Summary
Superoxide dismutase (SOD) is widely assumed to play a role in the detoxification of reactive oxygen species caused by environmental stresses. We found a characteristic expression of manganese SOD 1 (MSD1) in a heat‐stress‐tolerant cultivar of rice (Oryza sativa). The deduced amino acid sequence contains a signal sequence and an N‐glycosylation site. Confocal imaging analysis of rice and onion cells transiently expressing MSD1‐YFP showed MSD1‐YFP in the Golgi apparatus and plastids, indicating that MSD1 is a unique Golgi/plastid‐type SOD. To evaluate the involvement of MSD1 in heat‐stress tolerance, we generated transgenic rice plants with either constitutive high expression or suppression of MSD1. The grain quality of rice with constitutive high expression of MSD1 grown at 33/28 °C, 12/12 h, was significantly better than that of the wild type. In contrast, MSD1‐knock‐down rice was markedly susceptible to heat stress. Quantitative shotgun proteomic analysis indicated that the overexpression of MSD1 up‐regulated reactive oxygen scavenging, chaperone and quality control systems in rice grains under heat stress. We propose that the Golgi/plastid MSD1 plays an important role in adaptation to heat stress.
Keywords: high‐temperature tolerance, Golgi, grain quality, Oryza sativa L., plastid, superoxide dismutase
Introduction
Impairment of rice (Oryza sativa L.) grain filling under global warming is a major threat facing Asian countries. Daily mean temperatures above 26 °C during the early ripening period of japonica rice compromises yields through decreases in grain size and quality (Morita et al., 2004; Peng et al., 2004; Tashiro and Wardlaw, 1991). Perfect grains are fully rounded, transparent and filled with normal starch granules. A chalky appearance reduces commercial value because of increased cracking during polishing (Fitzgerald et al., 2009) and poorer cooking quality (Singh et al., 2003; Tsutsui et al., 2013). Scanning microscope images of chalky areas of grain ripened under heat stress show loosely packed rounded starch granules (Evers and Juliano, 1976; Ishimaru et al., 2009; Tashiro and Wardlaw, 1991). The air spaces among these abnormal starch granules refract light, making the grain appear white. Occasional small pits on the surface of the starch granules suggest attack by starch‐degrading enzymes (Iwasawa et al., 2009; Zakaria et al., 2002); the suppression of α‐amylase genes improved the quality of rice grains ripened under heat stress (Hakata et al., 2012). It is widely recognized that heat stress lowers the activity of starch synthesis enzymes (Jiang et al., 2003; Umemoto and Terashima, 2002; Yamakawa et al., 2007). Mutants deficient in genes for starch synthesis enzymes exhibited dramatic changes in grain phenotype, including shape and chalkiness (Fujita et al., 2011; Kubo et al., 1999; Nishi et al., 2001; Tanaka et al., 2004). Furthermore, novel factors such as FLOURY ENDOSPERM2 (FLO2), GLUTELIN PRECURSOR MUTANT6 (GLUP6) and GLUTELIN PRECURSOR ACCUMULATION3 (GAP3) have been shown to be involved in the regulation of rice grain size and starch quality (Fukuda et al., 2013; Ren et al., 2014; She et al., 2010). FLO2 contains a tetratricopeptide repeat motif that interacts with late‐embryogenesis and basic helix‐loop‐helix proteins (She et al., 2010). GLUP6 is a guanine nucleotide exchange factor involved in intracellular transport from the Golgi apparatus to the protein storage vacuole, and the glup6 mutant accumulates an abnormally large amount of proglutelin (Fukuda et al., 2013). GAP3 is involved in post‐Golgi vesicular traffic for vacuolar protein sorting (Ren et al., 2014). In addition, redox regulation may affect seed maturation and quality (Onda and Kawagoe, 2011; Onda et al., 2011). Thus, the mechanism of grain chalkiness caused by heat stress may be highly complex.
Abiotic stresses, including high light, drought, salinity and heat, lead to the accumulation of reactive oxygen species (ROS) such as superoxide (), hydroxyl radicals (•OH) and hydrogen peroxide (H2O2; Apel and Hirt, 2004). ROS damage multiple cellular components, interfering with lipid peroxidation (Niki et al., 2005), breaking DNA strands (Brawn and Fridovich, 1981) and inactivating enzymes (Fucci et al., 1983). On the other hand, they also serve as signalling molecules, regulating processes including pathogen defence, programmed cell death and stomatal behaviour (Apel and Hirt, 2004). Although ROS are produced predominantly and continuously in chloroplasts, mitochondria and peroxisomes, the production and scavenging of ROS must be strictly controlled in the absence of stress. Enzymatic ROS scavenging mechanisms involve superoxide dismutase (SOD), ascorbate peroxidase, glutathione peroxidase and catalase (Apel and Hirt, 2004).
