3, − 4, − 17, and − 31) were downregulated. In response to NaCl stress, ScCIPK1, − 2, and − 28 was upregulated, whereas ScCIPK3, − 4, − 15, − 20, − 21, and − 31 were downregulated, and only ScCIPK17 showed no significant difference between treatment and control.
Overexpression of ScCIPKs in E. coli cells under salinity stress
The growth performance of E. coli cells transformed pEZYHb (empty vector) or pEZYHb-ScCIPKs (recombinant plasmid) under non-stress (i.e. control) and stress conditions (i.e. high salinity) was tested (Fig. 6). In the spot assay, pEZYHb and pEZYHb-ScCIPK-transformed bacterial cells showed a normal growth on solid LB medium (control) with no significant difference. Under salinity stress, either pEZYHb or pEZYHb-ScCIPK-transformed bacterial cells all could not grow in the LB plates supplemented with 500 or 750 mM NaCl. These results showed that excessive salt concentration can halt the development of E. coli cells. For low-salinity stress, 250 mM NaCl was used, and pEZYHb-ScCIPK3-, − 15- and − 17-transformed bacterial cultures showed an increase in number with better survival compared to the untransformed cells. These findings suggest that the E. coli cells harboring pEZYHb-ScCIPK3, − 15 and − 17 enhance the tolerance of bacterial cells under low-salinity stress (250 mM NaCl).
Transient overexpression of ScCIPKs in N. benthamiana leaves
After transient overexpression of ScCIPKs in N. benthamiana leaves, the expression levels of eight tobacco immunity associated marker genes were detected by qRT-PCR at 2 days post inoculation with ScCIPKs (Fig. 7), 1 day (Fig. 8A (b)), and 7 days (Fig. 8B (b)) post inoculation with Ralstonia solanacearum (Supplementary Fig. S4, Fig. S5, Fig. S6, and Fig. S7).
The transcript expression levels of ethylene synthesis dependent genes (NtEFE26 and NtAccdeaminase) were upregulated in ScCIPK15, − 17 and − 21 except for ScCIPK3 at 2 days post inoculation with 35S::ScCIPKs. The expression of hypersensitive response (HR) marker genes (NtHSR203 and NtHSR515) and SA-related gene NtNPR2 was inhibited, whereas that of NtHSR201, NtPR-1a/c, and NtNPR3 did not change in the control and 35S::ScCIPK3 leaves. In the 35S::ScCIPK15 leaves, the expression level of NtNPR3 was upregulated, whereas that of the three HR maker genes did not change, and only NtPR-1a/c and NtNPR2 were downregulated compared to the control. The transcript abundance of five genes (NtHSR201, NtHSR203, NtHSR515, NtPR-1a/c, and NtNPR2) decreased, and only NtNPR3 did not change in the 35S::ScCIPK17 leaves. In the 35S::ScCIPK21 leaves, the expression of two HR marker genes (NtHSR201 and NtHSR515) showed no significant difference compared to the control, whereas the other four genes (NtHSR203, NtPR-1a/c, NtNPR2, and NtNPR3) were downregulated.
One day after inoculation with R. solanacearum (Fig. 8A (b)), the ethylene synthesis dependent genes were also upregulated compared to the control in the four 35S::ScCIPKs leaves. Except for the ethylene synthesis dependent genes, the expression of the NtPR-1a/c gene was only induced in the transient ScCIPK3-overexpressing leavess. NtHSR515 was induced in the 35S::ScCIPK15 leaves. The HR marker gene, NtHSR203, was upregulated in both the 35S::ScCIPK15 and 35S::ScCIPK21 leaves.
After 7 days post infiltration with R. solanacearum (Fig. 8B (b)), seven genes (NtHSR201, NtHSR203, NtHSR515, NtPR-1a/c, NtNPR2, NtNPR3, and NtEFE26) were inhibited in 35S::ScCIPK17 leaves. Two SA-related genes (NtPR-1a/c and NtNPR3) and two ethylene synthesis dependent genes (NtEFE26 and NtAccdeaminase) were upregulated in the 35S::ScCIPK21 leaves. All of the eight marker genes were upregulated in the 35S::ScCIPK1 leaves. However, in the 35S::ScCIPK15 leaves, three HR marker genes (NtHSR201, NtHSR203, and NtHSR515) and SA-related genes (NtPR-1a/c and NtNPR2) were downregulated.
