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Article

Overexpression of OsPIN9 Impairs Chilling Tolerance via Disturbing ROS Homeostasis in Rice

by
Qiqi Ouyang
,
Yanwen Zhang
,
Xiaoyi Yang
,
Chong Yang
,
Dianyun Hou
,
Hao Liu
and
Huawei Xu
*
College of Agriculture, Henan University of Science and Technology, Luoyang 471000, China
*
Author to whom correspondence should be addressed.
Plants 2023, 12(15), 2809; https://doi.org/10.3390/plants12152809
Submission received: 4 July 2023 / Revised: 23 July 2023 / Accepted: 26 July 2023 / Published: 28 July 2023
(This article belongs to the Special Issue Abiotic Stress of Crops: Molecular Genetics and Genomics)
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Abstract

:
The auxin efflux transporter PIN-FORMED (PIN) family is one of the major protein families that facilitates polar auxin transport in plants. Here, we report that overexpression of OsPIN9 leads to altered plant architecture and chilling tolerance in rice. The expression profile analysis indicated that OsPIN9 was gradually suppressed by chilling stress. The shoot height and adventitious root number of OsPIN9-overexpressing (OE) plants were significantly reduced at the seedling stage. The roots of OE plants were more tolerant to N-1-naphthylphthalamic acid (NPA) treatment than WT plants, indicating the disturbance of auxin homeostasis in OE lines. The chilling tolerance assay showed that the survival rate of OE plants was markedly lower than that of wild-type (WT) plants. Consistently, more dead cells, increased electrolyte leakage, and increased malondialdehyde (MDA) content were observed in OE plants compared to those in WT plants under chilling conditions. Notably, OE plants accumulated more hydrogen peroxide (H2O2) and less superoxide anion radicals ( O 2 ) than WT plants under chilling conditions. In contrast, catalase (CAT) and superoxide dismutase (SOD) activities in OE lines decreased significantly compared to those in WT plants at the early chilling stage, implying that the impaired chilling tolerance of transgenic plants is probably attributed to the sharp induction of H2O2 and the delayed induction of antioxidant enzyme activities at this stage. In addition, several OsRboh genes, which play a crucial role in ROS production under abiotic stress, showed an obvious increase after chilling stress in OE plants compared to that in WT plants, which probably at least in part contributes to the production of ROS under chilling stress in OE plants. Together, our results reveal that OsPIN9 plays a vital role in regulating plant architecture and, more importantly, is involved in regulating rice chilling tolerance by influencing auxin and ROS homeostasis.

1. Introduction

Due to extreme weather events, plants are progressively subjected to various abiotic stresses, such as chilling stress. Chilling stress restricts the geographical distribution and affects plant productivity [1,2]. Rice (Oryza sativa L.) originates from tropical and subtropical regions and is more sensitive to chilling stress than other cereal crops [3,4,5]. Previous data showed that rice yield decreased by 30–40% due to cold stress in temperate areas [6]. Therefore, improving rice chilling tolerance for maintaining food security is an urgent target [7]. In recent years, excellent progress has been made in understanding the physiological and molecular mechanisms underlying chilling stress [1,8,9,10]. Chilling stress triggers Ca2+ influx, which plays a key role in chilling tolerance [1,11,12,13]. For example, COLD1 (CHILLING-TOLERANCE DIVERGENCE 1) and OsCNGC9 (CYCLIC NUCLEOTIDE-GATED CHANNEL 9) have been demonstrated to regulate rice chilling tolerance by mediating Ca2+ influx under chilling stress [7,14]. Growing evidence shows that low temperatures dramatically induce the expression of the well-known C-repeat binding factor (CBF)/dehydration-responsive element binding factor (DREB) genes, which play a crucial role in plant chilling tolerance [15,16,17,18]. Conversely, evidence also showed that the transcriptional abundance of these transcription factors plays a minor role in cold tolerance [19,20,21]. Additionally, reactive oxygen species (ROS) are pivotal in various abiotic stress adaptations [22,23]. Low-level ROS at the early stress stage act as signals to trigger diverse stress responses, whereas excessive ROS cause cell damage; therefore, ROS homeostasis should be well controlled during abiotic stresses [10], including chilling tolerance [21,24,25,26]. In line with this, it is evidenced that more ROS are accumulated at the relative earlier chilling stage, while less ROS accumulation is detected at the late chilling stage in high chilling tolerance rice than in low chilling tolerance rice, which suggests that ROS homeostasis plays a vital role in regulating rice chilling tolerance [21].
The phytohormone auxin (indole-3-acetic acid, IAA) functions in almost all plant developmental processes and is involved in responses to many environmental clues, such as light, gravity, and temperature fluctuations [27,28,29,30]. Most auxin is synthesized in primordial and young leaves [31,32,33] and is transported basipetally to facilitate plant growth and development. The plant-specific PIN-FORMED (PIN) efflux carriers are the most important players in this process [34], which cooperated with the AUXIN1 (AUX1)/LIKE AUX1 (LAX) influx carriers, the phosphoglycoprotein (PGP/MDR/ABCB) efflux/influx transporters [35,36] and PIN-LIKES (PILS) family proteins [37] to drive polar auxin transport.
Significant progress has been made in the role of PIN genes, which are mainly derived from the dissection of PIN genes in the model plants Arabidopsis thaliana and rice [38,39,40,41,42]. The Arabidopsis genome possesses eight PIN genes, and the function of these AtPIN genes has been deeply investigated [38,43,44]. In contrast, the role of rice OsPIN genes is largely unknown. Twelve OsPIN genes have been identified in the rice genome [45,46], and several OsPIN genes have been functionally identified to play key roles in regulating rice growth and development by influencing polar auxin transport. OsPIN1b, which is also named OsPIN1, is mainly expressed in the vascular tissues and root primordial and functions in regulating the emergence of adventitious roots [47]. Our previous study showed that OsPIN1b, also designated as OsPIN1a [46], is associated with root negative phototropism [48]. Further investigation indicated that OsPIN1a and OsPIN1b redundantly regulate root and inflorescence development, while OsPIN1c and OsPIN1d are redundantly involved in modulating panicle formation [49]. OsPIN2 regulates rice root system architecture and gravitropism by influencing auxin transport and distribution in roots, especially in columella cells [50,51,52]. OsPIN5b is constitutively expressed in vegetative and reproductive tissues and functions in modulating rice architecture and yield [53]. OsPIN10a (also designated as OsPIN3t) is mainly expressed in vascular tissue and functions in drought stress response and drought tolerance [54]. Recently, the monocot-specific OsPIN9 gene has been indicated to function in regulating tiller bud outgrowth and affecting tiller number [55]. In addition, the expression profile of PIN genes, such as tissue-specific analysis and response to abiotic stress, in the other two monocot plants, sorghum (Sorghum bicolor) and maize (Zea mays), was deeply investigated [56,57,58]. Taken together, although excellent progress has been made in the functional dissection of OsPIN genes, which mainly focuses on rice growth and development, whether and how OsPIN genes are involved in regulating abiotic stresses, especially chilling stress, is still elusive.
The underlying mechanism of auxin in regulating cold tolerance is largely unknown, although auxin plays key roles in regulating plant growth and development. Increasing evidence has shown that cold stress is tightly related to auxin homeostasis. For example, an earlier study indicated that temperature could influence exogenous auxin transport velocity in some plant species [59]. Although the underlying mechanism of auxin in regulating cold tolerance is almost completely unknown, cold stress not only differentially regulates the expression of auxin-responsive genes but also markedly increases auxin content in rice [30,60]. Additionally, auxin transport could be suppressed and restored by low temperature and room temperature, respectively [61]. Inhibition of intracellular trafficking of auxin efflux carriers substantially influences auxin homeostasis under cold conditions [29]. Further research demonstrated that GNOM, a SEC7 containing ARF-GEF, which is closely associated with endosomal trafficking of auxin efflux carriers, can positively regulate Arabidopsis cold tolerance [62]. Collectively, these results strongly suggest that auxin homeostasis and transport are implicated in regulating plant chilling tolerance. However, little is known about the underlying molecular mechanisms involved in the role of auxin homeostasis and transport in chilling stress.
Previous studies demonstrated that OsPIN9 functions in polar auxin transport and is involved in regulating adventitious root number and tiller number [55]. Recently, Manna et al. (2022) [63] reported that salt and drought treatment significantly induced OsPIN9 expression, indicating the potential role of OsPIN9 in abiotic stress adaptation. In line with this, our previous study showed that mutation of OsPIN9 by CRISPR/Cas9 technology confers enhanced chilling tolerance in rice [64]. However, whether and how OsPIN9 overexpression regulates rice chilling tolerance is unknown. In addition, since off-target effects or newly formed mutation proteins derived from CRISPR/Cas9 technology have the potential to cover the true function of target genes, it is necessary to further verify gene function by upregulating its expression. Here, we functionally examined the role of OsPIN9 in modulating chilling tolerance by overexpressing technology. Our results showed that overexpression of OsPIN9 not only leads to the alteration of rice architecture but also impairs rice chilling tolerance. We provided strong evidence that OsPIN9 plays a crucial role in modulating rice chilling tolerance and shed light on the relationship between polar auxin transport and chilling tolerance in rice.