Superoxide dismutase catalyses the conversion of to H2O2; it is responsible primarily for defence against oxidative stress. There are three classes of SODs categorized by their metal cofactor: Fe SOD, Mn SOD and Cu/Zn SOD (Fridovich, 1975). Plant SODs have different subcellular localizations. Typically, Mn SOD is localized to the mitochondria, Fe SOD to the plastids and Cu/Zn SOD to the plastids and cytosol (Bowler et al., 1992; Kliebenstein et al., 1998). Peroxisomal and extracellular Cu/Zn SODs also exist (Bueno et al., 1995; Streller and Wingsle, 1994). Numerous attempts have been made to enhance stress tolerance in plants by modifying the production of SOD enzymes. Ectopic production of cytosolic Cu/Zn SOD improved stress tolerance in tobacco (Faize et al., 2011), potato (Perl et al., 1993), sugar beet (Tertivanidis et al., 2004) and plum (Diaz‐Vivancos et al., 2013). Overproduction of chloroplastic Cu/Zn SOD, Fe SOD and Mn SOD (fused to a chloroplast transit peptide) also increased stress resistance in tobacco (Badawi et al., 2004; van Camp et al., 1994, 1996; Sen Gupta et al., 1993; Slooten et al., 1995), potato (Perl et al., 1993), sugar beet (Tertivanidis et al., 2004), cotton (Payton et al., 2001) and alfalfa (McKersie et al., 2000). Transgenic rice overproducing cytosolic Cu/Zn SOD from mangrove (Avicennia marina) tolerated drought stress better than untransformed plants (Prashanth et al., 2008). Rice transformed with a yeast mitochondrial Mn SOD fused to the transit peptide of glutamine synthase conferred resistance to salt stress (Tanaka et al., 1999). Furthermore, rice transformed with pea (Pisum sativum) mitochondrial Mn SOD fused to the transit peptide of pea Cu/Zn SOD under the control of an oxidative stress‐inducible promoter was more resistant to oxidative stress induced by methyl viologen or polyethylene glycol (Wang et al., 2005).
We have been searching for candidate genes involved in heat‐stress tolerance during seed development to improve the formation of normal rice grains under a warming climate. In proteomic analysis, we detected a characteristic expression behaviour of Mn SOD in developing seeds of the heat‐resistant cultivar Yukinkomai. This Mn SOD exhibited a unique subcellular localization that has never previously been described in the literature. Here, we report that control of the Golgi/plastid‐type Mn SOD1 (MSD1) expression regulates tolerance to heat stress during grain filling of rice.
Results
Identification of Golgi/plastid‐type Mn SOD (MSD1)
We examined the heat susceptibilities of three rice cultivars, Yukinkomai, Yukinosei and Todorokiwase, during seed development from 2004 to 2008. The plants were grown in paddy fields with irrigation water at either ambient temperature or 35 °C during the heading, ripening and maturity stages. The daily mean temperature at around the panicles in the warm‐water field was 1.4–1.9 °C higher than that in the ambient‐water field (25.4 °C). The percentage of damaged grains in Yukinkomai was about 22% in both treatments (Figure 1), indicating that Yukinkomai is tolerant to high temperatures during development. In contrast, that of Todorokiwase increased from 35% to 44%. Yukinosei was intermediate (Figure 1). To search for genes involved in the heat tolerance of Yukinkomai, we used a proteomic approach. As rice is sensitive to heat stress at an early stage of seed development (Nagata et al., 2004; Satake and Yoshida, 1978), we separated grain proteins of Yukinkomai, Yukinosei and Todorokiwase at 4 days after flowering (DAF) by two‐dimensional polyacrylamide gel electrophoresis (2D‐PAGE). The separation profiles showed changes in the production of stress‐responsive proteins, including heat shock proteins 70 (HSP70) and 16.9 (HSP16.9), 20S proteasome αF, ABA‐inducible protein (R40g2), alcohol dehydrogenase (ADH) and MSD1 (Figure 2). In the heat‐tolerant Yukinkomai, 20S proteasome αF, ADH and HSP16.9 were up‐regulated and R40g2 were down‐regulated under heat stress (Figure 2a,b). In the susceptible Todorokiwase, in contrast, HSP70, HSP16.9 and MSD1 were up‐regulated (Figure 2e,f). Those in Yukinosei were intermediate (Figure 2c,d). We focused on MSD1, which was characteristically and highly expressed in developing seeds of Yukinkomai in both treatments (Figure 2a,b).