Discussion
The CIPK protein is a plant specific Ser/Thr protein kinase which can interact with calcium sensor CBL to form a complex signaling network mediating calcium signaling and various environmental stimuli [47, 48]. The CIPK gene family has been extensively studied in A. thaliana [11], as well as in other major crops, such as rice [49] and sorghum [50]. However, CIPK family genes in sugarcane have not been studies to date. Its significant function and lack of research into consideration, genome-wide and function analysis of CIPK family genes from sugarcane is imperative, and it may be used in the identification of resistance-related genes in sugarcane resistance breeding. This study, utilized the genome of S. spontaneum, and bioinformatics methods to determine the evolution of the CIPK gene family in Saccharum. Comprehensive molecular biology techniques were employed to verify the functional divergence of CIPK genes.
Evolution of the CIPK gene family
In parallel to the results of phylogenetic analysis (Fig. 2), the gene structure of the SsCIPKs incurred substantial variations during evolution, with the number of introns varying from 0 to 15. SsCIPK20 and SsCIPK32 may have emerged after the first gene duplication event, with 12 introns for each. However, those genes that were inferred to have emerged after the sixth gene duplication event consisted of introns ranging in number from 0 to 3. Gene structures can evolve by the insertion and/or loss of introns [51]. In the present study, the evolution of gene structures in SsCIPK family genes involved intron losses. The results were consistent with the research on soybean CIPK family genes [43].
The composition of motifs can reflect the similarities and differences among gene family proteins. The proteins in the same clade of phylogenetic tree usually had similar motif compositions (Fig. 1). It is well know that in N-terminal of common CIPK proteins there was a conserved kinase domain with a putative activation loop between the DFG and APE residues [47, 52]. In the C-terminal, CIPK proteins usually had a unique regulatory domain with a conserved NAF/FISL motif [24, 26]. Some CIPKs even contained a protein phosphatase 2C binding domain designated as PPI [46, 53, 54]. In this study, five SsCIPKs did not have the motif 2 (DFG residues) and three SsCIPKs lost the motif 5 (APE residues), suggesting that the activation loop may lose in the SsCIPK proteins. Only SsCIPK11 did not have the motif 7 (NAF/FISL motif), which indicated that SsCIPK11 lost the NAF/FISL motif. Since the NAF/FISL motif was the key to regulating CBL-CIPK interaction [26], SsCIPK11 may not interact with CBLs. Here, nineteen SsCIPKs were found lacking motif 8 (PPI). The result implied that these SsCIPKs may not have the ability to interact with ABI2.
WGDs or polyploidy were considered as an important driving force in the evolution of organisms, especially for ancestral polyploidy in seed plants and angiosperms [55, 56]. In this study, 48 CIPK genes were identified in S. spontaneum genome. Figure 2 showed the phylogeny of the SsCIPK gene family, which may have undergone six gene duplication events from the LCA of SsCIPK. The two SsCIPK genes (SsCIPK20 and − 32) that were clustered in group I (subfamilies A and B) may have emerged after the first gene duplication, while 12 SsCIPK genes (SsCIPK1, −2a, −2b, − 5, −8a, −8b, − 12, − 14, −23a, −23b, −23c, and − 24) in group I (subfamilies C, D, and E) have appeared after the second duplication event. Besides, SsCIPK17, − 28, and − 30 may have emerged after the third gene duplication event, and only SsCIPK11 from the fourth, 18 genes (SsCIPK4a, −4b, −4c, −4d, −4e, −7a, −7b, − 9, − 13, − 16, − 18, − 19, − 26, −27a, −27b, −29a, −29b, and − 33) from the fifth, while 12 SsCIPKs (SsCIPK3, − 6, − 10, − 15, − 21, −22a, −22b, −22c, −25a, −25b, −31a and − 31b) from the sixth.
