Expression patterns of UGT2 during salt and ABA treatments
The Genevestigator (https://genevestigator.com/gv) was used in our initial screen for rice UDP-glycosyltransferase (UGT) genes responsive to abiotic stresses. The UGT2 gene (Os11g0444000) was found to be up-regulated by salt stress. To verify this response, the transcript levels of UGT2 in rice leaf tissues were analyzed during treatments with high salinity, ABA and polyethylene glycol (PEG) (Fig. 1). Our data showed that the UGT2 transcript was clearly induced by NaCl and ABA, but not by PEG. These data suggested that UGT2 was possibly involved in salt stress response in rice.
UGT2 positively regulates salt tolerance in rice
To further study the physiological role of UGT2 gene, we generated UGT2 knock-out mutants (ko lines) and overexpression lines (OE lines). Among those lines, the ugt2ko1 and ugt2ko2 are base deletion and insertion mutants, respectively, generated by the CRISPR/Cas9 system (Fig. 2A, B). UGT2OE11 and UGT2OE12 are overexpression plants with much higher UGT2 transcript levels than those of wild-type (WT) plants (Fig. 2C).
To determine the sensitivity of mutants and overexpression plants to salt stress, seeds of WT and transgenic plants were germinated and then placed in water containing 0 mM, 50 mM or 100 mM NaCl. There were no differences in shoot and root lengths between WT and transgenic plants under normal conditions (0 mM NaCl). However, under NaCl treatment conditions, the average root and shoot lengths of UGT2OE lines were increased compared to that of WT plants, root and shoot lengths of ugt2ko lines were decreased (Fig. 2D, E).
Besides, the soil-grown UGT2 overexpression lines, ugt2ko mutant lines and WT plants were also subjected to salt stress (Fig. 2F, G). We observed that mutant plants exhibited earlier wilted phenotypes than WT after exposure to salt stress, and UGT2 overexpression lines showed increased tolerance than WT to NaCl treatments. Almost 75% of UGT2 overexpression plants and 60% of WT plants survived, whereas only 35% of the mutant plants survived under this treatment. Therefore, these results evidence that overexpression of UGT2 enhanced the salt stress tolerance in rice.
Additionally, the proline and soluble sugars, which serve as osmotic regulators, were also accumulated more in UGT2 overexpression plants and less in ugt2ko mutant plants after treatment with 200 mM NaCl (Fig. 2H). The results showed that UGT2OE can accumulate more osmoprotectants than wild-type under salt stress.
Ectopic expression of UGT2 in Arabidopsis enhances salt tolerance
Two homozygous Arabidopsis transgenic lines (OE1 and OE2) ectopically expressing UGT2 were used to investigate the salt tolerance. In the non-treatment group, root growth of Arabidopsis transgenic lines in vertical culture was similar with WT. However, a significant difference in root length was found between the transgenic plants and WT plants upon exposure to 150 or 200 mM NaCl after 7 days (Fig. 3A). Under salt stress conditions, the transgenic plants had longer roots compared to WT plants.
Soil-grown plants were also subjected to salt treatment experiments. Before salt treatment, transgenic Arabidopsis plants and WT showed uniform growth. After exposed to 200 mM NaCl for 15 days, the transgenic plants exhibited better growth and higher survival rate. However, the non-transgenic WT plants wilted (Fig. 3B). These results demonstrated that ectopic expression of the rice UGT2 gene enhanced salt tolerance of the transgenic Arabidopsis plants.
The physiological and biochemical changes in UGT2 overexpression and mutant plants after salt stress
It is well known that ROS produced in abiotic stresses can lead to oxidative damage. Thus, the ROS scavenging capacity in plant cells was also an important index to indicate the stress tolerance. Here, we used NBT staining to investigate the accumulation of superoxide radicals (O2−·) in different transgenic plants under NaCl treatments. The results showed that no significant difference in the level of superoxide radicals between overexpression lines, mutant lines and wild-type lines under control conditions. After salt stress, however, UGT2 overexpression lines accumulated less superoxide radicals and ugt2ko mutant lines accumulated much more than WT in rice, which can be estimated from the coloration (Fig. 4A). Besides, we also examined the antioxidant enzyme activities of CAT, APX and SOD in WT and transgenic plant under normal and salt stress conditions, and found that they were higher in overexpression lines than in WT in response to salt stress, but lower in the mutant/ lines than in WT (Fig. 4B). We determined the expression of antioxidant enzyme encoding genes, including OsAPX2, OsCATA, and OsCATB. Expression levels of antioxidant enzyme encoding genes in mutants and overexpression lines supported our observation from NBT staining and enzyme activity determination (Fig. 4C). These results indicated that the UGT2 overexpression lines had a stronger ability to remove active oxygen and accumulated less ROS under stress conditions.