2. Results

2.1. Expression Patterns of OsPIN Genes under Chilling Stress

Increasing evidence shows that plant chilling tolerance is tightly associated with polar auxin transport [29,59,61,62]. However, the mechanism by which OsPIN genes respond to chilling stress is still largely unknown. To this end, quantitative real-time polymerase chain reaction (qRT-PCR) was performed to evaluate the responses of OsPIN genes in rice roots upon chilling stress. Nine OsPIN genes (OsPIN1b, OsPIN1c, OsPIN1d, OsPIN2, OsPIN5a, OsPIN5b, OsPIN9, OsPIN10a, and OsPIN10b), which can be detected in rice roots [39,45,46], were selected to analyze the expression profiles under chilling stress. OsPIN1b displayed a different expression pattern under chilling treatment compared to OsPIN1c and OsPIN1d, albeit belonging to the same subfamily. In detail, OsPIN1b was induced to the highest expression after chilling for 6 h and then decreased sharply, while OsPIN1c and OsPIN1d were suppressed after chilling for 3 h and kept to a relatively constant level thereafter. OsPIN2 remained at a constant level under chilling treatment. Similar to OsPIN1b, OsPIN5a and OsPIN5c also showed increased expression first and then decreased. Three monocot-specific PIN genes, OsPIN9, OsPIN10a, and OsPIN10b, were greatly inhibited after chilling treatment and gradually decreased with treatment duration (Figure 1). Intriguingly, the paralogous OsPIN genes, OsPIN1c/1d, OsPIN5a/5c, and OsPIN10a/10b, showed a similar expression profile under chilling stress, implying that they might play a synergistic role in chilling tolerance.

2.2. Generating OsPIN9-Overexpressing Transgenic Rice and Phenotypes of Transformants

The monocot-specific OsPIN9, which was dramatically suppressed under chilling treatment, was chosen for further study. To obtain insight into the function of OsPIN9 in chilling tolerance, a plasmid carrying the OsPIN9 ORF, driven by a strong constitutive Ubiquitin promoter (pUbi) (Figure 2A), was introduced into rice cultivar Nipponbare by Agrobacterium. The transgenic plants were confirmed by PCR using genomic DNA as a template with specific primers. qRT-PCR analysis showed that the OsPIN9 transcript significantly increased by 3.6–1237 times in the five tested transgenic line roots compared with that in WT plants (Figure 2B). Among which, A4 and B14 represented the high expression levels, A1 represented the moderate expression level, and A2 and B15 represented the low expression levels. Three lines, A4, A1, and B15, which represented high, moderate, and low expression levels of OsPIN9, were employed to further analyze the expression of OsPIN9 in leaves, roots, and stem bases. The highest increase in expression was detected in leaves, followed by roots and stem bases (Figure 2C). Two T2 homozygous transgenic lines, A4 and B14, with high expression levels of OsPIN9, designated as OE1 and OE2, respectively, were used for further investigation.
Overexpression of OsPIN9 significantly decreased shoot height, root length, and adventitious root number after germination for 7 d in comparison with those in WT plants (Figure 3A). In detail, compared with the WT plants, the shoot height, root length, and adventitious root number of the OE plants were significantly decreased by 23–26%, 11–15%, and 17–18%, respectively. After germination for 14 d, shoot height and adventitious root number of OE lines declined by 21–25% and 13–14%, respectively, compared to those in WT plants. However, the root length was similar to WT plants at this stage (Figure 3B), indicating that rice plants can dynamically adapt to the change in auxin transport to some extent.

2.3. Overexpression of OsPIN9 Disturbs Auxin Homeostasis in Rice

It was reported that overexpression of OsPIN9 accelerated auxin transport from shoots to roots and resulted in an increase and decrease of IAA in roots and shoots, respectively [55]. N-1-naphthylphthalamic acid (NPA) is an inhibitor of polar auxin transport and can interact with PIN carriers directly [65]. To further assess the role of OsPIN9 in auxin transport, germinated wild-type and transgenic seeds were cultured in Kimura B complete nutrient solution [39] supplemented with 0.5 μM NPA. After 7 d treatment, NPA obviously inhibited plant growth; the shoot height of OE lines was significantly decreased compared to WT plants both under normal conditions and NPA treatment. Contrastingly, the root length of OE lines was shorter than that of WT under normal conditions, while it increased significantly more than that of WT plants under NPA treatment. In detail, the root length of OE lines was significantly decreased by 10–12% when compared with WT under normal conditions, whereas it was about 39% and 49% longer compared with control plants after NPA treatment, indicating the roots of OE lines were more resistant to NPA than those of WT plants (Figure 4). Overexpression of OsPIN9 significantly lowered the adventitious root number under control conditions, while NPA treatment severely decreased the adventitious root number and completely abolished the difference in adventitious root number between WT and OE lines. In addition, the ability to grow upright in some OE plant shoots was obviously inhibited and showed a partially impaired negative gravitropism compared with that in WT plants, indicating that the shoots of OE lines are probably more sensitive to NPA than those of WT plants (Figure 4). Collectively, these results demonstrate that auxin homeostasis is disturbed in OE lines.

2.4. Overexpression of OsPIN9 Impairs Chilling Tolerance in Rice

Due to the fact that polar auxin transport is closely related to chilling stress [66], and PIN carriers perform a rate-limiting role in regulating auxin efflux [34], as well as the quick suppression of OsPIN9 under chilling stress (Figure 1), the role of OsPIN9 in chilling tolerance was evaluated in WT and OE plants. Fourteen day old rice seedlings were moved from 28 °C to 4 °C. After chilling for 36 h, most WT leaves remained normal, but almost all leaves of OE plants displayed rolling and wilting (Figure 5A). The survival rate of OE plants was significantly lower than that of WT plants after 3 d of recovery at 28 °C (Figure 5A). Consistently, after 57 h of chilling treatment followed by 3 d of recovery, the survival rate of WT was dramatically higher than that of OE plants (Figure 5B). In detail, WT plants showed a 98% survival rate, while the survival rates of OE1 and OE2 were only about 17% and 26%, respectively. These results suggest that the expression of OsPIN9 is involved in negatively modulating rice chilling tolerance.
We then detected several physiological indicators, including cell death, electrolyte leakage, and malondialdehyde (MDA) contents, to evaluate the influence of overexpression of OsPIN9 on rice chilling tolerance. Trypan blue staining, which is an indicator of cell death, was performed to monitor the cell damage. There was no apparent difference in trypan blue staining in leaves between WT and OE plants under normal growth conditions, while staining was more intensive in the leaves of OE plants compared to that of WT plants after chilling for 36 h and 57 h (Figure 6A), indicating that the cell death in OE plants is greater than that in WT plants. In line with this, another two indicators, electrolyte leakage and MDA contents, were both significantly increased in OE plants compared to those in WT plants after chilling for 36 h and 57 h (Figure 6B,C). Taken together, these results strongly suggest that overexpression of OsPIN9 substantially impairs rice chilling tolerance.

2.5. The Role of OsDREB1 Regulon and Ca2+ Signaling-Related Genes in Chilling Stress

The expression of OsDREB1 genes could be dramatically induced by low temperatures [19,67], and more and more evidence has demonstrated that OsDREB1 genes play a vital role in chilling stress [14,19,67]. We then detected the expression levels of OsDREB1A, OsDREB1B, and OsDREB1C in WT and OE plants upon chilling stress. Under normal conditions, these OsDREB1 genes were significantly more induced in OE plants than in WT plants (Figure 7A). However, after chilling for 8 h, the expression levels of these genes in OE plants were similar to or even lower than those in WT plants (Figure 7A). Similarly, trehalose-6-phosphate phosphatase 1 (OsTPP1), which has been demonstrated to play a vital role in rice cold tolerance [9,68], displayed a similar expression profile with OsDREB1 genes in WT and OE plants under both normal and chilling conditions (Figure 7B). Additionally, increasing evidence shows that Ca2+ signaling is involved in chilling tolerance regulation [9,69], and COLD1 and OsCNGC9 have been demonstrated to facilitate cytoplasmic Ca2+ elevation and positively regulate rice cold tolerance [7,14]. To evaluate the role of these Ca2+ signaling-related genes in OE lines under chilling stress, we further examined the expression of these two genes under normal and chilling conditions. The results showed that both COLD1 and OsCNGC9 in OE lines were slightly induced compared to those in WT plants under normal conditions, while strikingly suppressed under chilling stress (Figure 7C). Collectively, these data suggest that the defense response might be triggered in advance under normal conditions, and the DREB1 regulon and Ca2+ signaling are likely to be implicated in regulating the chilling tolerance of OE lines.