Except for WGDs, single-gene duplicates also play an important role in the formation of gene families [51]. Previous studies have shown that single-gene duplicates have higher levels of expression divergence, functional innovation, network rewiring and epigenetic changes than duplicated genes retained from WGDs [57–62]. On the basis of defined criteria, 16 pairs of duplicated genes were identified in this study. Five tandem duplication events occurred in chromosomes 2A, 2B, 4C and 7B. Meanwhile, a total 12 pairs of SsCIPK paralog genes were produced by segmental duplication events between chromosomes. These observations suggest that single-gene duplication events play important roles in the expansion of SsCIPK gene family in sugarcane. By estimating the divergence time of these 16 pairs of duplicated genes with an average duplication time of approximately 35.66 Mya, we hypothesize that these duplication events occurred after the divergence of the monocots and eudicots (165 Mya) [63]. Xi et al. [64] found that the tandem and segmental duplication events of grapevine CIPK genes might have happened around 17 Mya and 11 Mya, respectively. In addition, the divergence time of the BrCIPK paralogs was between 1.4457 and 28.1533 Mya, with an average duplication time of approximately 12.4194 Mya [65]. Our results implied that the gene duplication events of CIPKs in the monocots and dicots occurred after the divergence of monocots and eudicots. The Ka/Ks ratio of 15 out of 16 pairs was < 1, indicating that the duplicated genes were possibly under strong purifying selection pressure [66] and functional constraint in S. spontaneum. Strong purifying selection pressure also was reported in the CIPKs in turnip [65].
Functional divergence of ScCIPKs
The CIPK genes play important roles in the responses to phytohormones and abiotic stress [22, 27, 32, 67]. To investigate the expression patterns of ScCIPKs under phytohormones stimulus and abiotic stress in sugarcane, qRT-PCR was used to analyze the expression of 10 ScCIPK genes under ABA, PEG and NaCl stress.
ABA is an important signaling molecule in biotic and abiotic stress responses [68]. In the present study, only ScCIPK21 was upregulated at 3 h and 6 h under ABA stress, whereas the transcript levels of ScCIPK1, − 2, − 3, − 4, − 15, − 28, and -31 were downregulated. ScCIPK2 and ScCIPK20 did not show significant changes in expression at either time point tested. Previous studies have shown that OsCIPK5 [49] and TaCIPK31 [32] exhibited ABA-induced upregulation. In canola seedlings, BnaCIPK6 was upregulated, BnaCIPK3 was downregulated and the other 10 BnaCIPKs showed no significant changes under ABA [22].
Adequate evidence has demonstrated that CIPK genes play an important role in response to drought stress [12]. Several genes had been reported to be induced by drought stress, such as 4 AtCIPKs (AtCIPK6, − 9, − 11, and − 23) [22] and 12 OsCIPKs (OsCIPK1, − 2, − 5, − 6, − 14, − 17, − 19, − 23, − 24, − 25, − 31, and − 32) [13]. AtCIPK6 [69], OsCIPK12 [49], and OsCIPK23 [70] enhanced drought tolerance. Under PEG stress, the expression of 6 out of 10 ScCIPKs (ScCIPK1, − 2, − 15, − 20, − 21 and − 28) peaked at 24 h, whereas the other four (ScCIPK3, − 4, − 17, and − 31) were downregulated. NaCl treatment upregulated ScCIPK1, − 2, and − 28 expression, and downregulated ScCIPK3, − 4, − 15, − 20, − 21, and − 31 transcript expression. In eggplant (Solanum melongena L.), under NaCl stress, 11 SmCIPKs (SmCIPK2, − 3, − 6, − 11, − 12, − 14, − 17, − 22, − 23, − 24, and − 25) were upregulated, whereas transcript expression of SmCIPK4, − 7, and − 20 was downregulated [71]. Sun et al. [32] found that under salt stress, TaCIPK24 was upregulated, and overexpression of TaCIPK24 improved salt tolerance in Arabidopsis. From what has been discussed above, the ScCIPK genes may have different roles in response to drought and salt stress.
Prokaryotic expression was performed to study the expression of four ScCIPKs. Previous studies have shown that overexpression of plant-stress-tolerant functional genes in E. coli cells enhances their growth under abiotic stresses [72–75]. In this study, the recombinant and control cells showed the similar growth on LB medium in overnight grown cultures. On 250 mM NaCl supplemented medium, except ScCIPK21, the recombinant cells showed increased number of colonies compared to control cells. However, no cell growth was observed on the 500 mM and 750 mM NaCl-supplemented medium. These results suggest that the recombinant proteins of ScCIPK3, − 15, and − 17 only slightly enhance growth in NaCl stress condition, whereas ScCIPK21 does not.