The RiceXPro public microarray database (http://ricexpro.dna.affrc.go.jp/) shows that the MSD1 gene (OsMSD1) is actively expressed throughout the rice plant, particularly in the embryo and endosperm of developing seeds. Our gel‐based proteomic analysis of developing seeds supports the view that MSD1 is a major constituent in the seed proteome (Figure 2a,b). OsMSD1 is located in the centre of chromosome 5 (Figure 3a). The cDNA is 901 bp in length, encoding 231 amino acid residues that form a 24.9‐kDa precursor protein (Figure 3b). MSD1 is mitochondrial enzyme in both monocots and dicots (Kliebenstein et al., 1998; del Río et al., 2003; White and Scandalios, 1988; Wu et al., 1999). Analyses by the PSORT algorithm (http://psort.hgc.jp/form.html) predicted an N‐terminal mitochondrion‐targeting sequence in the precursor proteins of MSD1 of Arabidopsis, maize, wheat and pea (Figure 3b). Indeed, pea MSD1 is localized chiefly in mitochondria (del Río et al., 2003). However, the prediction by PSORT and signalP (http://www.cbs.dtu.dk/services/SignalP/) showed that the rice MSD1 precursor's N‐terminal sequence potentially acts as signal to the endoplasmic reticulum (ER; Figure 3b; Sakamoto et al., 1993).
To determine the subcellular localization of rice MSD1, we analysed the transient expression of OsMSD1 fused with a gene for yellow fluorescent protein (YFP) in rice and onion epidermal cells, using particle bombardment. In rice cells, confocal laser scanning microscopy showed that the distribution of MSD1‐YFP coincided well with the autofluorescence of chloroplasts (Figure 4). In onion cells, MSD1‐YFP revealed numerous particulate structures (Figure 5a,c). When MSD1‐YFP was cobombarded with a sequence encoding a trans‐Golgi marker (sialyltransferase, ST) fused at the transmembrane domain to monomeric red fluorescent protein (ST‐mRFP) into onion cells, MSD1‐YFP fluorescence overlapped well with the ST‐mRFP‐labelled trans‐Golgi vesicles (Figure 5a). The GTPases ARF1 and SAR1 are essential for membrane trafficking between the ER and the Golgi apparatus in higher plant cells. Expression of dominant‐negative ARF1 or constitutively active SAR1 mutant proteins, which are defective in GTPase cycling, prevents the ER‐to‐Golgi traffic (Takeuchi et al., 2000, 2002). Golgi‐resident proteins and secretory and vacuolar proteins are therefore retained in the ER with such mutants (Takeuchi et al., 2000, 2002). We examined the effects of dominant‐negative and constitutive‐active mutants of ARF1 and SAR1 on the subcellular distribution of MSD1‐YFP. We simultaneously expressed MSD1‐YFP, the trans‐Golgi marker ST‐mRFP, and either AtARF1(T31N), AtARF1(Q71L), or AtSAR1(H74L) in onion cells. Both MSD1‐YFP‐ and ST‐mRFP‐labelled vesicles were rearranged and remerged into tubular structures, which are probably part of the ER network, in cells expressing the mutants (Figure 5b).
Recent investigations have revealed the dual targeting of proteins to Golgi apparatus and plastids in Arabidopsis (Villarejo et al., 2005), rice (Asatsuma et al., 2005; Chen et al., 2004; Kaneko et al., 2011, 2014; Kitajima et al., 2009; Nanjo et al., 2006) and photosynthetic micro‐organisms (van Dooren et al., 2001; Nowack and Grossman, 2012; Sláviková et al., 2006). To test the possibility of plastid‐targeting of MSD1, we cobombarded MSD1‐YFP with a sequence encoding a plastid marker, the transit peptide of Waxy (Klösgen and Weil, 1991) fused to red fluorescent protein from Discosoma sp. (WxTP–DsRed), into onion cells. MSD1‐YFP was notably colocalized with the plastids visualized by WxTP–DsRed (Figure 5c). Simultaneous expression of MSD1‐YFP, the plastid marker WxTP–DsRed, and either AtARF1(T31N), AtARF1(Q71L), or AtSAR1(H74L) indicated that the plastid targeting of MSD1‐YFP was inhibited in cells expressing the ARF1 and SAR1 mutant proteins (Figure 5d,f). The overall results clearly indicate that MSD1 is a multilocalizing protein that is targeted to the interior of plastids from the Golgi apparatus via the secretory pathway.
