Abstract
Cells prevent heat damage through a highly conserved canonical heat stress response (HSR) in which heat shock factors (HSFs) bind heat shock elements (HSEs) to activate heat shock proteins (HSPs). Plants generate short HSFs that originate from HSF splicing variants, but little is known about S-HSFs. Although an enhanced canonical HSR confers thermotolerance, its hyperactivation inhibits plant growth. How this process is prevented to ensure proper plant growth has not been determined. Here, we report that Arabidopsis S-HsfA2, S-HsfA4c, and S-HsfB1 confer extreme heat (45°C) sensitivity and represent new kinds of HSF with a unique truncated DNA-binding domain (tDBD) that binds a new heat-regulated element (HRE). The HRE conferred a minimal promoter response to heat and exhibited heat stress sensing and transmission patterns. We used S-HsfA2 to investigate whether and how S-HSFs prevent hyperactivation of the canonical HSR. HSP17.6B, a direct target gene of HsfA2, conferred thermotolerance, but its overexpression caused HSR hyperactivation. We revealed that S-HsfA2 alleviated this hyperactivation in two different ways. 1) S-HsfA2 negatively regulates HSP17.6B via the HRE-HRE-like element, thus constructing a noncanonical HSR (S-HsfA2-HRE-HSP17.6B) to antagonistically repress HsfA2-activated HSP17.6B expression. 2) S-HsfA2 binds to the DBD of HsfA2 to prevent HsfA2 from binding to HSEs, eventually attenuating HsfA2-activated HSP17.6B promoter activity. Overall, our findings underscore the biological importance of S-HSFs, namely, preventing plant heat tolerance hyperactivation to maintain proper growth.
Graphical Abstract
Introduction
Elevated temperatures, i.e., heat shock or heat stress, have become a global problem threatening crop yields (Bita and Gerats, 2013). Cells prevent heat damage through the canonical heat stress response (HSR). In this canonical HSR, a heat shock factor (HSF) trimer binds a DNA cis-acting element called a heat shock element (HSE) to induce the production of heat shock proteins (HSPs). This canonical HSR is highly conserved among different organisms but is highly complex in plants (Morimoto, 1993). Accordingly, heat-tolerant plants are usually generated by overexpressing HSFs or HSPs (Fragkostefanakis et al., 2015). Several studies have revealed that enhanced canonical HSR is beneficial for plant heat tolerance but also results in growth inhibition under normal conditions. Zhu et al. (2009) reported that overexpression of Boea hygrometrica Hsf1 in Arabidopsis and tobacco confers plant thermotolerance but also leads to seedling dwarfism under normal conditions. When Arabidopsis HsfA2 and HsfA3 are overexpressed, these Arabidopsis plants tolerate increased heat stress but exhibit seedling dwarfism under nonstress conditions (Ogawa et al., 2007; Yoshida et al., 2008). These findings reflect the active growth inhibition of canonical HSR hyperactivation under nonstress conditions, which is undesirable for plant productivity. However, much less is known about how plants prevent canonical HSR hyperactivation to ensure a balance between heat resistance and growth. Considering that HSRs are highly complex in plants, we reasoned that there should be new kinds of HSFs that inhibit canonical HSR hyperactivation in plants. However, these new kinds of HSFs and their underlying regulatory mechanisms have yet to be determined in plants.
A common way for introns to expand the diversity of host gene products is alternative splicing (AS). An increasing number of studies have shown that heat stress-induced AS events in heat response genes, including HSFs, are very important regulatory mechanisms for the fitness of plants under heat stress (Ling et al., 2021). Thus, we focused on heat-induced AS events in HSFs as a starting point for revealing new kinds of HSFs and their functions and regulatory mechanisms in the plant response to heat stress.
HSFs share similar constructs across eukaryotes, in which the HSE DNA-binding domain (DBD) is the most conserved (Nover et al., 2001). The DBD is a “winged” helix-turn-helix protein that consists of three α-helices (H1, H2, H3) and four-stranded antiparallel β-sheets (β1, β2, β3, β4). H3 directly binds to the HSE, and its adjacent wing domain (β3-loop-β4) is needed for the formation of HSF-HSE trimers (Littlefield and Nelson, 1999; Ahn et al., 2001; Feng et al., 2021). Interestingly, for all HSFs, the position of an intron within the DBD is conserved (Nover et al., 2001), and the intron is inserted between H3 and the wing domain coding region. In plants, mostly under heat stress, this intron is fully or partially retained to generate splice variants, such as Arabidopsis HsfA2-II (Sugio et al., 2009), Arabidopsis HsfA2-III (Liu et al., 2013), rice (Oryza sativa) OsHSFA2dII (Cheng et al., 2015), lily (Lilium spp.) LlHSFA3B-III (Wu et al. 2019), wheat (Triticum aestivum) TaHsfA2-7-AS (Ma et al., 2023), and maize (Zea mays) ZmHsf17-II (Zhang et al., 2024). These variants contain in-frame stop codons within the retained intron that may translate into short HSF isoforms (S-HSFs).
Several S-HSFs have been proven to play regulatory roles in thermotolerance in plants. Previously, we reported that heat stress-induced S-HsfA2 was detected by immunoblotting and can regulate the expression of HsfA2 by binding to HSEs within the HsfA2 promoter (Liu et al., 2013). Wu et al. (2019) also reported that LlHSFA3B-III (S-LIHSFA3B) can be detected by immunoblotting and that overexpressing S-HSFA3B reduces tolerance to acute heat (45°C) in Arabidopsis plants. TaHsfA2-7 generates the splice variant TaHsfA2-7-AS (S-TaHsfA2-7), which confers tolerance to heat (45°C) in Arabidopsis (Ma et al., 2023).
S-LIHSFA3B interacts with lily HSFA3A to limit its transactivation function and temper the function of lily HSFA3A (Wu et al., 2019). S-ZmHsf17 can interact with the DBD of full-length ZmHsf17 to suppress the transactivation of ZmHsf17 (Zhang et al., 2024). These findings suggest that S-HSFs can regulate the activities of HSFs through S-HSF‒HSF protein interactions. However, how S-HSFs, as transcription factors, regulate plant heat responses remains unclear. Unlike classical HSFs, S-HSFs contain a unique C-terminal truncated DBD (tDBD) and an extended motif or domain encoded by the retained intron sequences (Liu et al., 2013). Although S-HSFs lack nuclear localization signals, S-HSFs can also localize to the nucleus (Sugio et al., 2009; Liu et al., 2013; Cheng et al., 2015; Wu et al. 2019; Ma et al., 2023; Zhang et al., 2024). The tDBD lacks a wing domain and thereby might enable S-HSFs to recognize new heat-responsive DNA elements related to the HSE, while extended motifs or domains are variable in length and sequence and subsequently might contribute to regulatory roles, such as transcriptional regulation. Thus, S-HSFs could represent new kinds of plant HSFs. Considering that unique S-HSFs are expressed mostly under extreme heat stress, they could be associated with plant responses to heat stress. Therefore, uncovering the mechanism through which canonical HSR hyperactivation is regulated by S-HSFs will shed light on the balance between growth and thermotolerance.
In this study, we reported that S-HSFs (i.e., S-HsfA2, S-HsfA4c, and S-HsfB1) are new kinds of HSFs that bind new heat-regulated elements (HREs) and negatively regulate Arabidopsis tolerance to extreme heat stress. Using S-HsfA2 as a representative S-HSF, we further investigated the molecular mechanisms by which S-HSFs prevent canonical HSR hyperactivation. The results showed that S-HsfA2 alleviates HSP17.6B overexpression-mediated HSR hyperactivation in two different ways: antagonistically repressing HSP17.6B overexpression through a noncanonical HSR (S-HsfA2-HRE-HSP17.6B) and acting as a negative binding regulator of HSFs to inhibit the binding of HsfA2 to the HSE of the HSP17.6B promoter. Our results reveal new kinds of HSF originating from HSF splicing variants and provide deep mechanistic insights into proper growth control against thermotolerance hyperactivity in plants.