2.6. OsPIN9-Overexpressing Plants Accumulated More H2O2 Rather Than O 2 under Chilling Stress

In addition to the well-known CBF/DREB regulon, reactive oxygen species (ROS) also play a crucial role in chilling stress [21]. To further investigate the underlying mechanism of OsPIN9 under chilling stress, ROS content assays were performed by diaminobenzidine tetrahydrochloride (DAB 4HCl) staining for H2O2 and NBT staining for O 2 under normal and chilling conditions. The result showed that OE plants accumulated a similar level of H2O2 and O 2 compared to WT plants before chilling treatment (Figure 8A). After chilling for 36 h, the leaves of OE plants accumulated more H2O2 and less O 2 compared to WT plants (Figure 8B). Consistently, more H2O2 and less O 2 were still detected in OE leaves compared to WT plants after chilling for 57 h (Figure 8C). These results indicate that OE lines accumulate more H2O2 than O 2 when compared with WT plants, which probably causes cell damage and impairs rice chilling tolerance.

2.7. The Delayed Induction of Antioxidant Enzymes Probably Leads to the Accumulation of H2O2 in OE Lines

ROS are vital signaling molecules that play a crucial role in biotic and abiotic stress responses, while their content should be carefully controlled in plant cells via an array of enzymatic and non-enzymatic antioxidants [23]. Given that ROS homeostasis is disturbed in OE lines, we then analyzed the activities of three antioxidant enzymes, including superoxide dismutase (SOD), catalase (CAT), and peroxidase (POD), which play a key role in ROS scavenging [10,23], before chilling treatment and after chilling for 36 h and 72 h. There were no significant differences in SOD and CAT activities in WT and OE plants, while POD activity was significantly increased in OE lines compared to WT plants under normal conditions (Figure 9A). After chilling for 36 h, the activities of CAT and SOD decreased significantly in OE plants compared to those in WT plants. To our surprise, the POD activity was still strikingly higher in OE lines than in WT plants (Figure 9B). After chilling for 57 h, the activities of the three enzymes in OE lines all increased greatly compared to those in WT plants (Figure 9C). These results imply that it is likely that the decreased activities of SOD and CAT rather than increased POD activity led to the accumulation of H2O2 in OE lines at the early chilling stage, and the delayed induction of SOD and CAT is ineffective to quench excess ROS at the late chilling stage and causes cell damage in OE lines. However, considering that SOD usually functions in the conversion of O 2 to H2O2, the source of the accumulated H2O2 during chilling stress needs further investigation.

2.8. OsRobh Genes Show Differential Expression in OsPIN9-Overexpressing Lines

Previous reports showed that respiratory burst oxidase homologs (Rboh), also known as NADPH oxidase, play critical roles in various cellular activities and responses to abiotic stresses by regulating the production of ROS [70,71,72]. For the higher production of H2O2 detected in OE lines, we assayed the expression of OsRboh genes before and after chilling stress treatment to evaluate the source of H2O2 in OE lines. As shown in Figure 10, under normal conditions, most OsRboh genes in transgenic lines kept similar expression levels compared to those in WT plants, except for OsRboh1, OsRboh2, and OsRboh9, which showed a slight increase in OE lines. After chilling for 24 h, more OsRboh genes were induced, including OsRboh2, OsRboh4, OsRboh6, and OsRboh8, and showed a relative higher expression level in OE lines, which may contribute to the production of H2O2 in transgenic lines under chilling conditions.

3. Discussion

Although excellent progress has been made in the molecular mechanisms of plant cold adaptation [8,9,10], auxin, the first phytohormone discovered and one of the most important phytohormones in plant growth and developmental regulation, its role in modulating chilling adaptation is still elusive. In this present study, the role of a monocot-specific OsPIN9 gene, which mainly functions in regulating auxin transport basipetally, in chilling stress was investigated by overexpression technology.
Auxin plays a vital role in regulating almost all cellular processes, and in many cases, an appropriate auxin level and distribution within plant tissues are direct determinators affecting plant architecture [73]. PIN genes have been demonstrated to play a central role in auxin efflux and, consequently, influence auxin content and distribution in various tissues. Expression levels of PIN genes are usually closely associated with plant architecture [74,75]. The most representative is AtPIN1, and disruption of AtPIN1 seriously influences inflorescence development and leads to the formation of needle-like inflorescence in Arabidopsis [76]. The rice genome possesses 12 OsPIN genes [45,46], and although the possibility of redundant functions of OsPIN genes exists [49], mutation of most OsPIN genes substantially influences rice architecture [47,49,53,54,55,77]. The previous report demonstrated that the OsPIN9 carrier functions in auxin transport basipetally, overexpression of OsPIN9 substantially increases auxin content in rice roots [55], so we speculate that the auxin content in OE plant roots should be increased compared to that in WT plants. In line with this, the OE plant roots displayed a more resistant phenotype under NPA treatment (Figure 4), implying an increased auxin content in the OE roots. It was reported that overexpression of OsPIN9 increased the adventitious root number [55]. Unexpectedly, we observed a lower number of adventitious roots in these two OE lines, which is different from the previous report [55]. Considering that adventitious root number is tightly associated with auxin content [55], and auxin regulates plant growth and development usually in a concentration-dependent manner, relative high auxin content accelerates plant growth, while excess auxin content strongly inhibits plant growth. Therefore, we speculate that the dramatic expression of OsPIN9 probably leads to excess accumulation of auxin in OE roots, which suppresses adventitious root number (Figure 3). In agreement with this, the relative lower expression of OsPIN9 (A2 line) significantly increased adventitious root number when compared to WT plants (Figure S1).
Rice is sensitive to chilling stress [7,78,79,80], and severe chilling disasters hamper rice growth and strikingly impair rice productivity [10]. Previous reports have suggested that chilling stress is implicated in auxin transport in plants [29,30,61,62]. However, there is no direct genetic evidence regarding the role of auxin transport in the regulation of chilling stress. In this study, we provided direct evidence that OsPIN9, which functions in auxin transport basipetally and could be quickly suppressed by chilling stress (Figure 1), is involved in rice chilling tolerance. The chilling treatment assay showed that OE lines are more sensitive to low temperatures than WT plants (Figure 5); further experiments confirmed that OE lines possess more dead cells (Figure 6A), higher membrane permeability (Figure 6B), and increased MDA content (Figure 6C) compared to WT plants after chilling treatment. Increased MDA content usually acts as a marker of lipid peroxidation [81], especially under various abiotic stresses [82,83], including chilling stress. Apart from rice, MDA levels were also employed to evaluate chilling tolerance in other plants, such as bermudagrass (Cynodon dactylon) [84] and Pyrus betulaefolia [85]. Collectively, these results strongly demonstrate that OsPIN9 is involved in regulating rice chilling tolerance, which is probably mediated by influencing auxin transport. Over the last decade, significant progress has been made in the dissection of the underlying molecular mechanisms of plant chilling adaptation. At least the CBF/DREB-dependent cold-signaling pathway, the Ca2+ signaling pathway, the ROS-dominated adaptation mechanism, and the phytohormone regulation mechanism [1,9,86] have been demonstrated to regulate plant cold adaptation. Several lines of evidence have strongly suggested that overexpression of OsPIN9 notably impairs rice chilling tolerance (Figure 5 and Figure 6), while how OsPIN9 influences plant chilling tolerance is completely unknown. To this end, we first examined whether the impaired chilling tolerance of OE lines is associated with the CBF/DREB-dependent cold signaling pathway and the Ca2+ signaling pathway by employing qRT-PCR technology. The expression of OsDREB1A, OsDREB1B, and OsDREB1C was detected before and after chilling stress due to the sharp induction of these genes under chilling conditions [19,67]. Surprisingly, the OsDREB1 genes, OsTPP1, COLD1, and OsCNGC9 were all induced before treatment and kept at similar or even lower levels in OE lines compared to those in WT plants after chilling treatment (Figure 7). Considering that OsDREB1 genes are mainly induced by low temperatures [19], and higher expression of OsTPP1, COLD1, and OsCNGC9 also facilitates plant cold adaptation [7,14,68], we speculate that a stress response probably occurred in OE lines before chilling treatment. In contrast, all genes show a similar or lower expression level in OE lines compared to WT plants under chilling conditions, suggesting that the DREB regulon and Ca2+ signaling might be implicated in the impaired chilling tolerance of OE lines. Further investigations are needed to address this speculation.
Next, we assayed ROS levels to clarify the role of ROS homeostasis in WT and OE lines under chilling stress. Chilling stress triggers ROS accumulation [21,87]. Low-level H2O2 can act as a signal to trigger the stress response at the early stress stage, whereas at the later stress stage, high-level H2O2 can damage plant cells [10,87]. Surprisingly, we only observed the accumulation of H2O2 in OE leaves at both early and late chilling stages, while O 2 was not accumulated during the chilling stages (Figure 8), indicating that ROS homeostasis is disturbed in OE plant cells and that H2O2 rather than O 2 causes cell damage in OE lines. It has been demonstrated that ROS homeostasis plays a vital role in plant abiotic stress adaptations [88,89], and ROS content must be carefully controlled by many ROS scavenging and detoxification systems during stress conditions [10]. Antioxidant enzyme activity measurement showed that SOD and CAT activities were significantly decreased and increased in OE lines compared to those in WT plants at the early and late chilling stages, respectively, while POD activity was always strikingly higher than that in WT plants (Figure 9B,C), even before chilling treatment (Figure 9A), indicating that the prompt trigger of antioxidant enzymes, mainly SOD and CAT in OE lines, plays a vital role in quenching accumulated ROS at the early chilling stage. Additionally, although antioxidant enzymes showed significantly higher activities in OE lines than in WT plants at the late chilling stage (Figure 9C), which could not detoxify excess H2O2 quickly (Figure 8C), indicating that the delayed induction of the antioxidant enzymes is not enough to scavenge ROS at the late chilling stage, and the constantly high levels of H2O2 then damage cells.
To further evaluate the source of H2O2 in OE lines under chilling conditions, we assayed the expression of OsRboh genes before and after chilling stress. Since only a slight increase of OsRboh1, OsRboh2, and OsRboh9 was detected in OE lines before chilling stress, it is reasonable that less ROS accumulation was observed under normal conditions. In contrast, more OsRboh genes were induced after chilling treatment, indicating that OsRboh is at least in part involved in ROS production after chilling stress. We also noticed that these induced OsRboh genes were still kept at low expression levels (up to about twofold) even after chilling treatment (Figure 10). Although evidence has shown that Rboh plays a vital role in ROS production under various abiotic stress conditions [70,71], we cannot rule out the possibility that other ROS-production sources probably exist that contribute to the ROS burst after chilling stress in OE lines.