Transient overexpression is widely used to study the function of genes under biotic stresses [76, 77]. Figures 7 and 8 showed that defense-related genes are differentially expressed in N. benthamiana leaves that transiently express ScCIPKs. As for ScCIPK3, the defense-related genes were repressed or showed no significant changes after overexpression for 2 days (Fig. 7B), whereas NtPR-1a/c, NtEF26, and NtAccdeminase were upregulated at 1 day post inoculation with R. solanacearum (Fig. 8 A (b)). After 7 days post inoculation with R. solanacearum, seven out of eight immunity-associated marker genes were upregulated (Fig. 8 B (b)). The results suggest that ScCIPK3 plays a role in the induction of immune-related genes during later stages. After 7 days post inoculation with R. solanacearum, the defense-related genes were downregulated or showed no significant changes in ScCIPK15 and ScCIPK17 expression (Fig. 8 B (b)), whereas two or three genes were upregulated at 2 days post inoculation with ScCIPK17 or ScCIPK15 (Fig. 7B) and at 1 day post inoculation with R. solanacearum (Fig. 8 A (b)), respectively. The ethylene synthesis-dependent genes (NtEFE26 and NtAccdeaminase) were almost induced in the all of transiently overexpressed materials. Ethylene not only play as an internal signal regulator during plant growth and development, but also can respond to external adverse conditions (biotic and abiotic stresses) [78].
CIPKs are an important part of the Ca2+-mediated CBL-CIPK network and can specifically target CBLs to transduce the perceived calcium signal in response to diverse stimuli [21, 22]. Previous studies on the relationship between ethylene and CBL-CIPK networks have found that ethylene-responsive gene can be activated by the CBL-CIPK networks when the concentration of Ca2+ ions is increased [79]. Based on our results, we hypothesize that different ScCIPK genes work at various times of infection and may play a role in the response to external stressors through the ethylene synthesis pathway [79].
Conclusions
In this study, 48 SsCIPK genes were identified from the S. spontaneum genome. These genes were uneven on the chromosomes. Base on the number of introns, these genes can be divided into intron-poor and intron-rich groups. The SsCIPK gene family not only underwent six gene duplication events, but also single-gene duplications. The Ka/Ks ratio showed that the duplicated genes of SsCIPKs were possibly under strong purifying selection pressure. Ten ScCIPK genes were cloned in sugarcane cultivar ROC22 (Saccharum spp. hybrid). Under ABA, PEG, and NaCl stress, 10 CIPK genes were differentially expressed in ROC22. A spot assay demonstrated that only ScCIPK3, − 15, and − 17 could slightly enhance growth in NaCl stress condition, whereas ScCIPK21 does not. The results of transient overexpression of ScCIPKs in N. benthamiana leaves suggested that the ScCIPK genes may respond against the attack of R. solanacearum through the ethylene synthesis pathway and function at different times of infection. These results provided information on the evolution and functional divergence of the CIPK gene family that may be utilized in breeding sugarcane cultivars with improved stress tolerance.
Methods
Plant materials and treatment
The sugarcane cultivar ROC22 (Saccharum spp. hybrid) was collected from the Key Laboratory of Sugarcane Biology and Genetic Breeding, Ministry of Agriculture (Fuzhou, China).
According to the method of Su et al. [80, 81]., uniform four-month-old tissue cultured plantlets of ROC22 were grown in water for 1 week and then treated with three exogenous treatments by root dipping at 28 °C with 16 h light and 8 h darkness, including 100 μM ABA, 25% PEG 8000, 250 mM NaCl. The whole plantlets treated by ABA were collected at 0 h, 3 h, 6 h and 12 h. The plantlets under 25% PEG and 250 mM NaCl treatments were collected at 0 h, 6 h, 12 h, and 24 h. Each treatment contained three biological replicates. The harvested samples were immediately frozen in liquid nitrogen and stored at − 80 °C until total RNA extraction.
Identification of CIPK gene family members in S. spontaneum genome
The genome of S. spontaneum [42] was downloaded from the National Center for Biotechnology Information (NCBI, https://www.ncbi.nlm.nih.gov/) database. Hidden Markov Model (HMM) analysis was used for searching the CIPK genes. A total of 30 OsCIPKs [49] and 34 ZmCIPKs [27] protein sequences were aligned and used to construct a specific CIPK HMM using hmmbuild from the HMMER v3.2.1 suite. This new CIPK HMM was used, and all proteins with an E-value lower than 0.01 were selected. Then the HMM profile of NAF (PF03822), which was downloaded from Pfam protein database (http://pfam.sanger.ac.uk/) was used to further search the gene sets obtained from a previous screen. After removing all of the redundant sequences, the resulting putative CIPK protein sequences were submitted to CDD (https://www.ncbi.nlm.nih.gov/Structure/bwrpsb/bwrpsb.cgi), and Pfam protein database was applied to confirm the domain. Finally, the preserved sequences of SsCIPKs were named based on their locations on the chromosomes.