Results
S-HsfA2 confers extreme heat (45°C) sensitivity in Arabidopsis
S-HsfA2 contains a 42-aa N-terminal domain (N-ter), a 61-aa tDBD, and a 26-aa extended leucine (L)-rich domain (LRD) (Figure 1A). According to the predicted AlphaFold 3D structure of S-HsfA2, the LRD forms an α-helix structure. Given that S-HsfA2 is expressed under extreme heat (42°C) but not under moderate heat (37°C) (Liu et al., 2013), we determined its role in tolerance to extreme heat. Overexpression of Flag-tagged S-HsfA2 under the control of the cauliflower mosaic virus 35S RNA promoter (35S) (35S:S-HsfA2-Flag, S-HsfA2-OE) significantly reduced seedling survival at 45°C for 2 h compared to that of the wild-type (WT) control (Figure 1B).
Our previous study showed that LRD is responsible for the transcriptional repression of S-HsfA2 in yeast cells (Liu et al., 2013). We noted that a conserved transcriptional repression motif, LxLxLx (x=any amino acid) (Tiwari and Guilfoyle, 2004), exists in the LRD (Figure 1A). Mutations (L to alanine (A)) in the LxLxLx motif (S-HsfA2L-A) converted S-HsfA2 from a transcriptional repressor to a transcriptional activator in yeast cells (Supplemental Figure S1), indicating that S-HsfA2 is an LxLxLx-type transcriptional repressor. As a result, overexpression of this dominant activator of S-HsfA2-Flag (S-HsfA2L-A-OE) eliminated the extreme heat-sensitive phenotype (Figure 1B). When the plants were grown in soil, the S-HsfA2 genetic plants also exhibited the same extreme heat response phenotype (Figure 1B).
Next, we generated S-HsfA2-encoding mRNA (HsfA2-III)-knockdown transgenic lines (S-HsfA2-KD) through RNA interference (RNAi) (Figure 1C). In S-HsfA2-KD, the abundance of HsfA2-III but not HsfA2-II or HsfA2 mRNA decreased under heat stress. S-HsfA2-KD plants displayed a clear resistance phenotype to extreme heat in both medium and soil (Figure 1C). Overall, these genetic data strongly confirm that S-HsfA2 is sensitive to extreme heat in Arabidopsis and that the LxLxLx motif is needed for its biological functions.
The constitutive expression of S-HsfA2 inhibits Arabidopsis seedling growth
We also noted that overexpression of S-HsfA2 (S-HsfA2-OE) caused short root length (growth in medium) and seedling dwarfism (growth in soil) under normal conditions (Supplemental Figure S2). However, these growth defects were partially rescued in the S-HsfA2L-A-OE seedlings (Supplemental Figure S2), suggesting that the LxLxLx motif of S-HsfA2 is required for these biological functions. This finding reflected the negative impact of the constitutive expression of S-HsfA2 on Arabidopsis seedling growth.
Heat stress promotes the nuclear accumulation of S-HsfA2
A previous study showed that S-HsfA2 is localized in the nucleus of Arabidopsis mesophyll protoplasts (Liu et al., 2013). We further investigated the subcellular localization of S-HsfA2 in Arabidopsis using the 35S:S-HsfA2-GFP transgene. We found that the GFP signals were distributed throughout the root cells under normal conditions but that the signals accumulated mainly in the nucleus after heat stress treatment (Supplemental Figure S3). This result is consistent with the finding that S-HsfA2 is a transcription factor involved in heat stress regulation.
S-HsfA2 binds a cis-acting element termed the heat-regulated element (HRE)
As S-HsfA2 is a transcription factor with a unique tDBD, we identified new cis-acting elements other than HSEs recognized by S-HsfA2 through chromatin immunoprecipitation (ChIP) in heat stress-treated 35S:S-HsfA2-GFP transgenic Arabidopsis (Supplemental Figure S4A). High-throughput sequencing (seq) of DNA precipitated with an anti-GFP antibody revealed a centrosymmetric 7-bp motif (5′-GAAGAAG-3′). This motif was most significantly enriched (E=10−19) in the ChIP-Seq dataset (Supplemental Figure S4B). Because it was demonstrated to be a heat-regulated element, we hereafter named it an HRE.
HSEs are composed of at least three alternating nGAAn/nTTCn blocks (n denotes any nucleotide) (Amin et al., 1988). Accordingly, an HRE is considered a partially overlapping element of two inverted nGAAn blocks sharing a G base (5′-nGAA->G<-AAGn-3′), indicating that the HRE and HSE are partially related. From the ChIP-Seq dataset, a total of 80 putative S-HsfA2 targets were identified (Supplemental Figure S4C), 65 of which contained the HRE (Supplemental Table S1).
We next confirmed the binding of S-HsfA2 or tDBD to the HRE. The bacterially expressed and purified glutathione S-transferase (GST)-tagged S-HsfA2 fusion protein (GST-S-HsfA2) (Supplemental Figure S5) was used in electrophoretic mobility shift assays (EMSAs). The results showed that GST-S-HsfA2, but not the mock control (GST alone), specifically bound to HRE in vitro (Figure 2A). According to the yeast one-hybrid (Y1H) assay, S-HsfA2 also specifically recognized HRE (Figure 2B). Interestingly, His6-tDBD recognized the HRE, but His6-DBD bound to the HSE in vitro (Figure 2C). Consistent with this observation, His-tagged HsfA2 did not bind to HRE in vitro (Supplemental Figure S6). These findings indicate that S-HsfA2 uses the tDBD to bind to HREs in vitro.
HRE serves as a heat response element
To determine the heat induction effect of HRE, we constructed an HRE trimer driving the minimal 35S promoter (-46/+8, 35Sm)-β-glucuronidase (GUS) reporter gene (HRE-35Sm:GUS) in transgenic Arabidopsis (Figure 3A). HRE could drive 35Sm to enable clear GUS histochemical staining in seedlings. However, as observed for the vector control (35Sm:GUS), mutations in the HRE (mHRE-35Sm:GUS) caused a full loss of GUS staining regardless of heat stress. Weak GUS signals were mainly detected in the shoot apical region and the shoot vascular system in the HRE-35Sm:GUS seedlings. In a time-course study, GUS signals were enhanced under heat stress (37°C) for 15-30 min, suggesting that GUS might be transported via the vascular system from the shoot apical region to the shoot to respond to the heat response at the whole-plant level.
A quantitative GUS expression assay at both the mRNA (Figure 3B) and protein (Figure 3C) levels revealed that HRE conferred heat responsiveness to 35Sm by 2- to 4-fold. This heat responsiveness was also heat (37°C)-time dependent (Figure 3D). HRE-bound nuclear extracts were derived from Arabidopsis in vitro, particularly from extreme heat shock (42°C)-treated Arabidopsis nuclear extracts (Figure 3E), further suggesting that HRE has the biochemical characteristics of a heat response element. Overall, the above molecular, biochemical, and genetic data strongly demonstrated that the HRE serves as a heat response element.