4. Materials and Methods

4.1. Plant Materials, Growth Conditions, and Chilling Treatment

Rice japonica variety Nipponbare was employed for the physiological experiments and rice transformation. Hydroponic experiments were performed according to our previous report [90]. Briefly, rice seeds were sterilized first and then cultured in darkness for 3–4 days at 30 °C. The germinated seeds were transferred to Kimura B complete nutrient solution in plant growth chambers with a 12 h of light (30 °C)/12 h of darkness (25 °C) photoperiod and 60–70% relative humidity.
To assay the responses of OsPIN genes to chilling treatment, 14 day old seedlings were transferred to low temperatures (4 °C), and root samples were collected at the indicated time points. The samples were then frozen quickly using liquid nitrogen and preserved at −80 °C for gene expression analysis.
To evaluate rice chilling tolerance, 14 day old WT and OE seedlings were transferred to 4 °C for 36 h and 57 h, followed by a 3 d recovery, and then the survival rate and physiological indicators were analyzed.

4.2. Vector Construction and Generation of the Transgenic Plants

The full-length OsPIN9 gene was amplified by PrimeSTAR HS DNA Polymerase (TaKaRa Biotechnology Co., Ltd., Dalian, China) from rice cDNA using the specific primers listed in Table S1. A plant expression vector, pCAMBIA1301-pUbi, which was kindly provided by Dr. Yao-Guang Liu (College of Life Sciences, South China Agricultural University, Guangzhou, China), was used for overexpressing OsPIN9. To insert into the expression vector pCAMBIA1301-pUbi, the restriction sites BamH I and Kpn I were added at the 5′ end of forward and reverse primers, respectively. The recombinant construct was named pUbi:OsPIN9 and confirmed by restriction enzyme digestion and sequencing. The constructed plasmid was then transformed into Agrobacterium tumefaciens (EHA105) and employed for rice transformation according to the previous report [91]. Homozygous T3-generation transgenic plants were used for further studies.

4.3. Quantitative RT-PCR

qRT-PCR was performed according to a previous report [39]. In short, total RNA was extracted from the collected samples using RNAiso Plus (TAKARA Bio Inc., Dalian, China), and reverse transcription was conducted using HiScript III RT SuperMix for qPCR (Nanjing Vazyme Biotech Company, Ltd., Nanjing, China). The online website INTEGRATED DNA TECHNOLOGIES (https://sg.idtdna.com, accessed on 1 May 2019) was used to design the gene-specific primers. qRT-PCR was conducted using AceQ Universal SYBR qPCR Master Mix (Nanjing Vazyme Biotech Company, Ltd.) and the Lightcycle® 96 system. At least three biological replicates and three technical repetitions were performed to assay the gene expression. The OsACTIN1 gene (Os03g0718100) was employed as an internal control. All primers used in this study are listed in Table S1, and gene names and ID numbers used for qRT-PCR in this study are listed in Table S2.

4.4. Exogenous NPA Treatment

NPA is usually employed as a classical inhibitor of polar auxin transport to elucidate the underlying mechanisms of plant growth and development associated with polar auxin transport [65]. For analyzing the responses of WT and OE lines to NPA treatment, germinated seeds were transferred into Kimura B complete nutrient solution containing 0.5 μM NPA and cultured for 7 d, and then the shoot height, root length, and adventitious root number were assessed. WT and OE lines cultured under normal conditions were used as controls in this experiment.

4.5. Physiological Analysis

Trypan blue staining was conducted as described previously [92] with minor modifications. Rice leaves were sampled before and after chilling treatment and stained with a lactophenol-trypan blue solution (10 mL lactic acid, 10 mL glycerol, 10 g phenol, and 10 mg trypan blue, mixed in 10 mL distilled water). The leaves were boiled in a water bath for 10 min in trypan blue solution and then kept at room temperature for 1 h. Decolorization was performed using chloral hydrate solution (25 g chloral hydrate dissolved in 10 mL distilled water). Electrolyte conductivity and MDA content were detected according to the previous report [93]. 3′3-diaminobenzidine (DAB) and nitro blue tetrazolium (NBT) staining were performed as previously reported [21]. Briefly, rice leaves were first cut into sections (about 2 cm in length) and then soaked in DAB and NBT solutions, respectively, overnight at 37 °C. Alcohol (95%) was used for decolorization. CAT, POD, and SOD activities were assayed according to the previous methods [94] with minor modifications. In short, 0.1 g of rice leaves were broken with liquid nitrogen and then homogenized in 1 mL of extraction buffer (50 mM phosphate, pH 7.8). After centrifugation, the supernatant was used for enzyme activity assays. CAT activity was measured in a reaction solution consisting of 50 mM phosphate buffer (pH 7.0), 0.2% H2O2, and enzyme extract. POD activity was measured in a reaction mixture (0.2% H2O2, 0.2% guaiacol, and enzyme extract) at 470 nm. SOD activity was assayed in a reaction mixture containing 50 mM phosphate, pH 7.8, 130 mM L-methionine, 750 μM NBT, 100 μM EDTA, 20 μM riboflavin, and enzyme extract at 560 nm. The Coomassie Brilliant Blue G-250 staining method was employed to measure protein content [95].

4.6. Data Analysis

Each experiment was biologically replicated at least three times. The one-way analysis of variance (ANOVA) method was used to statistically analyze experimental data by GraphPad PRISM 8 version 8.0.2 (GraphPad Software Inc., San Diego, CA, USA) at the significance levels of p < 0.05 (*), p < 0.01 (**), and p < 0.001 (***), and all data are given as means ± SD.

5. Conclusions

In conclusion, in this report, we systematically monitored the responses of OsPIN genes to chilling treatment and generated transgenic rice plants with high expression levels of OsPIN9. The transgenic plants showed impaired chilling tolerance compared to WT plants, which is probably mainly caused by the sharp accumulation of H2O2 and delayed induction of SOD and CAT. OsRboh genes, at least in part, contribute to the production of ROS in OE lines under chilling stress conditions. The DREB regulon and Ca2+ signaling pathway are implicated in the chilling tolerance of OE lines, while the detailed functional mechanisms need further investigation. Several issues need further discussion, for example, how the relationship between auxin homeostasis and ROS homeostasis is derived and where the accumulated H2O2 is derived from? What is the role of O 2 and POD in OE lines under chilling stress? Further investigation focused on these detailed issues may lead to insight into the underlying molecular mechanisms of rice chilling tolerance and may provide potential targets for breeding chilling-resistant crops.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/plants12152809/s1, Figure S1: Adventitious root number analysis in the transgenic A2 line; Table S1: Primers used in this study; Table S2: Gene names and ID numbers used for qRT-PCR in this study.

Author Contributions

Conceptualization and research design, H.X.; experimental, Q.O., Y.Z., X.Y. and C.Y.; analyzing the data, D.H., H.L. and H.X.; manuscript—writing, H.X.; writing—review (completion), D.H., H.L. and H.X. All authors have read and agreed to the published version of the manuscript.