Bioinformatics analysis
The pI and MW of each CIPK protein were predicted using ExPASy (http://web.expasy.org/protparam/). WOLF PSORT (https://www.genscript.com/wolf-psort.html) was used to predict the subcellular location of these CIPK proteins. The palmitoylation sites and myristoylation sites were predicted by CSS-Palm (http://csspalm.biocuckoo.org/). MapGene2Chrom (MG2C) software (http://mg2c.iask.in/mg2c_v2.1/) was applied to map the chromosomal positions of the SsCIPK genes. The exon-intron structures of SsCIPK genes were gathered from the GFF3 file of the S. spontaneum genome. Motifs prediction was performed using MEME (Multiple Em for Motif Elicitation) program (http://meme-suite.org/tools/meme). The optimized parameters were employed as follows: the number of repetitions, any; the maximum number of motifs, 20; and the optimal width of each motif, between 6 and 100 residues. The gene structures and motifs were merged using TBtools [82]. MEGA X (http://www.megasoftware.net/) was employed for phylogenetic analysis. Gene duplication was confirmed according to two criteria: (1) the length of the shorter aligned sequence covered > 70% of the longer sequence; and (2) the similarity of the two aligned sequences were > 70% [83, 84]. In the same chromosome, two genes separated by five or fewer genes within a < 100 kb chromosome fragment were identified as tandem duplicated genes [85]. All of the duplicated genes were mapped to chromosomes based on physical location information from the database of S. spontaneum genome using Circos [86]. KaKs_Calculator v2.0 was applied to calculate the Ka/Ks ratios using the maximum-likelihood MA method [87]. To assess the validity of the Ka and Ks that were calculated by this method, Fisher’s exact test for small samples was used [88]. The divergence time (T) was calculated by T = Ks/(2 × 6.1 × 10− 9) × 10− 6 Mya [66]. Clustal Omega (https://www.ebi.ac.uk/Tools/msa/clustalo/) was used to calculate the percent identity matrix between CIPK proteins in sugarcane.
RNA extraction and first-strand cDNA synthesis
Refer to the manufacturer’s specifications, TRIzol® Reagent (Invitrogen, Carlsbad, CA, USA) was used to extract total RNA from all of the samples collected. A spectrophotometer (NanoVueplus, GE, USA) was used to measure absorbance at wavelengths of 260 nm and 280 nm, and RNA samples with an OD260/OD280 between 1.8 and 2.0 were selected for further analysis. DNase I (Promega, USA) was used to remove DNA contamination. For cloning, first-strand cDNA was synthesized using a RevertAid First Strand cDNA Synthesis Kit (Fermentas, Shanghai, China). For qRT-PCR analysis, the Prime-Script™ RT Reagent Kit (Perfect for Real Time) (TaKaRa, Dalian China) was used to synthesize the first-strand cDNA.
Cloning of ScCIPK gene family and gateway entry vector construction
The CSA221G05 Maturing Sugarcane Stem Lambda ZIPLOX Library (MCS) Saccharum hybrid cultivar Q117 cDNA clone MCSA211C03 5′ similar to serine/threonine kinase, mRNA sequence (GenBank Accession No. CF577339.1) was used as a probe and the NCBI BlastN tool was used to retrieve homologous EST sequences in the sugarcane genome. The BioEdit Contig Assembly Program (CAP) was used to assemble one of the ScCIPK sequences (ScCIPK15). Three ScCIPK sequences (ScCIPK1, ScCIPK17, and ScCIPK20) were selected from our previous transcriptome data of sugarcane infected with sugarcane mosaic virus [89]. The other six ScCIPK sequences (ScCIPK2, ScCIPK3, ScCIPK4, ScCIPK21, ScCIPK28, and ScCIPK31) were screened from our previous transcriptome data of sugarcane infected with smut fungus [90]. Primer 5.0 and the NCBI primer designing tool (http://www.ncbi.nlm.nih.gov/tools/primer-blast/) were employed to design the specific primers for cloning the target genes (Supplementary Table S5). The system of RT-PCR reactions was constructed by the specifications for Ex Taq (TaKaRa, Dalian, China) and LA Taq (TaKaRa, Dalian, China). The amplification reactions are shown in Supplementary Table S6. Then, 1% agarose gel electrophoresis was performed to detect the PCR products. The right PCR products were selected, purified, ligated into the pMD-19-T vector, transformed into E. coli DH5α and sequenced (Sangon, Shanghai, China).