Overexpression and suppression of MSD1 affect the grain quality of rice ripened under heat stress
To determine the possible stress‐adapting function of MSD1 in ripening seeds of rice, we generated transgenic overexpressor (OE) plants with the maize Ubiquitin‐1 promoter (PUbi1) fused to MSD1 (MSD1OE) by Agrobacterium‐mediated transformation. It was reported that PUbi1‐controlled genes are highly expressed in various rice tissues (Cornejo et al., 1993). The expression profiles of MSD1 mRNA in leaves, roots and developing seeds of Nipponbare wild type (WT) and MSD1OE revealed a constitutive high expression of MSD1 in MSD1OE plants (Figure 6a–c). Furthermore, H2O2 increased in the developing seeds and young seedlings of MSD1OE (Figure 7). The ratio of H2O2 content between MSD1OE and WT seedlings under hot condition revealed that H2O2 formation increased in MSD1OE under heat stress (Figure 7b). When plants were incubated at normal or high temperatures after heading, the ratios of perfect grains harvested were 78% (WT) and 83% (MSD1OE) at 28/23 °C, 77% (WT) and 88% (MSD1OE) at 30/23 °C, and 26% (WT) and 60% (MSD1OE) at 33/28 °C (Figure 6d–f). Under heat stress, the grain quality of MSD1OE was significantly greater than that of WT (Figures 6f and S1). To suppress the expression of MSD1 in developing seeds, we used a 696‐bp fragment of MSD1 cDNA which contains no sequence of more than 21 nucleotides conserved with other rice SODs to construct RNA interference (RNAi) binary vectors under the control of the promoter of the developing endosperm‐specific Waxy (PWx) by arranging two identical fragments derived from MSD1 in a tail‐to‐tail manner, yielding a vector generating artificial hairpin‐structure transcripts (Figure S2). We generated two transgenic knock‐down (KD) rice plants transformed with PWx fused to MSD1 RNAi, designated Nipponbare MSD1KD and Yukinkomai MSD1KD. Both transformants were grown under heat stress after heading. The expression of MSD1 mRNA in developing seeds decreased to 18% of WT in Nipponbare MSD1KD and 53% in Yukinkomai MSD1KD (Figure 6g,i), along with significant decreases in the proportion of perfect grains (to 12% and 71%, respectively; Figure 6h,j). The overall results indicate that the constitutive high expression of MSD1 was involved in maintaining the quality of rice grains produced under heat stress during ripening.
Proteomic characterization of developing seeds of MSD1OE under heat stress
To clarify how constitutive high expression of MSD1 leads to adaptation to heat stress, we carried out quantitative shotgun proteomic analysis of ripening seeds. Proteins extracted from ripening seeds of Nipponbare WT and MSD1OE grown under control (28/23 °C) and heat stress (33/28 °C) conditions at 4 and 10 DAF were labelled by iTRAQ (isobaric tag for relative and absolute quantitation), followed by tandem mass spectrometry (MS/MS) analysis. Under heat stress, 79 proteins (~6% of all identified proteins), including storage and allergen proteins, were down‐regulated and 219 (~16%) were up‐regulated in the ripening seeds of MSD1OE relative to WT (Table S1). Under the control condition, however, the characteristic response of MSD1OE did not appear. Under high temperature, scavengers of reactive oxygen species (ROS), including Cu/Zn SOD, peroxiredoxins, thioredoxin, peptide methionine sulfoxide reductase, ascorbate peroxidases, monodehydroascorbate reductase and NADH‐ubiquinone oxidoreductase, were markedly up‐regulated in MSD1OE relative to WT (Figure 8 upper panel). Under the control condition, however, changes were minor. Several HSPs, chaperones, chaperonins, calreticulin, proteasome components and S‐phase kinase‐associated protein 1 were also up‐regulated in MSD1OE under heat stress (Figure 8 lower panel), but glutelin, prolamin and allergen family proteins were down‐regulated (Figure S3).
Discussion
Identification of Golgi/plastid‐type Mn SOD
Generally, Mn SODs are known as mitochondrial enzymes in both monocots and dicots (Kliebenstein et al., 1998; del Río et al., 2003; White and Scandalios, 1988; Wu et al., 1999) and in eukaryotic algae (Kitayama et al., 1999; Wolfe‐Simon et al., 2005). However, Mn SOD was localized in the chloroplasts of a marine diatom, Thalassiosira pseudonana (Wolfe‐Simon et al., 2006). The chloroplastic Mn SOD controlled by the nuclear‐encoded sodA gene must have plastid/ER transit peptides, but typical transit peptides have not been identified (Wolfe‐Simon et al., 2006). As shown in Figure 3b, the deduced amino acid sequence predicted that MSD1 is an extracellular glycoprotein with an N‐linked oligosaccharide chain. Confocal fluorescent microscopy revealed that rice MSD1 localized in multiple plastids and Golgi apparatus (Figures 4 and 5). Furthermore, the dominant‐negative and constitutive‐active mutants of ARF1 and SAR1 GTPases arrested the plastid‐targeting of MSD1‐YFP (Figure 5d), and the MSD1‐YFP fluorescence was rearranged into an ER tubular network (Figure 5b). This indicates that MSD1 is transported from the Golgi apparatus via the secretory pathway to the plastid, as are Arabidopsis CAH1 (Burén et al., 2011; Villarejo et al., 2005), O. sativa AmyI‐1 (Asatsuma et al., 2005; Kitajima et al., 2009) and NPP1 (Kaneko et al., 2011, 2014; Nanjo et al., 2006). This is the first report of the Golgi‐to‐plastid traffic of noncarbohydrate metabolism‐related enzyme.