Funding

This work was funded by the National Natural Science Foundation of China (grant number 3110019) and the Natural Science Foundation of Henan Province (grant number 182300410012).

Data Availability Statement

Not applicable.

Acknowledgments

We sincerely thank Chunzhao Zhao (Shanghai Center for Plant Stress Biology, CAS Center for Excellence in Molecular Plant Sciences, Chinese Academy of Sciences) for constructive discussion. The authors are grateful to all lab members for their useful suggestions and encouragement.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Ding, Y.; Shi, Y.; Yang, S. Molecular regulation of plant responses to environmental temperatures. Mol. Plant 2020, 13, 544–564. [Google Scholar] [CrossRef]
  2. Shi, Y.; Ding, Y.; Yang, S. Molecular regulation of CBF signaling in cold acclimation. Trends Plant Sci. 2018, 23, 623–637. [Google Scholar] [CrossRef]
  3. Wang, W.; Vinocur, B.; Altman, A. Plant responses to drought, salinity and extreme temperatures: Towards genetic engineering for stress tolerance. Planta 2003, 218, 1–14. [Google Scholar] [CrossRef] [PubMed]
  4. Wang, D.; Liu, J.L.; Li, C.G.; Kang, H.X.; Wang, Y.; Tan, X.Q.; Liu, M.H.; Deng, Y.F.; Wang, Z.L.; Liu, Y.; et al. Genome-wide association mapping of cold tolerance genes at the seedling stage in rice. Rice 2016, 9, 61. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  5. Zhang, Q.; Chen, Q.; Wang, S.; Hong, Y.; Wang, Z. Rice and cold stress: Methods for its evaluation and summary of cold tolerance-related quantitative trait loci. Rice 2014, 7, 24. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  6. Andaya, V.C.; Mackill, D.J. Mapping of QTLs associated with cold tolerance during the vegetative stage in rice. J. Exp. Bot. 2003, 54, 2579–2585. [Google Scholar] [CrossRef] [PubMed]
  7. Ma, Y.; Dai, X.; Xu, Y.; Luo, W.; Zheng, X.; Zeng, D.; Pan, Y.; Lin, X.; Liu, H.; Zhang, D.; et al. COLD1 confers chilling tolerance in rice. Cell 2015, 160, 1209–1221. [Google Scholar] [CrossRef] [Green Version]
  8. Ding, Y.; Yang, S. Surviving and thriving: How plants perceive and respond to temperature stress. Dev. Cell 2022, 57, 947–958. [Google Scholar] [CrossRef]
  9. Guo, X.; Liu, D.; Chong, K. Cold signaling in plants: Insights into mechanisms and regulation. J. Integr. Plant Biol. 2018, 60, 745–756. [Google Scholar] [CrossRef] [Green Version]
  10. Zhang, J.; Li, X.M.; Lin, H.X.; Chong, K. Crop improvement through temperature resilience. Annu. Rev. Plant Biol. 2019, 70, 753–780. [Google Scholar] [CrossRef]
  11. Knight, H.; Trewavas, A.J.; Knight, M.R. Cold calcium signaling in Arabidopsis involves two cellular pools and a change in calcium signature after acclimation. Plant Cell 1996, 8, 489–503. [Google Scholar] [CrossRef] [Green Version]
  12. Gong, M.A.V.D.; Knight, M.R.; Trewavas, A.J.; Ah, V.D.L. Heat-shock-induced changes in intracellular Ca2+ level in tobacco seedlings in relation to thermotolerance. Plant Physiol. 1998, 116, 429–437. [Google Scholar] [CrossRef]
  13. Zhu, J.K. Abiotic stress signaling and responses in plants. Cell 2016, 167, 313–324. [Google Scholar] [CrossRef] [Green Version]
  14. Wang, J.; Ren, Y.; Liu, X.; Luo, S.; Zhang, X.; Liu, X.; Lin, Q.; Zhu, S.; Wan, H.; Yang, Y.; et al. Transcriptional activation and phosphorylation of OsCNGC9 confer enhanced chilling tolerance in rice. Mol. Plant 2021, 14, 315–329. [Google Scholar] [CrossRef]
  15. Sun, Q.; Huang, R.; Zhu, H.; Sun, Y.; Guo, Z. A novel Medicago truncatula calmodulin-like protein (MtCML42) regulates cold tolerance and flowering time. Plant J. 2021, 108, 1069–1082. [Google Scholar] [CrossRef]
  16. Ding, Y.; Shi, Y.; Yang, S. Advances and challenges in uncovering cold tolerance regulatory mechanisms in plants. New Phytol. 2019, 222, 1690–1704. [Google Scholar] [CrossRef] [Green Version]
  17. Stockinger, E.J.; Gilmour, S.J.; Thomashow, M.F. Arabidopsis thaliana CBF1 encodes an AP2 domain-containing transcriptional activator that binds to the C-repeat/DRE, a cis-acting DNA regulatory element that stimulates transcription in response to low temperature and water deficit. Proc. Natl. Acad. Sci. USA 1997, 94, 1035–1040. [Google Scholar] [CrossRef]
  18. Liu, Q.; Kasuga, M.; Sakuma, Y.; Abe, H.; Miura, S.; Yamaguchi-Shinozaki, K.; Shinozaki, K. Two transcription factors, DREB1 and DREB2, with an EREBP/AP2 DNA binding domain separate two cellular signal transduction pathways in drought- and low-temperature-responsive gene expression, respectively, in Arabidopsis. Plant Cell 1998, 10, 1391–1406. [Google Scholar] [CrossRef] [Green Version]
  19. Mao, D.; Chen, C. Colinearity and similar expression pattern of rice DREB1s reveal their functional conservation in the cold-responsive pathway. PLoS ONE 2012, 7, e47275. [Google Scholar] [CrossRef] [Green Version]
  20. Zhao, C.; Lang, Z.; Zhu, J.K. Cold responsive gene transcription becomes more complex. Trends Plant Sci. 2015, 20, 466–468. [Google Scholar] [CrossRef] [Green Version]
  21. Zhang, J.; Luo, W.; Zhao, Y.; Xu, Y.; Song, S.; Chong, K. Comparative metabolomic analysis reveals a reactive oxygen species-dominated dynamic model underlying chilling environment adaptation and tolerance in rice. New Phytol. 2016, 211, 1295–1310. [Google Scholar] [CrossRef] [Green Version]
  22. Baxter, A.; Mittler, R.; Suzuki, N. ROS as key players in plant stress signalling. J. Exp. Bot. 2014, 65, 1229–1240. [Google Scholar] [CrossRef]
  23. Mittler, R.; Zandalinas, S.I.; Fichman, Y.; Van Breusegem, F. Reactive oxygen species signalling in plant stress responses. Nat. Rev. Mol. Cell Biol. 2022, 23, 663–679. [Google Scholar] [CrossRef]
  24. Du, H.; Wu, N.; Chang, Y.; Li, X.; Xiao, J.; Xiong, L. Carotenoid deficiency impairs ABA and IAA biosynthesis and differentially affects drought and cold tolerance in rice. Plant Mol. Biol. 2013, 83, 475–488. [Google Scholar] [CrossRef]
  25. Lee, B.H.; Lee, H.; Xiong, L.; Zhu, J.K. A mitochondrial complex I defect impairs cold-regulated nuclear gene expression. Plant Cell 2002, 14, 1235–1251. [Google Scholar] [CrossRef] [Green Version]
  26. Dong, C.H.; Zolman, B.K.; Bartel, B.; Lee, B.H.; Stevenson, B.; Agarwal, M.; Zhu, J.K. Disruption of Arabidopsis CHY1 reveals an important role of metabolic status in plant cold stress signaling. Mol. Plant 2009, 2, 59–72. [Google Scholar] [CrossRef] [Green Version]
  27. Kimura, M.; Kagawa, T. Phototropin and light-signaling in phototropism. Curr. Opin. Plant Biol. 2006, 9, 503–508. [Google Scholar] [CrossRef]
  28. Palme, K.; Dovzhenko, A.; Ditengou, F.A. Auxin transport and gravitational research: Perspectives. Protoplasma 2006, 229, 175–181. [Google Scholar] [CrossRef]
  29. Shibasaki, K.; Uemura, M.; Tsurumi, S.; Rahman, A. Auxin response in Arabidopsis under cold stress: Underlying molecular mechanisms. Plant Cell 2009, 21, 3823–3838. [Google Scholar] [CrossRef] [Green Version]
  30. Du, H.; Liu, H.; Xiong, L. Endogenous auxin and jasmonic acid levels are differentially modulated by abiotic stresses in rice. Front. Plant Sci. 2013, 4, 397. [Google Scholar] [CrossRef] [Green Version]
  31. Woodward, A.W.; Bartel, B. Auxin: Regulation, action, and interaction. Ann. Bot. 2005, 95, 707–735. [Google Scholar] [CrossRef] [Green Version]
  32. Zhao, Y. Auxin biosynthesis and its role in plant development. Annu. Rev. Plant Biol. 2010, 61, 49–64. [Google Scholar] [CrossRef] [Green Version]
  33. Zhao, Y. The role of local biosynthesis of auxin and cytokinin in plant development. Curr. Opin. Plant Biol. 2008, 11, 16–22. [Google Scholar] [CrossRef]
  34. Petrasek, J.; Mravec, J.; Bouchard, R.; Blakeslee, J.J.; Abas, M.; Seifertova, D.; Wisniewska, J.; Tadele, Z.; Kubes, M.; Covanova, M.; et al. PIN proteins perform a rate-limiting function in cellular auxin efflux. Science 2006, 312, 914–918. [Google Scholar] [CrossRef] [Green Version]
  35. Zazimalova, E.; Murphy, A.S.; Yang, H.; Hoyerova, K.; Hosek, P. Auxin transporters-why so many? Cold Spring Harb. Perspect. Biol. 2010, 2, a001552. [Google Scholar] [CrossRef] [Green Version]
  36. Benkova, E.; Michniewicz, M.; Sauer, M.; Teichmann, T.; Seifertova, D.; Jurgens, G.; Friml, J. Local, efflux-dependent auxin gradients as a common module for plant organ formation. Cell 2003, 115, 591–602. [Google Scholar] [CrossRef] [Green Version]
  37. Sauer, M.; Kleine-Vehn, J. PIN-FORMED and PIN-LIKES auxin transport facilitators. Development 2019, 146, dev168088. [Google Scholar] [CrossRef] [Green Version]
  38. Krecek, P.; Skupa, P.; Libus, J.; Naramoto, S.; Tejos, R.; Friml, J.; Zazimalova, E. The PIN-FORMED (PIN) protein family of auxin transporters. Genome Biol. 2009, 10, 249. [Google Scholar] [CrossRef] [Green Version]
  39. Xu, H.W.; Zhang, Y.W.; Yang, X.Y.; Wang, H.H.; Hou, D.Y. Tissue specificity and responses to abiotic stresses and hormones of PIN genes in rice. Biologia 2022, 77, 1459–1470. [Google Scholar] [CrossRef]
  40. Abdollahi Sisi, N.; Ruzicka, K. ER-localized PIN carriers: Regulators of intracellular auxin homeostasis. Plants 2020, 9, 1527. [Google Scholar] [CrossRef]
  41. Zwiewka, M.; Bilanovicova, V.; Seifu, Y.W.; Nodzynski, T. The nuts and bolts of PIN auxin efflux carriers. Front. Plant Sci. 2019, 10, 985. [Google Scholar] [CrossRef] [Green Version]
  42. Lin, Y.Q.; Qi, Y.H. Advances in auxin efflux carrier PIN proteins. Chin. Bull. Bot. 2021, 56, 151–165. [Google Scholar]
  43. Petrasek, J.; Friml, J. Auxin transport routes in plant development. Development 2009, 136, 2675–2688. [Google Scholar] [CrossRef] [Green Version]