S-HsfA2 acts as an HRE-binding transcription repressor in Arabidopsis
To determine whether S-HSfA2 depends on the HRE to regulate a gene, we introduced the 35S:S-HsfA2-Flag or 35S:S-HsfA2L-A-Flag effector into the HRE-35Sm:GUS reporter lines by crossing, and we found that GUS protein levels were downregulated compared with those in uncrossed controls (Figure 3F). In contrast, the 35S:S-HsfA2L-A-Flag effector increased GUS levels (Figure 3F). These results confirmed that S-HsfA2 is an HRE-binding transcription repressor. This finding also indicated that the LxLxLx motif within the LRD is needed for S-HsfA2 repression activity in plant cells, which is consistent with findings in yeast cells (Supplemental Figure S1).
S-HsfA2, S-HsfA4c, and S-HsfB1 represent new kinds of plant HSF
Given that S-HsfA2 is an HRE-binding transcriptional repressor and confers extreme heat sensitivity in Arabidopsis, we hypothesized that S-HsfA2 represents a new HSF. The new HSFs are not limited to S-HsfA2 because tDBD is responsible for HRE binding and is highly conserved among S-HSFs. To provide further supporting data, we characterized S-HsfA4c, S-HsfB1, and S-HsfB2a, which were previously identified (Liu et al., 2013).
HsfA4c (At5G45710) has two splice variants (Liu et al., 2013): an intron 2-containing predominant S-HsfA4c and a less abundant intron 1-containing full-length HsfA4c. S-HsfA4c encodes S-HsfA4c. S-HsfA4c was constitutively expressed, but heat stress enhanced its expression (Figure 4A). S-HsfA4c shares similar structural features (LxLxLx motif-containing LRD, Figure 4A) with S-HsfA2. S-HsfA4c acted as a transcriptional repressor in yeast cells, and LRD was needed for its transcriptional repression (Supplemental Figure S7). S-HsfA4c bound to the HRE according to both Y1H (Figure 4B) and electrophoretic mobility shift assays (EMSAs) (Figure 4C). Overexpression of 35S:S-HsfA4c-GFP (S-HsfA4c-OE) resulted in heat sensitivity compared with that of the 35S:GFP vector control (Figure 4D), whereas T-DNA insert-mediated knockdown of S-HsfA4c together with HsfA4c increased thermotolerance (Figure 4E). Interestingly, heat stress enhanced the translocation of HsfA4c-GFP into the nucleus (Figure 4F), similar to what was observed for S-HsfA2-GFP (Supplemental Figure S3).
Like S-HsfA4c, S-HsfB1 was constitutively expressed, but heat stress strongly increased its expression (Figure 5A). In contrast, S-HsfB2a was heat stress inducible (Figure 5A). S-HsfB1 and S-HsfB2a were localized to the nucleus of plant cells (Figure 5B). S-HsfB2a is a weak transcriptional activator in yeast cells, but S-HsfB1 has no transactivation activity (Supplemental Figure S8). According to the Y1H results, both S-HsfB1 and S-HsfB2a could bind to the HRE (Figure 5C). However, S-HsfB1, but not S-HsfB2a, bound to the HRE in vitro (Figure 5D). Thus, S-HsfB2a did not appear to be an HRE-binding protein. Therefore, we selected S-HsfB1 for further confirmation of its effects on Arabidopsis thermotolerance. We found that seedling survival, especially chlorophyll content, was markedly reduced by S-HsfB1 overexpression (35S:S-HsfAB1-RFP) in Arabidopsis plants under heat stress (Figure 5E). In contrast, the specific knockdown of S-HsfB1 through antisense RNA (targeting the retained intron sequences) and both the HsfB1 and S-HsfB1 double knockout resulted in increased seedling survival, especially in terms of the chlorophyll content, under heat stress (Figure 5F). Collectively, these data indicate that HRE binding and negative regulatory effects on extreme heat stress tolerance are common for S-HsfA2, S-HsfA4c, and S-HsfB1. Therefore, we conclude that these three S-HSFs represent new kinds of plant HSFs.
The HRE-HRE-like element is involved in heat induction of the HSP17.6B promoter
Using S-HsfA2 as a representative S-HSF, we further investigated the transcriptional cascades linking S-HsfA2 to Arabidopsis heat tolerance sensitivity. Among the 80 putative targets of S-HsfA2, we focused on the heat shock-induced small HSP gene HSP17.6B (At2G29500) (Scarpeci et al., 2008). By searching the ChIP-Seq dataset, we identified the 103-bp promoter region of HSP17.6B. This region contains 14-bp DNA sequences (5′-GAAGAAGGAAGAAC-3′, -540 to -527 relative to the transcription start site), which consists of one perfect HRE (5′-GAAGAAG-3′) and one HRE-like (5′-GAAGAAC-3′), named the HRE-HRE-like element (Figure 6A). HSP17.6Bp also contains an HSE (5′-aTTCtaTTCaaTTCa-3′).
To determine the role of the HRE-HRE-like element in the response of HSP17.6Bp to heat stress, we generated transgenic Arabidopsis lines harboring HSP17.6Bp or HSP17.6Bp lacking the HRE-HRE-like element (HSP17.6BpΔHRE), which drives GUS reporter expression. GUS histochemical staining revealed a specific heat-induced expression pattern of HSP17.6Bp, and GUS signals were detected in the shoot apical region and the shoot vascular system after heat stress. Further quantitative GUS protein expression showed that HRE-HRE-like deletion did not change the heat-inducible expression pattern of HSP17.6Bp but did affect the heat-induced expression level (increased at 37°C but largely decreased at 42°C) (Figure 6B). These results suggested that the HRE-HRE-like element is involved in the heat induction of HSP17.6Bp, especially under heat shock at 42°C.
S-HsfA2 negatively regulates HSP17.6B by binding to the HRE-HRE-like element
ChIP‒qPCR assays verified the binding of S-HsfA2 to the HRE-HRE-like-containing HSP17.6Bp region (Figure 6C). Correspondingly, the heat-induced expression of HSP17.6B was upregulated in the S-HsfA2-knockdown lines but downregulated in the S-HsfA2-overexpressing lines (Figure 6D). These results indicated that S-HsfA2 negatively regulates HSP17.6B by directly binding to the HRE-HRE-like element within HSP17.6Bp.
HSP17.6B confers heat tolerance in Arabidopsis
We next tested whether HSP17.6B is involved in thermotolerance. We obtained two T-DNA-inserted HSP17.6B mutants (hsp17.6b-1 and hsp17.6b-2), 35S:HSP17.6B-Flag transgenic Arabidopsis plants in the WT background (HSP17.6B-OE), and 35S:HSP17.6B-Flag transgenic Arabidopsis plants in the hsp17.6b-1 background (HSP17.6B-KI) (Figure 7A). Subsequent heat tolerance phenotype analyses revealed that two hsp17.6b mutants were heat sensitive, whereas the HSP17.6B-OE lines were heat tolerant (Figure 7B). The heat tolerance of the HSP17.6B-KI lines was similar to that of the WT control (Figure 7C), suggesting that expressing 35S:HSP17.6B rescued the heat-sensitive phenotype of the hsp17.6b mutant.
Overall, HSP17.6B confers thermotolerance, but S-HsfA2 represses HSP17.6B via the HRE-HRE-like element, which is involved in heat induction by Hsp17.6Bp. Thus, HSP17.6B links S-HsfA2 to extreme heat sensitivity in Arabidopsis. Based on these findings, we propose that a noncanonical HSR is involved in extreme heat sensitivity, i.e., S-HsfA2-HRE-HSP17.6B.
HSP17.6B overexpression mediates heat tolerance hyperactivation
We noted that HSP17.6B overexpression also retarded seedling growth under normal conditions, as indicated by both decreased biomass (fresh weight) and low chlorophyll content (chlorosis) (Figure 8 A). When grown in soil, the HSP17.6B-OE seedlings exhibited a dwarf but heat-tolerant phenotype (Figure 8 B). These results demonstrated that HSP17.6B overexpression mediated heat tolerance hyperactivation. Therefore, the noncanonical S-HsfA2-HRE-HSP17.6B HSR can contribute to attenuating heat tolerance hyperactivation.