The primers of the Gateway entry vector were used to amplify the ScCIPK ORFs from pMD19-T-ScCIPKs with Gateway entry adapters attB1 and attB2 (Supplementary Table S5). According to the manufacturer’s instructions, Gateway® BP Clonase™ II Enzyme Mix (Invitrogen) was used to ligate the PCR amplification products, which were gel-purified into the Gateway@ donor vector pDONR221 (Invitrogen). Then, the BP reaction mixtures were transformed into E. coli DH5α cells and sequenced (Sangon, Shanghai, China). The verified pDONR221-ScCIPK plasmids were chosen and used in the construction of expression vectors.
Expression pattern of ScCIPKs under ABA, PEG, and NaCl stress
Using the 7500 qRT-PCR system (Applied Biosystems, South San Francisco, CA, USA), the relative expression levels of ScCIPKs under different exogenous stresses were assessed. The qRT-PCR primers of ScCIPKs were designed using Beacon Designer 8.12 software. The Cullin (CUL) [91] and Clathrin adaptor complex (CAC) [91] genes were used to normalize relative transcript levels. The qRT-PCR reaction system was prepared using the SYBR Green Master Mix (TaKaRa), following the manufacturer’s instructions. Each qRT-PCR was repeated thrice, and the reaction conditions were listed as follows: 50 °C for 2 min, 95 °C for 10 min, followed by 40 cycles of 95 °C for 15 s and 60 °C for 1 min. The qRT-PCR data was analyzed using the 2-ΔΔCtmethod [92]. Statistical analysis was conducted using Data Processing System v9.50 software (China). Significance (p < 0.05) was calculated using one-way ANOVA, followed by Duncan’s new multiple range test. All of the primers used in qRT-PCR are listed in Supplementary Table S5.
Salinity stress tolerance assay using transformed E. coli BL21 (DE3) cells
The prokaryotic expressive vectors of pEZYHb-ScCIPKs were constructed using LR. The recombinant plasmids of pEZYHb-ScCIPKs were transformed into E. coli BL21 (DE3) competent cells, and the empty vector pEZYHb was transformed into E. coli BL21 and served as control. For the salt tolerance assay, an additional 250 mM, 500 mM, and 750 mM concentration gradient of NaCl was added to the LB media. When the transformed E. coli BL21 cells were grown to an OD600 of 0.6, 1.0 mmol L− 1 isopropyl β-D-thiogalactoside (IPTG) was added to induce protein production and further grown for 12 h at 37 °C. Cell density was adjusted to an OD600 = 0.6, and then samples were diluted to 10− 3- and 10− 4-fold using LB medium [93]. Ten microliters of each of the 10− 3-and 10− 4-fold dilutions of the sample were spotted onto the LB agar plates.
The role of the ScCIPK genes in response to Ralstonia solanacearum infection
The experiment involved two groups, one overexpressed the target gene for 2 days, and the other overexpressed target gene for 1 day then inoculated with tobacco bacteria Ralstonia solanacearum for 1 day and 7 days. Overexpression vectors pEarleyGate 203-ScCIPKs were constructed using the Gateway cloning technique, then transformed into Agrobacterium strain GV1301 competent cells. GV1301 cells with empty vector pEarleyGate 203 served as control. After incubation, the cells that contained pEarleyGate 203-ScCIPKs and pEarleyGate 203 were centrifuged and resuspended in induction medium (10 mM MES, 10 mM MgCl2, 200 μM acetosyringone, pH 5.6) at an OD600 of 0.8 [94]. R. solanacearum were cultured overnight in potato dextrose water (PDW) liquid medium at 200 rpm and 28 °C, then resuspended in 10 mM magnesium chloride (MgCl2) solution and injected into the one-day overexpression N. benthamiana leaves. All of the injected leaves were collected for RNA extraction to analyze the expression level of ScCIPKs in N. benthamiana semi-quantitatively using with the specific primers (Supplementary Table S5). The transcript levels of eight tobacco immunity-associated marker genes [HR marker genes NtHSR201, NtHSR203 and NtHSR515, SA-related gene NtPR-1a/c, NtPR2, and NtPR3, ET synthesis-dependent genes NtEFE26 and NtAccdeaminase, Supplementary Table S5] were detected by qRT-PCR. The 2-ΔΔCtmethod [92] and DPS v9.50 software (China) were used to analyzed the qRT-PCR data. One-way ANOVA, followed by Duncan’s new multiple range test was used to calculate data significance (p < 0.05). All of the primers used in qRT-PCR are listed in Supplementary Table S5.