  44. Robert, H.S.; Friml, J. Auxin and other signals on the move in plants. Nat. Chem. Biol. 2009, 5, 325–332. [Google Scholar] [CrossRef]
  45. Wang, J.R.; Hu, H.; Wang, G.H.; Li, J.; Chen, J.Y.; Wu, P. Expression of PIN genes in rice (Oryza sativa L.): Tissue specificity and regulation by hormones. Mol. Plant 2009, 2, 823–831. [Google Scholar] [CrossRef]
  46. Miyashita, Y.; Takasugi, T.; Ito, Y. Identification and expression analysis of PIN genes in rice. Plant Sci. 2010, 178, 424–428. [Google Scholar] [CrossRef]
  47. Xu, M.; Zhu, L.; Shou, H.; Wu, P. A PIN1 family gene, OsPIN1, involved in auxin-dependent adventitious root emergence and tillering in rice. Plant Cell Physiol. 2005, 46, 1674–1681. [Google Scholar] [CrossRef] [Green Version]
  48. Xu, H.W.; Mo, Y.W.; Wang, W.; Wang, H.; Wang, Z. OsPIN1a gene participates in regulating negative phototropism of rice root. Rice Sci. 2014, 21, 83–89. [Google Scholar] [CrossRef]
  49. Li, Y.; Zhu, J.; Wu, L.; Shao, Y.; Wu, Y.; Mao, C. Functional divergence of PIN1 paralogous genes in rice. Plant Cell Physiol. 2019, 60, 2720–2732. [Google Scholar] [CrossRef]
  50. Inahashi, H.; Shelley, I.J.; Yamauchi, T.; Nishiuchi, S.; Takahashi-Nosaka, M.; Matsunami, M.; Ogawa, A.; Noda, Y.; Inukai, Y. OsPIN2, which encodes a member of the auxin efflux carrier proteins, is involved in root elongation growth and lateral root formation patterns via the regulation of auxin distribution in rice. Physiol. Plant 2018, 164, 216–225. [Google Scholar] [CrossRef] [Green Version]
  51. Wang, L.; Guo, M.; Li, Y.; Ruan, W.; Mo, X.; Wu, Z.; Sturrock, C.J.; Yu, H.; Lu, C.; Peng, J.; et al. LARGE ROOT ANGLE1, encoding OsPIN2, is involved in root system architecture in rice. J. Exp. Bot. 2018, 69, 385–397. [Google Scholar] [CrossRef] [Green Version]
  52. Li, W.Q.; Zhang, M.J.; Qiao, L.; Chen, Y.B.; Zhang, D.P.; Jing, X.Q.; Gan, P.F.; Huang, Y.B.; Gao, J.R.; Liu, W.T.; et al. Characterization of wavy root 1, an agravitropism allele, reveals the functions of OsPIN2 in fine regulation of auxin transport and distribution and in ABA biosynthesis and response in rice (Oryza sativa L.). Crop. J. 2022, 10, 980–992. [Google Scholar] [CrossRef]
  53. Lu, G.; Coneva, V.; Casaretto, J.A.; Ying, S.; Mahmood, K.; Liu, F.; Nambara, E.; Bi, Y.M.; Rothstein, S.J. OsPIN5b modulates rice (Oryza sativa) plant architecture and yield by changing auxin homeostasis, transport and distribution. Plant J. 2015, 83, 913–925. [Google Scholar] [CrossRef]
  54. Zhang, Q.; Li, J.; Zhang, W.; Yan, S.; Wang, R.; Zhao, J.; Li, Y.; Qi, Z.; Sun, Z.; Zhu, Z. The putative auxin efflux carrier OsPIN3t is involved in the drought stress response and drought tolerance. Plant J. 2012, 72, 805–816. [Google Scholar] [CrossRef]
  55. Hou, M.; Luo, F.; Wu, D.; Zhang, X.; Lou, M.; Shen, D.; Yan, M.; Mao, C.; Fan, X.; Xu, G.; et al. OsPIN9, an auxin efflux carrier, is required for the regulation of rice tiller bud outgrowth by ammonium. New Phytol. 2021, 229, 935–949. [Google Scholar] [CrossRef]
  56. Shen, C.; Bai, Y.; Wang, S.; Zhang, S.; Wu, Y.; Chen, M.; Jiang, D.; Qi, Y. Expression profile of PIN, AUX/LAX and PGP auxin transporter gene families in Sorghum bicolor under phytohormone and abiotic stress. FEBS J. 2010, 277, 2954–2969. [Google Scholar] [CrossRef]
  57. Yue, R.; Tie, S.; Sun, T.; Zhang, L.; Yang, Y.; Qi, J.; Yan, S.; Han, X.; Wang, H.; Shen, C. Genome-wide identification and expression profiling analysis of ZmPIN, ZmPILS, ZmLAX and ZmABCB auxin transporter gene families in maize (Zea mays L.) under various abiotic stresses. PLoS ONE 2015, 10, e0118751. [Google Scholar] [CrossRef]
  58. Forestan, C.; Farinati, S.; Varotto, S. The maize PIN gene family of auxin transporters. Front. Plant Sci. 2012, 3, 16. [Google Scholar] [CrossRef] [Green Version]
  59. Morris, D.A. The effect of temperature on the velocity of exogenous auxin transport in intact chilling-sensitive and chilling-resistant plants. Planta 1979, 146, 603–605. [Google Scholar] [CrossRef]
  60. Jain, M.; Khurana, J.P. Transcript profiling reveals diverse roles of auxin-responsive genes during reproductive development and abiotic stress in rice. FEBS J. 2009, 276, 3148–3162. [Google Scholar] [CrossRef]
  61. Nadella, V.; Shipp, M.J.; Muday, G.K.; Wyatt, S.E. Evidence for altered polar and lateral auxin transport in the gravity persistent signal (gps) mutants of Arabidopsis. Plant Cell Environ. 2006, 29, 682–690. [Google Scholar] [CrossRef] [Green Version]
  62. Ashraf, M.A.; Rahman, A. Cold stress response in Arabidopsis thaliana is mediated by GNOM ARF-GEF. Plant J. 2019, 97, 500–516. [Google Scholar] [CrossRef] [Green Version]
  63. Manna, M.; Rengasamy, B.; Ambasht, N.K.; Sinha, A.K. Characterization and expression profiling of PIN auxin efflux transporters reveal their role in developmental and abiotic stress conditions in rice. Front. Plant Sci. 2022, 13, 1059559. [Google Scholar] [CrossRef]
  64. Xu, H.; Yang, X.; Zhang, Y.; Wang, H.; Wu, S.; Zhang, Z.; Ahammed, G.J.; Zhao, C.; Liu, H. CRISPR/Cas9-mediated mutation in auxin efflux carrier OsPIN9 confers chilling tolerance by modulating reactive oxygen species homeostasis in rice. Front. Plant Sci. 2022, 13, 967031. [Google Scholar] [CrossRef]
  65. Abas, L.; Kolb, M.; Stadlmann, J.; Janacek, D.P.; Lukic, K.; Schwechheimer, C.; Sazanov, L.A.; Mach, L.; Friml, J.; Hammes, U.Z. Naphthylphthalamic acid associates with and inhibits PIN auxin transporters. Proc. Natl. Acad. Sci. USA 2021, 118, e2020857118. [Google Scholar] [CrossRef]
  66. Rahman, A. Auxin: A regulator of cold stress response. Physiol. Plant 2013, 147, 28–35. [Google Scholar] [CrossRef]
  67. Dubouzet, J.G.; Sakuma, Y.; Ito, Y.; Kasuga, M.; Dubouzet, E.G.; Miura, S.; Seki, M.; Shinozaki, K.; Yamaguchi-Shinozaki, K. OsDREB genes in rice, Oryza sativa L., encode transcription activators that function in drought-, high-salt- and cold-responsive gene expression. Plant J. 2003, 33, 751–763. [Google Scholar] [CrossRef]
  68. Zhang, Z.; Li, J.; Li, F.; Liu, H.; Yang, W.; Chong, K.; Xu, Y. OsMAPK3 phosphorylates OsbHLH002/OsICE1 and inhibits its ubiquitination to activate OsTPP1 and enhances rice chilling tolerance. Dev. Cell 2017, 43, 731–743.e5. [Google Scholar] [CrossRef] [Green Version]
  69. Dong, Q.; Wallrad, L.; Almutairi, B.O.; Kudla, J. Ca2+ signaling in plant responses to abiotic stresses. J. Integr. Plant Biol. 2022, 64, 287–300. [Google Scholar] [CrossRef]
  70. Xu, Y.; Wang, R.; Wang, Y.; Zhang, L.; Yao, S. A point mutation in LTT1 enhances cold tolerance at the booting stage in rice. Plant Cell Environ. 2020, 43, 992–1007. [Google Scholar] [CrossRef] [Green Version]
  71. Hu, C.H.; Wang, P.Q.; Zhang, P.P.; Nie, X.M.; Li, B.B.; Tai, L.; Liu, W.T.; Li, W.Q.; Chen, K.M. NADPH oxidases: The vital performers and center hubs during plant growth and signaling. Cells 2020, 9, 437. [Google Scholar] [CrossRef] [Green Version]
  72. Marino, D.; Dunand, C.; Puppo, A.; Pauly, N. A burst of plant NADPH oxidases. Trends Plant Sci. 2012, 17, 9–15. [Google Scholar] [CrossRef]
  73. Olatunji, D.; Geelen, D.; Verstraeten, I. Control of endogenous auxin levels in plant root development. Int. J. Mol. Sci. 2017, 18, 2587. [Google Scholar] [CrossRef] [Green Version]
  74. Michniewicz, M.; Brewer, P.B.; Friml, J.I. Polar auxin transport and asymmetric auxin distribution. Arab. Book 2007, 5, e0108. [Google Scholar] [CrossRef] [Green Version]
  75. Friml, J. Auxin transport-shaping the plant. Curr. Opin. Plant Biol. 2003, 6, 7–12. [Google Scholar] [CrossRef]
  76. Okada, K.; Ueda, J.; Komaki, M.K.; Bell, C.J.; Shimura, Y. Requirement of the auxin polar transport system in early stages of Arabidopsis floral bud formation. Plant Cell 1991, 3, 677–684. [Google Scholar] [CrossRef] [Green Version]
  77. Chen, Y.; Fan, X.; Song, W.; Zhang, Y.; Xu, G. Over-expression of OsPIN2 leads to increased tiller numbers, angle and shorter plant height through suppression of OsLAZY1. Plant Biotechnol. J. 2012, 10, 139–149. [Google Scholar] [CrossRef]
  78. Kovach, M.J.; Sweeney, M.T.; McCouch, S.R. New insights into the history of rice domestication. Trends Genet. 2007, 23, 578–587. [Google Scholar] [CrossRef]
  79. Saito, K.; Hayano-Saito, Y.; Kuroki, M.; Sato, Y. Map-based cloning of the rice cold tolerance gene Ctb1. Plant Sci. 2010, 179, 97–102. [Google Scholar] [CrossRef]
  80. Sang, T.; Ge, S. Genetics and phylogenetics of rice domestication. Curr. Opin. Genet. Dev. 2007, 17, 533–538. [Google Scholar] [CrossRef]
  81. Demidchik, V. Mechanisms of oxidative stress in plants: From classical chemistry to cell biology. Environ. Exp. Bot. 2015, 109, 212–228. [Google Scholar] [CrossRef]
  82. Hasanuzzaman, M.; Bhuyan, M.; Parvin, K.; Bhuiyan, T.F.; Anee, T.I.; Nahar, K.; Hossen, M.S.; Zulfiqar, F.; Alam, M.M.; Fujita, M. Regulation of ROS metabolism in plants under environmental stress: A review of recent experimental evidence. Int. J. Mol. Sci. 2020, 21, 8695. [Google Scholar] [CrossRef]
  83. Ahmad, P.; Alyemeni, M.N.; Al-Huqail, A.A.; Alqahtani, M.A.; Wijaya, L.; Ashraf, M.; Kaya, C.; Bajguz, A. Zinc oxide nanoparticles application alleviates arsenic (As) toxicity in soybean plants by restricting the uptake of as and modulating key biochemical attributes, antioxidant enzymes, ascorbate-glutathione cycle and glyoxalase system. Plants 2020, 9, 825. [Google Scholar] [CrossRef]
  84. Huang, X.; Cao, L.; Fan, J.; Ma, G.; Chen, L. CdWRKY2-mediated sucrose biosynthesis and CBF-signalling pathways coordinately contribute to cold tolerance in bermudagrass. Plant Biotechnol. J. 2021, 20, 660–675. [Google Scholar] [CrossRef]