Canonical HSR: HsfA2-HSE-HSP17.6B
HSP17.6Bp also contains an HSE, suggesting that HSP17.6B is regulated by HSFs. It has been reported that the constitutive expression of HSP17.6B is activated by HsfA2 overexpression, but the heat-induced expression of HSP17.6B is markedly reduced in the HsfA2 knockout mutant, suggesting that HSP17.6B is a putative target of HsfA2 (Nishizawa et al., 2006). ChIP‒qPCR using Arabidopsis transiently expressing 35S:HsfA2-RFP with an anti-RFP antibody showed the direct binding of HsfA2-RFP to the HSE-containing HSP17.6Bp region (Supplemental Figure S9A, B). According to the Y1H assay, HsfA2 also bound to the HSE within HSP17.6Bp (Supplemental Figure S9C). Together with the findings of a previous report (Nishizawa et al., 2006), our data confirmed that HSP17.6B is a direct target of HsfA2. Thus, a canonical HSR (HsfA2-HSE-HSP17.6B) is suggested.
Taken together, the above data indicate that S-HsfA2 and HsfA2 have opposite effects on HSP17.6B expression: repression by S-HsfA2 but activation by HsfA2. These findings suggested that the balance between HsfA2 and S-HsfA2 activity serves to fine-tune the HSP17.6B expression level, possibly preventing the hyperactivation of heat tolerance mediated by HSP17.6B overexpression.
S-HsfA2 interacts with several HSFs, including HsfA2
S-HSFs can negatively regulate the activities of HSFs through protein‒protein interactions (Wu et al., 2019; Zhang et al., 2024). We therefore explored whether and how S-HsfA2 regulates the activities of HSFs, especially HsfA2, through protein‒protein interactions. To address this issue, we first used a yeast two-hybrid (Y2H) assay to screen Arabidopsis HSFs that interact with S-HsfA2. The results showed that S-HsfA2 interacted with HsfA1e, HsfA2, HsfA3, HsfA7a, and HsfB2b among the 19 Arabidopsis HSFs tested (Figure 9A). In this study, we focused on HsfA2. GST pulldown confirmed the interaction between S-HsfA2 and HsfA2 in vitro (Figure 9B). Importantly, Y2H and bimolecular fluorescence complementation (BiFC) assays revealed that S-HsfA2 interacted with the DBD of HsfA2 (Figure 9C, 9D), which is consistent with previous findings that S-ZmHsf17 can interact with the DBD of full-length ZmHsf17 in a Y2H assay (Zhang et al., 2024).
S-HsfA2 decreases the HSE-binding capacity of HsfA2 in vitro
The streptavidin-bead pulldown assay is an efficient in vitro method for evaluating the DNA binding capacity of transcription factors (Deng et al., 2003). Because of the specific interaction between His6-HsfA2 and GST-S-HsfA2 in vitro (Figure 9B), we used His6-HsfA2 and GST-S-HsfA2 in this pulldown assay (Figure 10A). The results showed that His6-HsfA2 prebinding with GST-S-HsfA2 decreased the signal intensity of the biotin-labelled HSE bait-binding His6-HsfA2 (Figure 10A). These findings suggest that S-HsfA2 serves as a negative binding regulator of HsfA2 to decrease the HSE-binding capacity of HsfA2 in vitro.
S-HsfA2 attenuates HsfA2-regulated HSP17.6B promoter expression
We then explored the effects of S-HsfA2, a negative binding regulator of HsfA2, on HsfA2-mediated HSP17.6Bp expression. Based on the interaction between HsfA2-nYFP and S-HsfA2-cYFP in the BiFC assay (Figure 9D), we used dual-luciferase (LUC) reporter assays to test whether S-HsfA2-cYFP inhibits the HSP17.6Bp activity activated by HsfA2-nYFP. To avoid the effect of S-HsfA2 on HSP17.6Bp, a short, truncated 135-bp HSP17.6Bp (sHSP17.6Bp) containing HSE but lacking an HRE-HRE-like sequence was used in this assay. Compared with the GUS effector controls, HsfA2-nYFP increased sHSP17.6Bp-LUC reporter expression in tobacco cells. As expected, S-HsfA2-cYFP failed to regulate sHSP17.6Bp. However, compared with the GUS-cYFP control, S-HsfA2-cYFP reduced the HsfA2-nYFP-mediated sHSP17.6Bp-LUC reporter expression level by more than 50% (Figure 10B). These results establish the importance of S-HsfA2 in HsfA2-regulated HSP17.6Bp expression by preventing HsfA2 from binding to the HSE.
Discussion
The AS events of HSFs have been extensively described in plants (Sugio et al., 2009; Liu et al., 2013; Cheng et al., 2015; Wu et al. 2019; Ma et al., 2023; Zhang et al., 2024), but the specific biological functions of these splice variants and their underlying regulatory mechanisms have largely not been determined. In this study, we demonstrated that Arabidopsis S-HSFs, i.e., S-HsfA2, S-HsfA4c, and S-HsfB1, derived from HSF splicing variants represent new kinds of HSF. Several molecular and genetic studies support this conclusion: (i) S-HSFs are localized in the nucleus, especially after heat stress, reflecting their cellular heat response features; (ii) S-HSFs have a unique conserved tDBD that binds to the HRE, a new heat response element; and (iii) S-HSFs confer extreme heat stress sensitivity as negative regulators of heat tolerance. Using S-HsfA2 as a representative S-HSF, we further revealed the molecular mechanisms underlying the ability of S-HSFs to prevent canonical HSR hyperactivation caused by HSP17.6B overexpression. Therefore, our findings reveal a novel mechanism by which plants balance thermotolerance and growth and offer insight into the breeding of thermotolerant plants.
Splice variants of HSFs generate new plant HSFs
In this work, we showed that Arabidopsis S-HsfA2, S-HsfA4c, and S-HsfB1 are generated from partial or full retention of the conserved intron in the DBD. S-HSFs (such as S-HsfA2, S-HsfA4c, and S-HsfB1) lack all the C-terminal functional domains of HSFs but share a common unique structural feature, i.e., tDBD. Another structural feature of S-HSFs is extended motifs or domains encoded by the retained introns. However, their lengths and sequences vary among different S-HSFs and are therefore less conserved than those of the tDBD. For example, lengths of 26 aa, 30 aa, and 13 aa were found for S-HsfA2, S-HsfA4c, and S-HsfB1, respectively. We found that the extended domain, i.e., the LRD, allows S-HsfA2 to act as a transcriptional repressor. More importantly, LRD is needed for the functions of S-HsfA2 in heat tolerance regulation. Therefore, we concluded that the extended motifs or domains are essential for the functions of S-HSFs.
Although S-HsfA2, S-HsfA4c, and S-HsfB1 only have conserved tDBD sequences plus adjacent extended motifs or domains, these small HSF isoforms are of biological importance since they negatively regulate extreme heat tolerance in Arabidopsis. Notably, two aspects related to heat stress are consistent with their biological relevance. First, S-HsfA2, S-HsfA4c, and S-HsfB1 strongly respond to extreme heat stress, indicating that they function in extreme heat stress in Arabidopsis. We also found that the constitutive expression of S-HsfA2 inhibits Arabidopsis growth. Considering this, Arabidopsis plants do not produce S-HSFs or produce fewer S-HSFs under normal conditions to avoid growth inhibition. Another is the heat stress-induced translocation of S-HsfA2 and S-HsfA4c into the nucleus to regulate target gene transcription. Overall, our data strongly support that S-HSFs act as new kinds of HSFs and thus increase the diversity of HSFs.