The electron transport chain in chloroplasts contains several auto‐oxidizable enzymes. Ferredoxin in the reduced state can react with oxygen, releasing (Asada and Takahashi, 1987) and the aprotic interior of thylakoid membranes also produces (Takahashi et al., 1988). The outer layer tissues of developing rice seeds, namely the pericarp and the endosperm, contain chloroplasts during grain filling. Large amounts of starch molecules are synthesized and accumulated in the amyloplasts of endosperm cells. Thus, there is a need for ROS scavenging in the plastids of developing rice seeds. In addition to starches, proteins are also actively synthesized, assembled and stored in developing seeds. Storage proteins such as glutelins are synthesized in the ER and transported via the Golgi apparatus to the protein storage vacuoles (Ren et al., 2014; Washida et al., 2012). The production of H2O2 from O2 resulting from the maturation of glutelin in the endomembrane system (Onda et al., 2009) suggests the existence of an endomembranous ROS scavenging system.
Overproduction of MSD1 improves quality grain ripened under heat stress
Ectopic production of Golgi/plastid‐type MSD1 significantly improved the quality of rice grain ripened under heat stress (Figure 6f). On the other hand, suppression of MSD1 reduced the normal formation of rice grains (Figure 6h,j). These results indicate that the constitutive high expression of Golgi/plastid‐type MSD1 is effective for maintaining the formation of perfect grains under heat stress during grain filling. The introduction of yeast MnSOD and pea mitochondrial MnSOD into chloroplasts of rice conferred tolerance to salt and oxidative stress (Tanaka et al., 1999; Wang et al., 2005). In addition, transgenic rice transformed with mangrove cytosolic Cu/ZnSOD showed better tolerance to drought (Prashanth et al., 2008). We found that enhancement of OsMSD1 conferred significant tolerance to high temperatures during rice grain filling.
OsMSD1 is located in the centre of chromosome 5 (Figure 3a). Quantitative trait loci (QTLs) controlling grain appearance quality have been identified in populations derived from crosses between japonica cultivars (Ebitani et al., 2005; Kobayashi et al., 2007; Tabata et al., 2007), between japonica and indica cultivars (He et al., 1999; Wan et al., 2005) and between O. sativa and Oryza glaberrima (Li et al., 2004). The identification of a grain chalkiness QTL (qAPG5‐1, Ebitani et al., 2008) close to the position of MSD1 (Ebitani et al., 2005; Yamakawa et al., 2008) suggests that MSD1 is a determinant of chalkiness.
Proteomic characterization of developing seeds of MSD1OE under heat stress
Quantitative proteomic analysis of ripening seeds of MSD1OE and WT grown in normal and heat‐stress conditions at 4 and 10 DAF revealed that 79 proteins were down‐regulated and 219 were up‐regulated in MSD1OE under heat stress in comparison with WT (Table S1). The ROS scavenging system, molecular chaperones, chaperonins, calreticulin and proteasome components were markedly up‐regulated in MSD1OE under high temperature (Figure 8). In contrast, glutelin, prolamin and allergen family proteins were strongly down‐regulated (Figure S3). We detected an increase in APX 1, 2 and 4 in the developing seeds of MSD1OE. Monodehydroascorbate reductase, which regenerates ascorbate from monodehydroascorbate, was also up‐regulated (Figure 8 upper panel). The enhancement of APX production in rice (Lu et al., 2007; Tanaka et al., 1999) and other plants (Diaz‐Vivancos et al., 2013; Faize et al., 2011) confers abiotic stress tolerance. In addition, a series of peroxiredoxins (thioredoxin peroxidases), including 2‐Cys peroxiredoxin, were up‐regulated in MSD1OE (Figure 8 upper panel). Yeast transformed with O. sativa 2‐Cys peroxiredoxin showed increased stress tolerance and fermentation capacity (Kim et al., 2013). Moreover, an HSP was increased in MSD1OE under heat stress (Figure 8 lower panel). In rice (Sato and Yokoya, 2008) and Arabidopsis (Mu et al., 2013), overexpression of small HSPs enhanced tolerance to drought, salt and heat. Overall, these proteomic results and the literature strongly support the conclusion that MSD1OE rice showed improved adaptability to heat stress.