  85. Xing, C.; Liu, Y.; Zhao, L.; Zhang, S.; Huang, X. A novel MYB transcription factor regulates ascorbic acid synthesis and affects cold tolerance. Plant Cell Environ. 2019, 42, 832–845. [Google Scholar] [CrossRef]
  86. Liu, J.; Shi, Y.; Yang, S. Insights into the regulation of C-repeat binding factors in plant cold signaling. J. Integr. Plant Biol. 2018, 60, 780–795. [Google Scholar] [CrossRef] [Green Version]
  87. Prasad, T.K.; Anderson, M.D.; Stewart, C.R. Evidence for chilling-induced oxidative stress in maize seedling and a regulatory role for hydrogen peroxide. Plant Cell 1994, 105, 619–627. [Google Scholar]
  88. Considine, M.J.; Foyer, C.H. Stress effects on the reactive oxygen species-dependent regulation of plant growth and development. J. Exp. Bot. 2021, 72, 5795–5806. [Google Scholar] [CrossRef]
  89. Xia, X.J.; Zhou, Y.H.; Shi, K.; Zhou, J.; Foyer, C.H.; Yu, J.Q. Interplay between reactive oxygen species and hormones in the control of plant development and stress tolerance. J. Exp. Bot. 2015, 66, 2839–2856. [Google Scholar] [CrossRef] [Green Version]
  90. Xu, H.W.; Ji, X.M.; He, Z.H.; Shi, W.P.; Zhu, G.H.; Niu, J.K.; Li, B.S.; Peng, X.X. Oxalate accumulation and regulation is independent of glycolate oxidase in rice leaves. J. Exp. Bot. 2006, 57, 1899–1908. [Google Scholar] [CrossRef] [Green Version]
  91. Hiei, Y.; Ohta, S.; Komari, T.; Kumashiro, T. Efficient transformation of rice (Oryza sativa L.) mediated by Agrobacterium and sequence analysis of the boundaries of the T-DNA. Plant J. 1994, 6, 271–282. [Google Scholar] [CrossRef] [Green Version]
  92. Choi, H.W.; Kim, Y.J.; Lee, S.C.; Hong, J.K.; Hwang, B.K. Hydrogen peroxide generation by the pepper extracellular peroxidase CaPO2 activates local and systemic cell death and defense response to bacterial pathogens. Plant Physiol. 2007, 145, 890–904. [Google Scholar] [CrossRef] [Green Version]
  93. Hu, Z.; Huang, X.; Amombo, E.; Liu, A.; Fan, J.; Bi, A.; Ji, K.; Xin, H.; Chen, L.; Fu, J. The ethylene responsive factor CdERF1 from bermudagrass (Cynodon dactylon) positively regulates cold tolerance. Plant Sci. 2020, 294, 110432. [Google Scholar] [CrossRef]
  94. Wu, F.B.; Zhang, G.P.; Dominy, P. Four barley genotypes respond differently to cadmium: Lipid peroxidation and activities of antioxidant capacity. Environ. Exp. Bot. 2003, 50, 67–78. [Google Scholar] [CrossRef]
  95. Bradford, M.M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal. Biochem. 1976, 72, 248–254. [Google Scholar] [CrossRef]
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Figure 1. Expression profiles of OsPIN genes under chilling treatment. Values are means ± standard deviation (SD) (n = 3).
Figure 1. Expression profiles of OsPIN genes under chilling treatment. Values are means ± standard deviation (SD) (n = 3).
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Figure 2. Generation of OsPIN9-overexpressing transgenic lines. (A) Schematic diagram of pUbi:OsPIN9. (B) Expression of OsPIN9 in different transgenic lines. The expression level of OsPIN9 in WT was set to one. The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. ***: p < 0.001. (C) Expression analysis of OsPIN9 in diverse tissues of OsPIN9 transgenic lines. Values are means ± standard deviation (SD) (n = 3).
Figure 2. Generation of OsPIN9-overexpressing transgenic lines. (A) Schematic diagram of pUbi:OsPIN9. (B) Expression of OsPIN9 in different transgenic lines. The expression level of OsPIN9 in WT was set to one. The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. ***: p < 0.001. (C) Expression analysis of OsPIN9 in diverse tissues of OsPIN9 transgenic lines. Values are means ± standard deviation (SD) (n = 3).
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Figure 3. Phenotypes of wild-type (WT) and OsPIN9-overexpressing lines (OE) in 7 day old seedlings (A) and 14 day old seedlings (B). Bar = 4 cm. Values are means ± standard deviation (SD) (n = 24). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; ***: p < 0.001.
Figure 3. Phenotypes of wild-type (WT) and OsPIN9-overexpressing lines (OE) in 7 day old seedlings (A) and 14 day old seedlings (B). Bar = 4 cm. Values are means ± standard deviation (SD) (n = 24). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; ***: p < 0.001.
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Figure 4. Sensitivity analysis of wild-type (WT) and OsPIN9-overexpressing (OE) plants under NPA treatment. Bar = 2 cm. Values are means ± standard deviation (SD) (n = 24). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; **: p < 0.01; ***: p < 0.001.
Figure 4. Sensitivity analysis of wild-type (WT) and OsPIN9-overexpressing (OE) plants under NPA treatment. Bar = 2 cm. Values are means ± standard deviation (SD) (n = 24). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; **: p < 0.01; ***: p < 0.001.
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Figure 5. Chilling tolerance analysis of WT and OsPIN9-overexpressing (OE) rice. Wild-type (WT) and OE plants were treated with 4 °C for 36 h (A) and 57 h (B), followed by another 3 days of recovery under normal conditions, and then the survival rate was analyzed statistically. Bar = 5 cm. Values are means ± standard deviation (SD) (n = 24). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. ***: p < 0.001.
Figure 5. Chilling tolerance analysis of WT and OsPIN9-overexpressing (OE) rice. Wild-type (WT) and OE plants were treated with 4 °C for 36 h (A) and 57 h (B), followed by another 3 days of recovery under normal conditions, and then the survival rate was analyzed statistically. Bar = 5 cm. Values are means ± standard deviation (SD) (n = 24). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. ***: p < 0.001.
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Figure 6. Overexpression of OsPIN9 causes cell damage in rice seedling leaves. (A) Trypan blue staining. Bar = 1 mm. (B) Electrolyte leakage. (C) Malondialdehyde contents. Values are means ± standard deviation (SD) (n = 6). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; ***: p < 0.001.
Figure 6. Overexpression of OsPIN9 causes cell damage in rice seedling leaves. (A) Trypan blue staining. Bar = 1 mm. (B) Electrolyte leakage. (C) Malondialdehyde contents. Values are means ± standard deviation (SD) (n = 6). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; ***: p < 0.001.
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Figure 7. Expression analysis of OsDREB1 genes, OsTPP1, and Ca2+ signaling genes under normal and chilling conditions in wild-type (WT) and OsPIN9-overexpressing (OE) plants. (A) OsDREB1s gene expression analysis. (B) OsTPP1 expression analysis. (C) Ca2+ signaling gene expression analysis. Values are means ± standard deviation (SD) (n = 3). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; **: p < 0.01; ***: p < 0.001.
Figure 7. Expression analysis of OsDREB1 genes, OsTPP1, and Ca2+ signaling genes under normal and chilling conditions in wild-type (WT) and OsPIN9-overexpressing (OE) plants. (A) OsDREB1s gene expression analysis. (B) OsTPP1 expression analysis. (C) Ca2+ signaling gene expression analysis. Values are means ± standard deviation (SD) (n = 3). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; **: p < 0.01; ***: p < 0.001.
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Figure 8. ROS detection in wild-type (WT) and OsPIN9-overexpressing (OE) leaves before and after chilling treatments. H2O2 and O 2 in WT and OE leaves were monitored by DAB and NBT staining, respectively, before chilling stress (A) and after chilling for 36 h (B) and 57 h (C). Bar = 1 mm.
Figure 8. ROS detection in wild-type (WT) and OsPIN9-overexpressing (OE) leaves before and after chilling treatments. H2O2 and O 2 in WT and OE leaves were monitored by DAB and NBT staining, respectively, before chilling stress (A) and after chilling for 36 h (B) and 57 h (C). Bar = 1 mm.
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Figure 9. Analysis of antioxidant enzyme activities in wild-type (WT) and OsPIN9-overexpressing (OE) plants before and after chilling treatments. Enzyme activities were detected before chilling stress (A) and after chilling for 36 h (B) and 57 h (C) in WT and OE lines. Values are means ± standard deviation (SD) (n = 6). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; **: p < 0.01; ***: p < 0.001.
Figure 9. Analysis of antioxidant enzyme activities in wild-type (WT) and OsPIN9-overexpressing (OE) plants before and after chilling treatments. Enzyme activities were detected before chilling stress (A) and after chilling for 36 h (B) and 57 h (C) in WT and OE lines. Values are means ± standard deviation (SD) (n = 6). The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; **: p < 0.01; ***: p < 0.001.
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Figure 10. OsRboh expression analysis in wild-type (WT) and OsPIN9-overexpressing (OE) lines before and after chilling treatment. The expression level of OsRboh genes in WT was set to one. The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; **: p < 0.01; ***: p < 0.001.
Figure 10. OsRboh expression analysis in wild-type (WT) and OsPIN9-overexpressing (OE) lines before and after chilling treatment. The expression level of OsRboh genes in WT was set to one. The data were analyzed by ANOVA and Tukey’s tests at a p < 0.05 significance level. *: p < 0.05; **: p < 0.01; ***: p < 0.001.
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MDPI and ACS Style