Surprisingly, AS events in the DBD of plant HSFs have not been detected in animal HSFs. Several reports have shown that animal HSFs utilize exon skipping to generate HSF splicing isoforms containing full-length DBDs (Tanabe et al., 1999; Fujikake et al., 2005; Zhang et al., 2010; Neueder et al., 2014). These animal HSF isoforms have different transcriptional activities and work synergistically to regulate the transcription of HSPs (Tanabe et al., 1999; Neueder et al., 2014). Therefore, new kinds of HSF seem to be plant specific, reflecting a unique feature of plant systems.
HRE is a heat response element
HSE is a known heat-responsive element and is essential for heat-inducible transcription of genes. In this study, we showed that the HRE is a heat response element, as determined by molecular, biochemical, and genetic analyses. HRE confers a minimal promoter response to heat and is responsible for heat-induced expression of the HSP17.6B promoter. He et al. (2022) reported a heat stress sensing and transmission pathway at the whole-plant level. Nitric oxide (NO) bursts in the shoot apex under heat stress, and NO, an S-nitrosoglutathione, can rapidly move from shoot to root through the vascular system in whole Arabidopsis plants. Interestingly, the GUS reporter driven by HREs was constitutively expressed in the shoot apical region, and heat stress enhanced and promoted GUS movement along the shoot vascular system to the leaves and hypocotyl. Therefore, the HRE exhibits heat stress sensing and transmission patterns, indicating a heat regulation function.
The HRE consists of two inverted HSE blocks (nGAAn) that share a G base. Although HRE is partially related to HSE, it does not bind to the DBD or to HsfA2 in vitro. In contrast, HRE is recognized by tDBD, S-HsfA2, S-HsfA4c, and S-HsfB1 in vitro. Loss of the wing domain within the DBD might partly explain why the DNA-binding characteristics of the tDBD change.
We also noted that HRE can drive the constitutive expression of the GUS reporter and bind nuclear extracts under normal conditions. These data suggest that some unknown constitutive transcription factors other than S-HSFs exist in Arabidopsis. In the future, these HRE-binding transcription factors need to be screened by Y1H and DNA‒protein pulldown assays. These studies can further characterize the working molecular mechanisms of HRE.
The noncanonical HSR: S-HsfA2-HRE-HSP17.6B
Using S-HsfA2 as a representative S-HSF, we proposed the S-HsfA2-HRE-HSP17.6B noncanonical HSR. In this HSR, S-HsfA2 binds to the HRE-HRE-like element to prevent HSP17.6B overexpression and eventually attenuates Arabidopsis tolerance to extreme heat. Given that HSP17.6B overexpression-mediated heat tolerance hyperactivation represses Arabidopsis growth, our results underscore the biological significance of this noncanonical HSR: preventing plant heat tolerance hyperactivation to maintain proper growth. Although we propose a noncanonical HSR based on S-HsfA2, S-HSF-mediated noncanonical HSRs should constitute a widespread regulatory mechanism in planta because the tDBD is highly conserved in S-HSFs and because the HRE can be bound by the tDBD.
S-HSFs act as new negative binding regulators of HSFs
During the canonical HSR, cells often utilize negative binding regulators of HSFs, including HSP70 and HSF-binding proteins (HSBPs), to inactivate HSFs in different ways (Morimoto, 1998). HSP70 represses the transcriptional activity of HSFs by directly binding to the transcriptional activation domain (Baler and Voellmy, 1996). HSBPs are conserved small nuclear proteins that dissociate trimeric HSFs and abate transcription activation (Satyal et al., 1998). Arabidopsis HSBP (AT4G15802) attenuates the canonical HSR by interacting with HSFs and decreasing HSF DNA-binding activity (Hsu et al., 2010). S-ZmHsf17 can interact with the DBD of ZmHsf17 to suppress the transactivation of ZmHsf17 by reducing the HSE-binding capacity of ZmHsf17 (Zhang et al., 2024), suggesting that S-HSFs may act as negative binding regulators of HSFs. In the present study, S-HsfA2 was also identified as a negative binding regulator of HsfA2. Unlike HSP70 and HSBPs, S-HsfA2 binds to the DBD, thus decreasing the HSE-binding capacity of HSFs such as HsfA2 and eventually attenuating HsfA2-regulated HSP17.6B promoter activity. According to the Y2H results, S-HsfA2 interacts with five HSFs (HsfA1e, HsfA2, HsfA3, HsfA7a, and HsfB2b). It is of interest to explore whether S-HsfA2 inactivates HsfA1e, HsfA3, HsfA7a, and HsfB2b.
S-HsfA2 molecular working model
Taken together, our findings in this study support the use of a molecular model in which S-HsfA2 balances the gain and loss of canonical HsfA2-regulated HSP17.6B overexpression-mediated HSR hyperactivation. S-HsfA2 directly binds to the HRE of the HSP17.6B promoter to repress HSP17.6B expression and interacts with the DBD of HsfA2 to inactivate HsfA2 binding to the HSP17.6B promoter, ultimately alleviating hyperactivation of the HsfA2-HSE-HSP17.6B HSR (Figure 11). Considering that S-HsfA2 generation occurs upon exposure to severe heat, this negative regulatory pathway is not an “enemy” but rather a “friend” to avoid canonical HSR hyperactivation in Arabidopsis.
Our findings could lead to the breeding of thermotolerant plants
It has been reported that natural variation in HsfA2 pre-mRNA splicing is associated with changes in thermotolerance during tomato domestication (Hu et al., 2020). In the present study, selective knockdown of S-HsfA2 improved the tolerance to transient extreme heat (45°C for 2 h). Given that S-HsfA2 favours Arabidopsis growth under extreme temperature conditions by inhibiting heat tolerance hyperactivation mediated by HSP17.6B overexpression, our findings offer insights for plant breeding to orchestrate plant extreme heat (such as heat waves) tolerance and growth via extreme heat-specific expression of S-HsfA2 homologues.
Materials and methods
Plant Materials and Growth Conditions
Arabidopsis (A. thaliana, Columbia-0), the hsfa4c-1 mutant (SALK_016087C), the hsfa4c-2 mutant (SALK_138256C), hsp17.6b-1 (SALK_013435C), hsp17.6b-2 (WISCDSLOXHS008_12D), and hsfb1 (SALK_104713C) were surface sterilized with sodium hypochlorite (25%, v/v) and washed with sterile double distilled water. After vernalization treatment for 3 days, the seeds were grown on half Murashige and Skoog (MS) agar plate media with a 16-h/8-h light/dark cycle at 22°C and a white light intensity of 150 mmol m−2 s−1. In this study, the age of seedlings was calculated as days after sowing (DAS).
Primers
The primers and synthesized oligonucleotides used in this study are listed in Supplemental Table S2.
Recombinant plasmid construction
The target DNA fragments were obtained by PCR with the Taq enzyme (Takara, Japan) and subsequently cloned and inserted into the corresponding vectors with the ClonExpress II One Step Cloning Kit (Vazyme Biotech, Nanjing, China).
The S-HsfA2 and S-HsfA2L-A coding sequences lacking stop codons were amplified from Arabidopsis genomic DNA using S-HsfA2-Flag-F/-R and S-HsfA2-Flag-F/S-HsfA2mut-Flag-R, respectively. Similarly, the coding sequence of HSP17.6B lacking the stop codon "TGA" was amplified using HSP17.6B-Flag-F/-R. The PCR products were cloned and inserted into the XbaI/BamHI site 35S:3×Flag (our laboratory) and sequenced using GUS-R to generate 35S:S-HsfA2-Flag (S-HsfA2-OE), 35S:S-HsfA2L-A-Flag (S-HsfA2L-A-OE), and 35S:HSP17.6B-Flag (HSP17.6B-OE).