In order to investigate the potential pathways affected by UGT2, we evaluated the expression of several abiotic stress-regulated genes using qRT-PCR. Although no significant difference in the expressions of OsDREB2A, OsLEA3 and OsP5CS was observed between overexpression lines, mutant lines and WT under control condition, the expressions of those abiotic stress related genes were higher in overexpression plants, while lower in the mutant lines than WT under NaCl treatment (Fig. 4D). The results imply that these abiotic stress-responsive genes might contribute to the salt stress tolerance of plants conferred by UGT2.
OsbZIP23 positively regulates UGT2 transcription by physically interacting with the UGT2 promoter
To know the upstream regulation mechanism of UGT2 gene, we scanned its promoter regions with the online tool PLACE (http://www.dna.affrc.go.jp/htdocs/PLACE/), and found that UGT2 promoter bears a few stress-regulated cis-elements, including ABRE (CACGTG) and G-box (ACGT) elements (Noman et al., 2019; Ji et al., 2015), which are supposed to be bound by bZIP transcription factors and are involved in abiotic stress response (Fig. 5A).
We then selected several typical bZIP transcription factors involved in salt stress regulation, including OsbZIP23, OsABI5, OsABF2 and OsbZIP71, to explore their possible binding capability with UGT2 promoter. Yeast one-hybrid (Y1H) assays were performed to test the interaction between bZIP proteins and those cis-elements on UGT2 promoter. As shown in Fig. 5B, we found that OsbZIP23 had the strong capability of binding with the UGT2 promoter in Y1H assays. OsABI5 showed only a weak binding.
Previous studies had shown that ABRE (CACGTG) is the core sequence in the promoter of OsbZIP23-binding target genes (Zong et al., 2016). Here, a qRT-PCR-based chromatin immunoprecipitation (ChIP) assay was deployed to monitor the binding affinity of OsbZIP23 to the UGT2 gene promoter. One-week-old wild type rice seedlings exposed to either 0 or 150 mM NaCl for 12 h were used as plant materials. Fragments of the UGT2 promoter, containing ABRE element (b) or far away ABRE element (a), were amplified by PCR to monitor the fragment enrichment after chromatin immunoprecipitation by using the rabbit polyclonal antibody raised against synthetic peptide OsbZIP23 (Fig. 5C). Our results showed that the ‘b’ fragments were enriched much more than ‘a’ fragments under salt stress, but they were enriched to similar extents under control conditions (Fig. 5D), indicating that OsbZIP23 preferentially associated to the chromatin region containing a ABRE element of UGT2 promoter in vivo under salt stress.
To further confirm the transcription activating of UGT2 by OsbZIP23 or OsABI5, a dual-luciferase (LUC) reporter plasmid was constructed, which encodes a firefly LUC gene driven by the UGT2 promoter (− 2000 to 0 bp) and a Renilla luciferase (REN) gene driven by the constitutive 35S promoter. The constructs 35S:OsbZIP23 and 35S:OsABI5 were used as effectors, 35S:GFP was the empty plasmid control (Fig. 5E). Our experiment results showed that overexpression of OsbZIP23 can stimulate the luciferase activity of the UGT2 reporter as compared to the empty plasmid control. OsABI5 had only weak stimulation activity (Fig. 5F). These results suggested that OsbZIP23 is the major upstream regulator for transcription activity of UGT2.
UGT2 increases the plant sensitivity to exogenous ABA
It is reported that OsbZIP23 plays a critical role in mediating ABA sensitivity in rice and OsbZIP23-overexpressing lines were hypersensitive to ABA (Xiang et al., 2008). Given that UGT2 is directly regulated by the transcription factor OsbZIP23, it is necessary to test the ABA sensitivity of UGT2 transgenic plants. We examined the responses of UGT2 overexpression lines and mutant lines in terms of shoot and root growth upon ABA treatment. It was observed that the shoot and root growth of UGTOE11 and UGTOE12 seedlings were more sensitive to ABA treatment, whereas ugtko1 and ugtko2 were less sensitive to ABA treatment (Fig. 6A, B). These results further supported our conclusion that UGT2 is bound and regulated by bZIP23 transcription factor and is involved in abiotic stress response.