Ouyang, Q.; Zhang, Y.; Yang, X.; Yang, C.; Hou, D.; Liu, H.; Xu, H. Overexpression of OsPIN9 Impairs Chilling Tolerance via Disturbing ROS Homeostasis in Rice. Plants 2023, 12, 2809. https://doi.org/10.3390/plants12152809

AMA Style

Ouyang Q, Zhang Y, Yang X, Yang C, Hou D, Liu H, Xu H. Overexpression of OsPIN9 Impairs Chilling Tolerance via Disturbing ROS Homeostasis in Rice. Plants. 2023; 12(15):2809. https://doi.org/10.3390/plants12152809

Chicago/Turabian Style

Ouyang, Qiqi, Yanwen Zhang, Xiaoyi Yang, Chong Yang, Dianyun Hou, Hao Liu, and Huawei Xu. 2023. "Overexpression of OsPIN9 Impairs Chilling Tolerance via Disturbing ROS Homeostasis in Rice" Plants 12, no. 15: 2809. https://doi.org/10.3390/plants12152809

APA Style

Ouyang, Q., Zhang, Y., Yang, X., Yang, C., Hou, D., Liu, H., & Xu, H. (2023). Overexpression of OsPIN9 Impairs Chilling Tolerance via Disturbing ROS Homeostasis in Rice. Plants, 12(15), 2809. https://doi.org/10.3390/plants12152809

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