We used a fusion PCR method to generate the 35S:S-HsfA2-RNAi construct based on pUCCRNAi. First, the PCR1 products (forward intron 1a of HsfA2, 104 bp) were amplified from the BD-S-HsfA2 plasmid using the primers F1/R1. Second, the PCR2 products (intron 1 of potato GA20 oxidase, 219 bp) were amplified from pUCCRNAi using the primers F2/R2. Third, the PCR3 products (reverse intron 1a of HsfA2, 105 bp) were amplified from the BD-S-HsfA2 plasmid using the primers F3/R3. Fourth, fusion PCR was performed in a total volume of 50 μL containing 33 ng of each purified PCR product (template) for 5 cycles at an annealing temperature of 55°C (without primers) followed by 25 cycles (adding F1/R3) at 65°C. The fusion fragments were cloned and inserted into the BamHI/SacI site of pBI121 and sequenced using GUS-R.
For the expression vector constructs, HsfA2-RFP-F/-R, S-HsfB1-RFP-F/-R and S-HsfB2a-RFP-F/-R were used to amplify the coding regions of HsfA2, S-HsfB1 and S-HsfB2a from cDNA, which were subsequently cloned and inserted into the BamHI/SpeI sites of pCAMBIA1300. The resulting 35S:HsfA2-RFP, 35S:S-HsfB1-RFP and 35S:S-HsfB2a-RFP were sequenced using RFP-R. The expression vectors 35S:S-HsfB1 and 35S:S-HsfB2a were constructed by antisense RNA knockdown technology and reverse primers anti-S-HsfB1-F/-R and anti-S-HsfB2a-F/-R. The coding region of S-HsfA4c lacking the stop codon TAG was amplified from cDNA using the primers S-HsfA4c-GFP-F/-R and cloned and inserted into the BglII/SpeI sites of pCAMBIA1302 (Clontech) to generate 35S:S-HsfA4c-GFP. The coding region of S-HsfA2 lacking the stop codon TAG was amplified from genomic DNA using the primers S-HsfA2-GFP-F/-R and cloned and inserted into the NcoI/SpeI sites of pCAMBIA1302 (Clontech) to generate 35S:S-HsfA2-GFP.
For the AD constructs, the coding sequences of 19 HSFs, S-HsfA2, and S-HsfA4c were amplified from heat-treated Arabidopsis cDNA using the corresponding primers, inserted into the BamHI/BglII site of pGAD424 (Clontech) to generate corresponding AD-HSF fusion vectors and identified by sequencing.
For bait construction, 3×HRE, 3×mHRE, HSE (Enoki and Sakurai, 2011), and mHSE were synthesized by Shanghai Sangon Biotechnology and subsequently cloned and inserted into pHIS2.1 (Clontech). The PCR products were cloned and inserted into the EcoRI/SpeI site of the pHIS2.1 vector (Clontech) and sequenced using pHIS2.1 forward or reverse primers.
For the BD constructs, the S-HsfA2 and S-HsfA2L-A coding sequences were amplified from Arabidopsis genomic DNA using BD-S-HsfA2-F/-R and BD-S-HsfA2-F/BD-S-HsfA2mut-R, respectively. The S-HsfA4c, S-HsfA4c△LRD, S-HsfB1 and S-HsfB2a coding sequences were amplified from cDNA using BD-S-HsfA4c-F/-R, BD-S-HsfA4c-F/BD-S-HsfA4cΔLRD-R, BD-S-HsfB1-F/-R and BD-S-HsfB2a-F/-R, respectively. The corresponding PCR products were subsequently cloned and inserted into the EcoRI/PstI sites of pGBKT7 (Clontech) to generate the BD-S-HsfA2, BD-S-HsfA2L-A, BD-S-HsfA4c, BD-S-HsfA4cΔLRD, BD-S-HsfB1 and BD-S-HsfB2a constructs. T7 primers were used to sequence the BD fusion vectors.
To generate the glutathione S-transferase (GST)-tagged expression plasmid pGEX4T-S-HsfA2. Using the BD-S-HsfA2 plasmid as a template, the PCR product was amplified with GST-S-HsfA2-F/-R and subsequently cloned and inserted into the BamHI/SalI sites of pGEX-4T.
For the His6-tagged expression plasmids, the HsfA2, S-HsfA2, S-HsfA4c S-HsfB1 and S-HsfB2a coding sequences were amplified from cDNA using His6-HsfA2-F/-R, His6-HsfA2-F/His6-S-HsfA2-R, His6-S-HsfA4c-F/-R, His6-S-HsfB1-F/-R and His6-S-HsfB2a-F/-R, respectively. The PCR products were inserted into the BamHI/SalI sites of pET-28a(+) to generate His6-HsfA2, His6-S-HsfA2, His6-S-HsfA4c, His6-S-HsfB1 and His6-S-HsfB2a. Then, using His6-HsfA2 and His6-S-HsfA2 as templates, the DBD and tDBD coding sequences were amplified with His6-DBD-F/-R and His6-DBD-F/His6-tDBD-R. The PCR products were also cloned and inserted into the BamHI/SalI sites of pET-28a(+) to obtain His6-DBD and His6-tD. The plasmids were subsequently sequenced using the T7 primer.
We used an asymmetric overlap extension PCR method to construct the HRE-35Sm:GUS and mHRE-35Sm:GUS plasmids using 3×HRE-35Sm-F or 3×mHRE-35Sm-F and the common reverse primer HRE-35Sm-R. The PCR products were subsequently cloned and inserted into the HindIII/XbaI sites of pBI121 instead of the 35S promoter. The recombinant reporter plasmids were subsequently sequenced using GUS-R primers for validation.
The wild-type HSP17.6B promoter (HSP17.6Bp, -637/+1) and HSP17.6BpΔHRE were amplified from Arabidopsis genomic DNA using HSP17Bp-F/-R and HSP17BpΔHRE-F/-R, respectively. The above PCR products were cloned and inserted into the HindIII/BamHI sites of pBI121 and sequenced by GUS-R to generate the corresponding constructs HSP17.6Bp:GUS and HSP17BpΔHRE:GUS.
A short, truncated 135-bp HSP17.6B promoter fragment (sHSP17.6Bp) was amplified from Arabidopsis genomic DNA using sHSP17.6Bp-LUC-F/-R and inserted into the HindIII/SpeI sites of pGreenII0800-LUC (LUC vectors containing the REN gene under the control of the 35S promoter as an internal control) to generate the reporter vector sHSP17.6Bp:LUC.
For the BiFC constructs, the coding regions of S-HsfA2 and HsfA2 and a series of HsfA2 genes progressively truncated from the N-terminus were amplified from AD-S-HsfA2 and AD-HsfA2 using cYFP-S-HsfA2-F/-R, nYFP-HsfA2-F/-R, nYFP-HsfA2ΔN-F and nYFP-HsfA2ΔNΔDBD-F, respectively. The above PCR products were cloned and inserted into the XbaI/BamHI sites of modified pCAMBIA1300 containing the cYFP or nYFP coding sequence to generate the corresponding constructs S-HsfA2-cYFP, HsfA2-nYFP, HsfA2ΔN-nYFP, and HsfA2ΔN-DBD-nYFP. The above vectors were identified by sequencing nYFP-R or cYFP-R.