Supplementary Information
Acknowledgments
We are grateful to the reviewers for their helpful comments on the original manuscript. We would like to thank editors for their efficient works.
Abbreviations
- CIPK
CBL-interacting protein kinases
- CBL
Calcineurin B-like
- LCA
Last common ancestor
- WGD
Whole-genome duplication
- ABA
Abscisic acid
- PEG
Polyethylene glycol
- HMM
Hidden markov model
- NaCl
Sodium chloride
- aa
Amino acid
- MW
Molecular weight
- pI
Isoelectric points
- ML
Maximum likelihood
- Ka
Nonsynonymous
- Ks
Synonymous
- PPI
Protein-phosphatase interaction
- ABI2
Abscisic acid-insensitive 2
- CUL
Cullin
- CAC
Clathrin adaptor complex
- MG2C
MapGene2Chrom
- IPTG
Isopropyl β-D-thiogalactoside
- PDW
Potato dextrose water
- MgCl2
Magnesium chloride
- HR
Hypersensitive response
- CAP
Contig assembly program
- RT-PCR
Reverse transcription-polymerase chain reaction
- qRT-PCR
Quantitative reverse transcription polymerase chain reaction
- SE
Standard error
Authors’ contributions
Conceived and designed the experiments: WHS and YXQ. Performed the experiments: WHS, YJR, DJW, XQF, and HCT. Analyzed the data: WHS, LH, HL, and NH. Wrote the paper: WHS. Revised the final version of the paper: LPX, YCS, and YXQ. All authors read and approved the final manuscript.
Funding
This work was funded by National Key R&D Program of China (2019YFD1000500 and 2018YFD1000503), National Natural Science Foundation of China (31871688, 31671752, 31101196 and 31340060), Natural Science Foundation of Fujian Province, China (2015 J06006), and the Sugar Crop Research System of China (CARS-17). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Availability of data and materials
The sequences of ten CIPK genes from sugarcane analysed during the current study are available in the NCBI repository with the Accession Numbers of KX013381, KX013387, KX013382, KX013378, KX013384, KX013386, KX013380, KX013379, KX013385 and KX013383. The data of Saccharum spontaneum genome can be downloaded from the following link: http://www.life.illinois.edu/ming/downloads/Spontaneum_genome/. All the other data supporting the conclusions of this article are within the paper.
Ethics approval and consent to participate
Not applicable. This is to confirm that no specific permit was needed for the described experiments, and this study did not involve any endangered or protected species.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
Footnotes
Publisher’s Note
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Contributor Information
Weihua Su, Email: suweihua2016@126.com.
Yongjuan Ren, Email: ryj15555099306@163.com.
Dongjiao Wang, Email: dongjiaowanga@163.com.
Long Huang, Email: forever3553@126.com.
Xueqin Fu, Email: 1767242818@qq.com.
Hui Ling, Email: linghuich@163.com.
Yachun Su, Email: syc2009mail@163.com.
Ning Huang, Email: hning1989@126.com.
Hanchen Tang, Email: tanghanchen@163.com.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Data Availability Statement
The sequences of ten CIPK genes from sugarcane analysed during the current study are available in the NCBI repository with the Accession Numbers of KX013381, KX013387, KX013382, KX013378, KX013384, KX013386, KX013380, KX013379, KX013385 and KX013383. The data of Saccharum spontaneum genome can be downloaded from the following link: http://www.life.illinois.edu/ming/downloads/Spontaneum_genome/. All the other data supporting the conclusions of this article are within the paper.