How is MSD1 involved in the adaptation of MSD1OE to heat stress? We considered that the constitutive high expression of MSD1 immediately converts to H2O2 under heat stress, and H2O2 probably serves as a trigger for enhancing the expression of the ROS scavenging system and HSP genes, as the level of H2O2 was higher in MSD1OE than in WT (Figure 7). H2O2 is one of the most abundant ROS and is both highly reactive and toxic. However, H2O2 also functions as a signalling molecule and activates the MAPK cascade (Apel and Hirt, 2004; Neill et al., 2002). For example, H2O2 induced ascorbate peroxidase in embryos of germinating rice (Morita et al., 1999), in Arabidopsis leaves (Karpinski et al., 1999) and in tobacco leaves (Gupta et al., 1993) and induced peroxiredoxin in mammalian thyroid cells (Kim et al., 2000). Therefore, induced peroxiredoxin and ascorbate peroxidase likely work as the main regulators of intracellular H2O2 concentrations in MSD1OE. Furthermore, heat‐stress‐induced H2O2 was involved in the early stage of activation of heat shock factor (HSF) in Arabidopsis cell culture (Volkov et al., 2006). In rice leaves, H2O2 treatment induced the production of a chloroplastic small HSP (Lee et al., 2000). Thus, H2O2 formed by Golgi/plastid‐type MSD1 is the key factor that confers heat tolerance on MSD1OE.
Storage and allergen family proteins were down‐regulated in the early developing seeds of MSD1OE under heat stress (Figure S3). The formation of protein bodies in developing seed cells of heat‐susceptible Todorokiwase was brought forward by higher temperature (T. M., unpublished data). We infer that the constitutive high expression of Golgi/plastid‐type MSD1 controls the redox state in the endomembrane system, leading to the normal programmed formation of protein bodies. Further studies will be needed to confirm this hypothesis.
In conclusion, we found a novel Golgi/plastid‐type Mn SOD in developing rice seeds. The ectopic expression of MSD1 dramatically induced the expression of ROS scavengers, molecular chaperones and the quality control system in developing seeds under heat stress. We consider that the constitutive high expression of MSD1 maintains normal grain filling and the production of perfect grains of rice under heat stress.
Experimental procedures
Plasmids
The plasmids used in this study and references describing how they were constructed are listed in Table S2.
Plant materials and growth conditions
Seeds of rice cultivars Yukinkomai, Yukinosei, Todorokiwase and Nipponbare (a model cultivar used for transformant experiments) were obtained from the Niigata Agricultural Research Institute Crop Research Center (Nagaoka city, Niigata, Japan). Transgenic lines of rice (cv. Nipponbare) overexpressing MSD1 under the control of maize Ubiquitin‐1 constitutive promoter (MSD1OE) were obtained from the full‐length cDNA overexpressor (FOX) lines of rice (Nakamura et al., 2007).
Transgenic plants with suppression of the MSD1 gene in developing seeds were generated as follows: MSD1 cDNA (bp 1–696) which contains no sequence of more than 21 nucleotides conserved with other rice SODs was amplified by PCR from pOsMSD1 (accession no. AK104160) with a primer set (Table S2) and introduced into pESWA (Islam et al., 2005) to construct the RNAi vector pWX‐WB‐MSD1‐RNAi in combination with the Wx promoter (Figure S2) using a pENTR Directional TOPO Cloning Kit and the Gateway LR Clonase Enzyme mix (Thermo Fisher Scientific, Waltham, MA). The binary RNAi vector was transformed into Agrobacterium tumefaciens strain EHA101 (Hood et al., 1986), and Agrobacterium‐mediated transformation of rice plants was performed as described by Hiei et al. (1994). We generated two transgenic knock‐down (KD) rice lines transformed with pWX‐WB‐MSD1‐RNAi, designated Nipponbare MSD1KD and Yukinkomai MSD1KD.
Yukinkomai, Yukinosei and Todorokiwase plants were grown in paddy fields of the Crop Research Center from 2004 to 2008 with ambient temperature or warm water. During the heading, ripening and maturity stages, the warm water was supplied at 35 °C at a flow rate of 80 L/min, making the daily mean temperature at around the ear 1.4–1.9 °C higher than that of the ambient temperature field (25.4 °C).
Transgenic and wild‐type (Nipponbare) plants were grown under 28/23 °C (12 h at 20 000 lx/12 h dark) in a growth chamber (CFH‐415; Tomy Seiko, Tokyo, Japan). Grain quality (chalky or translucent) was determined with a rice grain grader (RGQI20A; Satake, Hiroshima, Japan).