Plant transformation and crossing
A series of plasmids related to S-HsfA2 (35S:S-HsfA2-Flag, 35S:S-HsfA2L-A-Flag, and 35S:S-HsfA2-RNAi), GUS reporter constructs [HRE-35Sm:GUS, mHRE-35Sm:GUS, and 35Sm:GUS (Wang et al., 2023)], recombinant vectors for HSP17.6B (35S:HSP17.6B-Flag, HSP17.6Bp:GUS, and HSP17BpΔHRE:GUS), and GFP fusion vectors (35S:S-HsfA2-GFP and 35S:S-HsfA4c-GFP) were introduced into the Agrobacterium GV3101 strain, which was subsequently used to transform the Columbia wild type using the flower infiltration method. The transgenic plants used in this study were T3 homozygous plants. The transgenic plants used in this study were T3 homozygous plants.
35S:HsfA2-RFP was subsequently introduced into A. tumefaciens GV3101. Ten-day-old Arabidopsis plants were vacuum infiltrated with A. tumefaciens as described by Marion et al. (2008) and subsequently incubated for 3 days.
The effector lines (♂,35S:S-HsfA2-Flag, 35S:S-HsfA2L-A-Flag) were crossed with GUS reporter lines (♀, HRE-35Sm:GUS) to generate T1 seeds by artificial pollination. To select the positive crossing lines, the leaves of T1 seedlings of the crossing lines (+effector) and control lines (−effector) were subjected to PCR analysis using a genomic DNA template. The following primers were used: S-HsfA2-F/121-R. Leaves from ten independent positive-crossing lines were used for protein isolation. GUS expression was detected by Western blotting as described below.
Subcellular localization
For S-HsfA2 and S-HsfA4c localization in Arabidopsis cells, the roots of 7-day-old 35S:S-HsfA2-GFP and 35S:S-HsfA4c-GFP transgenic Arabidopsis plants were observed via fluorescence microscopy and laser confocal microscopy (SP8) in the GFP channel. Cell nuclei were stained with 4,6-diamidino-2-phenylindole (DAPI, C0060; Solarbio). The fusion protein expression vectors 35S:S-HsfB1-RFP and 35S:S-HsfB2a-RFP were transiently transformed into tobacco. After 48 h, the leaf cells were stained with the nuclear stain DAPI under a fluorescence microscope in the RFP channel.
Transcriptional activity assay in yeast cells
The transcriptional activation activity was determined in synthetic defined (SD) medium lacking Trp but containing 40 μg mL-1 5-bromo-4-chloro-3-indolyl-α-D-galactopyranoside (X-α-gal; Sigma‒Aldrich) at 30°C for 3 days. BD and BD-PVERF15 were used as negative and positive controls, respectively. The β-galactosidase activity in liquid cultures was determined using an o-nitrophenyl-β-D-galactopyranoside (ONPG) assay in three independent clones.
GUS staining
GUS reporter transgenic Arabidopsis plants were immersed in precooled 90% [v/v] acetone for 20 min and then soaked in GUS staining solution (0.5 mg/mL X-Gluc, 100 mM Na3PO4 [pH=7.0], 50 μM K4[Fe6]·3H2O, 50 μM K3[Fe6], 1 mM EDTA [pH=8.0]) at 37°C in the dark for 12 to 24 h. After elution with 100% [v/v] anhydrous ethanol several times, observations were made with a microscope.
Heat stress treatments
In a thermotolerance test, Arabidopsis plants (10 or 12 DAS) were incubated at 45°C for 2 h following recovery at 22°C for 5 or 15 days. In the soil experiments, plants (12 DAS) were planted in soil for 8 days, treated in an incubator at 45°C for 3 h and returned to 22°C for 5 days.
To prepare nuclear extracts, 14-day-old Arabidopsis plants were transferred to filter paper with 1/4 MS liquid media and subjected to heat shock in a temperature incubator (22°C, 37°C, and 42°C) for 1 h.
To analyse GUS mRNA or protein expression levels, 14-day-old HRE-35Sm:GUS, mHRE-35Sm:GUS, or 35Sm:GUS transgenic Arabidopsis plants were subsequently transferred to filter paper in 1/4 MS liquid media and subjected to heat shock in a temperature incubator (22°C, 37°C, and 42°C) for 1 h. For heat time-course analysis of the HRE-35Sm:GUS transgenic Arabidopsis plants, samples were taken at various treatment intervals (0, 15, 30, 45, and 60 minutes).
Heat tolerance assays
For the survival rate, the true leaves of the plants were chlorotic and considered dead. For the root length assay, the seeds of WT and transgenic Arabidopsis plants (i.e., S-HsfA2-OE, S-HsfA2L-A-OE, and S-HsfA2-KD) were sown on vertical one-half-length MS agar plates at 22°C for 12 days and then subjected to root length analysis with the ImageJ analysis tool. The detached shoots were subjected to chlorophyll content analysis. Shoot chlorophyll contents were determined at 663 and 645 nm as described previously (Chen et al., 2024).
RNA isolation, cDNA synthesis and PCR analysis
Total RNA was extracted from plant materials using an RNAprep Pure Plant Kit with on-column DNase digestion (Tiangen Biotech, China) according to the manufacturer’s protocol. First-strand cDNA was synthesized from RNA (approximately 2 μg) with oligo(dT) primers according to the instructions of the PrimeScript First Strand cDNA Synthesis Kit (Takara).
RT‒PCR splicing analysis was carried out with Ex-Taq polymerase (Takara, Japan) for a total of 25-28 cycles. YLS8 (AT5G08290) was used as a loading control.
RT‒qPCR was performed on an IQ5 Multicolor Real-Time PCR Detection System (Bio-Rad) with the SYBR Premix Ex-Taq Kit (Takara). EF-1α (AT1G18070) was used as an internal control. The relative expression levels were analysed using the delta-delta cycle threshold method according to CFX ManagerTM software. A P value < 0.05 indicated a statistically significant difference.
Chromatin immunoprecipitation combined with high-throughput sequencing (ChIP-Seq)
Ten-day-old 35S:S-HsfA2-GFP transgenic Arabidopsis plants were treated at 45°C for 2 h following recovery at 22°C for 20 h. Two independent transgenic lines (#4 and #6) were generated and separately sequenced for each ChIP-seq. The plant samples were subjected to ChIP assays using an anti-GFP antibody (ab290, Abcam) according to the instructions for the EpiQuik Plant ChIP Kit (Epigentek). Enriched DNA was used to generate sequencing libraries using the nano-ChIP-seq protocol as previously described (Adli and Bernstein, 2001). The libraries were sequenced using the Illumina HiSeq 2500 platform at Majorbio (Shanghai, China). Following quality control of the resulting sequencing data, MACS software was used to analyse the ChIP-Seq data to obtain the peak (enrichment region) location and information. The S-HsfA2 binding motifs were identified using the MEME-ChIP tool (Machanick and Bailey, 2011). Our raw data have been deposited in the NCBI database under BioProject accession number PRJNA947075.
Protein extraction
The GST-tagged proteins (GST-S-HsfA2), GST mock proteins, His6-tagged proteins (His6-HsfA2/S-HsfA2/S-HsfA4c/S-HsfB1/S-HsfB2a/DBD/tDBD) and His6 mock proteins were purified using glutathione Sepharose 4B beads (GE Healthcare) and nickel-nitrotriacetic acid (Ni-NTA) agarose beads (CwBio, China), respectively. Total protein was extracted from plant samples according to Liu et al. (2013). Twenty-day-old Arabidopsis plants were left untreated (control, 22°C) or treated at 37°C or 42°C for 2 h, after which 2 g of each sample was subjected to nuclear protein extraction. Nuclear fractionation was performed based on the protocol described by Xia et al. (1997) with modifications to that of Wang et al. (2020). Protein concentrations were determined by using a SpectraMax QuickDrop and bovine serum albumin (Sigma) as the reference standards for analysis.