Microscopy studies
Yellow fluorescent protein (YFP) is a genetic mutant of green fluorescent protein from Aequorea victoria. We constructed pH35GY‐OsMSD1‐YFP to determine the subcellular localization of rice MSD1. We PCR‐amplified MSD1 from pOsMSD1 (primers in Table S2) and introduced it into pH35GY (Funakoshi Corp, Tokyo, Japan; Kubo et al., 2005) to create pH35GY‐OsMSD1‐YFP. To obtain pH35GY‐(AAGCTT)‐YFP (YFP vector alone), we PCR‐amplified an OsEMP70 fragment (bp 1083–1584) from pOsEMP70 (primers in Table S2) and introduced it into pH35GY. The pH35GY‐∆OsEMP70‐YFP construct was digested with HindIII to remove the OsEMP70 fragment and ligated with a Mighty Mix DNA ligation kit (Takara Bio, Ohtsu, Japan).
Construction of pWxTP‐DsRed (red fluorescent protein from Discosoma sp.; Kitajima et al., 2009), pST‐mRFP (monomeric red fluorescent protein; Matsuura‐Tokita et al., 2006), pMT121‐ARF1 T31N, pMT121‐ARF1 Q71L and pMT121‐SAR1 H74L (Takeuchi et al., 2000, 2002) were described elsewhere.
To introduce plasmid DNA into rice and onion (Allium cepa) epidermal cells, we used the particle bombardment method, using a helium‐driven particle accelerator, as described previously (Kitajima et al., 2009). Confocal laser‐scanning microscopes (FV300 and FV1000; Olympus, Tokyo, Japan) were used for imaging YFP, DsRed and chlorophyll autofluorescence in rice and onion cells (Kitajima et al., 2009). The FV300 uses an Ar laser at 488 nm to excite YFP and a green He/Ne laser at 543 nm to excite DsRed and chlorophyll. Fluorescence was detected at 510–530 nm through BA510IF and BA530RIF emission filters with an SDM570 emission dichroic mirror (YFP) and at >565 nm through a BA565IF emission filter (DsRed and chlorophyll). The FV1000 uses an Ar laser at 488 nm to excite YFP, and at 559 nm to excite DsRed and chlorophyll. Fluorescence was detected at 510 nm through an SDM560 emission dichroic mirror (YFP) and at 581 nm with an emission dichroic mirror (DsRed and chlorophyll). Images were observed through 40× air‐objective (UApo/340, NA 0.90; Olympus) and 100× oil‐objective lenses (UPlanSApo, NA 1.40 Oil; Olympus). The fluorescence intensity in plastids and in whole cells was determined using Lumina Vision imaging software. The background was always set at the maximum fluorescence intensity of an area in which no structural image was present. Areas identified by either chlorophyll autofluorescence or WxTP–DsRed were defined as plastids. To evaluate the plastid‐targeting abilities of YFP‐labelled proteins, we determined the ratio of the fluorescent intensity of YFP in the plastid to that in the whole cell (YFPplastid/YFPtotal; Kitajima et al., 2009).
Assay and diaminobenzidine staining for H2O2
H2O2 assays were carried out according to the procedure of Rao et al. (2000) and Xiong et al. (2007). Shoots and roots from rice seedlings at 7 days after imbibition were frozen and ground to a powder. Each sample (100 mg) was suspended in 0.5 mL of 0.2 m HClO4, incubated on ice for 5 min and then centrifuged at 14 000 g for 10 min at 4 °C. The supernatant was neutralized with 0.2 m NH4OH (pH 9.5) and centrifuged at 3000 g for 2 min. The neutralized extracts were passed through Sep‐Pak Light Accell Plus QMA Carbonate columns (Nihon Waters, Tokyo, Japan) and were eluted with 0.5 mL water. H2O2 in the extracts was quantified using an Amplex Red Hydrogen Peroxide–Peroxidase Assay kit (Life Technology Japan, Tokyo, Japan) following the manufacturer's directions. Fluorescence was measured with an RF‐5300PC spectrofluorophotometer (Shimadzu Corp., Kyoto, Japan) using excitation at 530 nm and fluorescence detection at 590 nm. For histochemical analysis, developing seeds (14 DAF) were sliced into 1‐mm transverse sections and immersed in 20 mm Tris·HCl buffer (pH 6.5) containing 1% (w/v) 3,3′‐diaminobenzidine. After vacuum infiltration for 30 min, the samples were incubated at room temperature for 20 h in the dark to develop a dark‐brown colour of diaminobenzidine oxidized by H2O2.