Western blot analysis
Proteins separated on a gel were electrophoretically transferred to a pure nitrocellulose blotting membrane (Pall Life Sciences). The membrane was cut across the molecular mass region of the corresponding proteins and separately probed with the following corresponding antibodies: an anti-β-glucuronidase (N-terminal) antibody (G5420, Sigma‒Aldrich) and an anti-tubulin antibody (T5168, Sigma‒Aldrich) for the expression of GUS in HRE-35Sm:GUS, mHRE-35Sm:GUS, and 35Sm:GUS seedlings; an anti-GFP (ab290, Abcam) and an anti-mCherry antibody (ab213511, Abcam) for the detection of 35S:S-HsfA2-GFP and 35S:HsfA2-RFP transgenic Arabidopsis seedlings; an anti-GST antibody (EASYBIO) and an anti-His6 antibody (Tiangen Biotech, China) for the expression of GST- or His6-tagged proteins; an anti-histone H3 antibody (AS10710, Agrisera, Vännäs, Sweden); and an anti-UGPase antibody (AS05086, Agrisera) to verify successful nuclear protein isolation. Chemiluminescence was performed on a Fujifilm LAS-4000 imager with ECL Prime Western Blot detection reagent (Amersham Biosciences). The ImageJ analysis tool was used for grayscale analysis of the Western blot bands of GUS and tubulin.
Yeast one-hybrid (Y1H) and electrophoretic mobility shift assays (EMSAs)
Y1H and EMSA were performed as described previously (Sun et al., 2015; Wang et al., 2020).
ChIP‒qPCR
Ten-day-old 35S:S-HsfA2-Flag and 35S:HsfA2-RFP plants were subjected to ChIP assays. The EpiQuik Plant ChIP Kit (Abcam), anti-Flag (F3165-2MG; SIGMA), anti-RFP (ab213511; Abcam) and normal mouse IgG (provided by the kit) were used for the assay. After immunoprecipitation, the enriched DNA was analysed by qPCR. Quantification was carried out using the input DNA relative to 1%. The enrichment of the ChIP target was defined as the binding rate between the immunoprecipitated samples of the Flag and RFP antibodies and the control immunoprecipitated sample of IgG. As noted above, the binding ratio was calculated using the triangular incremental period threshold method. ChIP‒qPCR for the plant materials described above was performed using the 3’-UTR as a negative control for HRE-HRE-like sequences as well as for the HSE.
DNA‒protein pulldown assay
DNA pulldown experiments were performed using Pulldown Kits for Biotin-Probes (Viagene Biotech, Changzhou, China) according to the manufacturer’s instructions. Briefly, equal amounts (50 μg) of GST-S-HsfA2 or His6-HsfA2 were incubated in binding buffer (50 mM Tris-HCl [pH 7.5], 100 mM NaCl, 0.1% Triton X-100 [v/v]) in a 4°C rotator for 0 h (control), 4 h, or 12 h. The corresponding samples were incubated with biotin-labelled HSE (7 ng) and 5 ng of polydeoxyinosinic-deoxycytidylic acid (dI-dC) for 40 min at 25°C. Then, the DNA/protein binding mixture was bound to streptavidin-agarose beads by incubating for 40 min at 25°C with gentle shaking and then washed three times to remove the unbound DNA/proteins. The bead-bound proteins were dissociated by boiling for 5 min in dissociation solution and analysed by immunoblotting (IB) with an anti-His6 antibody.
Yeast two-hybrid (Y2H) assay
The bait plasmid BD-S-HsfA2 and a series of AD-HSF prey plasmids were cotransformed into the Y2H Gold Cell yeast strain (Weidi, Shanghai, China). The GAL4 BD bait vector (pGBKT7) and GAL4 AD prey vector (pGAD424) combination were used as negative controls. pGBKT7-53 (BD-53) and pGADT7-T (AD-7) were transformed as positive controls. Their interaction was identified by a spot assay.
Bimolecular fluorescence complementation (BiFC) assay
Paired nYFP and cYFP constructs, i.e., HsfA2-nYFP/S-HsfA2-cYFP, HsfA2ΔN-nYFP/S-HsfA2-cYFP, HsfA2ΔNΔDBD-nYFP/S-HsfA2-cYFP, GUS-nYFP (nYFP negative control)/S-HsfA2-cYFP, HsfA2-nYFP/GUS-cYFP (cYFP negative control), and GUS-nYFP/GUS-cYFP, were coinfiltrated into N. benthamiana leaves for 48 h. After DAPI staining for 30 min to 1 h, the YFP fluorescence signal was acquired via confocal microscopy (Axio Imager M2; Germany) under the YFP and DAPI channels.
GST pulldown assay
Equal amounts (10 μg) of bacterially expressed and purified proteins, i.e., GST mock with His6 mock, GST mock with His6-HsfA2, GST-S-HsfA2 with His6 mock, or GST-S-HsfA2 with His6-HsfA2, were incubated in binding buffer (50 mM Tris-HCl [pH 7.5], 100 mM NaCl, 0.1% Triton X‒100 [v/v]) overnight in a 4°C rotator (with 50 μL used as the input). Fifty microliters of GST beads were added, and the mixture was incubated at 4°C for 2 h. After washing with washing buffer (50 mM Tris-HCl, pH 7.5; 150 mM NaCl; 0.1% Triton X-100 [v/v]), the proteins were eluted with 20-30 μL of 20 mM GSH. Subsequently, with input as a positive control, anti-GST and anti-His6 antibodies were used to detect His6-HsfA2 and GST-S-HsfA2 in the pull-down samples by immunoblotting.
Dual-luciferase reporter assay
Leaves of N. benthamiana were infiltrated with a mixed bacterial solution of Agrobacterium tumefaciens (with each construct at OD600=0.5) for induction using sHSP17.6Bp:LUC together with the paired effectors GUS-cYFP/HsfA2-nYFP, S-HsfA2-cYFP/HsfA2-nYFP, S-HsfA2-cYFP/GUS-nYFP, and GUS-cYFP/GUS-nYFP (vector control). LUC bioluminescence was detected after 48 h using D-luciferin, sodium salt (GOLDBIO) and a CCD camera (Tanon, China). LUC and REN activities were measured on an automated microplate reader (Varioskan Flash, Thermo, USA) using the Dual Luciferase Reporter Gene Assay Kit (Yeasen Biotechnology, Shanghai, China). The LUC/REN ratio of the GUS control (GUS-cYFP/GUS-nYFP) transformed with sHSP17.6Bp:LUC was used as the calibrator (set as 1). Three independent experiments were performed.
Statistical analysis
Statistical Product and Service Solutions (SPSS23) and Microsoft Excel 2007 (Microsoft Corp) were used to perform one-way ANOVA, and Student’s t tests were performed for P < 0.05.
Accession numbers
The Arabidopsis Genome Initiative numbers for the genes mentioned in this article are as follows: HsfA2 (AT2G26150), HsfA4c (AT5G45710), HSP17.6B (AT2G29500), YLS8 (AT5G08290), HsfB1 (AT4G36990), HsfB2a (AT5G62020), and EF-1α (AT1G18070). The ChIP-seq data supporting the findings of this study have been deposited in the NCBI database under BioProject accession number PRJNA947075.
Acknowledgements
We thank Prof. Jing Li (Capital Normal University, China) for critical reading and valuable suggestions. This work was supported by the National Natural Science Foundation of China (grant nos. 32070546 and 31771361 to X.Q.).
Data availability
All the data generated or analysed during this study are included in the manuscript and supporting files.
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