Gel‐based proteomics
Grains of Yukinkomai, Yukinosei and Todorokiwase (100 mg) at 4 DAF were extracted with 8 m urea, 1% (w/v) CHAPS detergent, 10 mm ethylene diamine tetraacetic acid (EDTA) and 5 mm phenylmethylsulfonyl fluoride and centrifuged at 10 000 g for 10 min at 4 °C. The supernatants were precipitated with 10% (w/v) trichloroacetic acid and resolved with 9 m urea, 3% (w/v) IGEPAL detergent, and 2% (v/v) 2‐mercaptoethanol and then used for gel‐based proteomics. The procedures of 2D polyacrylamide gel electrophoresis (2D‐PAGE) and matrix‐assisted laser desorption ionization time‐of‐flight MS (MALDI‐TOF‐MS) were essentially identical to the previous reports (Kaneko et al., 2011; Nanjo et al., 2004). In 2D‐PAGE, the 1st dimension used isoelectric focusing with ampholine (pH 3.5–10) and the 2nd dimension used sodium dodecyl sulphate (SDS)‐PAGE with 16% separating gel. The 2D gels were stained with Coomassie brilliant blue R‐250 (Nanjo et al., 2004). The protein spots excised from the gels were digested by trypsin using standard procedures (Awang et al., 2010). MALDI‐TOF‐MS was carried out with a matrix of α‐cyano‐4‐hyrdoxycinnamic acid in an AXIMA‐CFR mass spectrometer (Shimadzu Corp.) and an Autoflex III TOF/TOF mass spectrometer (Bruker BioSpin, Yokohama, Japan; Kaneko et al., 2011).
Quantitative shotgun proteomics
At 4 and 10 DAF, developing seeds of WT and MSD1OE grown under hot (33/28 °C, 12/12 h) or control conditions (28/23 °C, 12/12 h) were used in quantitative shotgun proteomic analysis with iTRAQ labelling. The seeds (0.2 g) were ground in liquid nitrogen to a fine powder and suspended in extraction buffer consisting of 100 mm Tris·HCl (pH 8.0), 20% (w/v) glycerol, 2% (w/v) Triton X‐100, 20 mm dithiothreitol, 3 m urea, 2 m thiourea and 3% (w/v) CHAPS. The homogenates were centrifuged at 10 000 g at 4 °C for 5 min. The supernatant was collected and centrifuged again. The supernatants were mixed with 1/10 volume of 100% (w/v) trichloroacetic acid, incubated on ice for 15 min and centrifuged at 10 000 g at 4 °C for 15 min. The resulting protein precipitates were washed 3 times in ice‐cold acetone and resuspended in 0.5 m triethylammonium bicarbonate buffer (pH 8.5) containing 0.1% SDS. Protein concentration was determined by the Bradford method (Bio‐Rad Laboratories, Hercules, CA) using bovine serum albumin as a standard. Proteins (50 μg) were reduced with tris‐(2‐carboxyethyl) phosphine at 37 °C for 60 min and then alkalized with methylmethanethiosulfonate at 25 °C for 60 min. Samples were digested in 10 μL of trypsin (1 μg/μL) at 37 °C for 16 h and labelled with 4‐plex iTRAQ tags (Thermo Fisher Scientific) according to Fukao et al. (2011), and the resultant 4 iTRAQ‐labelled peptide samples were mixed.
For quantitative proteomics, we used a combined KYA DiNA‐A (KYA Tech., Tokyo, Japan) and LTQ‐Orbitrap XL (Thermo Fisher Scientific) liquid chromatography‐MS/MS system. The ionization voltage and capillary transfer temperature at the electrospray ionization nano‐stage were set to 1.7–2.5 kV and 200 °C. iTRAQ‐labelled peptides were separated in a HiQ sil C18W column (75 μm i.d. ×50 mm, 3 μm particle size; KYA Tech.), using buffers A (0.1% [v/v] acetic acid and 2% [v/v] acetonitrile in water) and B (0.1% [v/v] acetic acid and 80% [v/v] acetonitrile in water). A linear gradient from 0% to 33% B for 240 min, 33% to 100% B for 10 min and back to 0% B over 15 min was applied, and peptides eluted from the column were introduced directly into an LTQ‐Orbitrap XL mass spectrometer (Thermo Fisher Scientific, Bremen, Germany) at a flow rate of 300 nL min−1 and a spray voltage of 4.5 kV.
Liquid chromatography‐MS/MS data were acquired in data‐dependent acquisition mode using Xcalibur 2.0 software (Thermo Fisher Scientific). The mass range selected for MS scan was set to 350–1600 m/z, and the top three peaks were subjected to MS/MS analysis. Full MS scan was detected in the Orbitrap, while the MS/MS scans were detected in the linear ion trap and Orbitrap. The normalized collision energy for MS/MS was set to 35 eV for collision‐induced dissociation (CID) and 45 eV for higher energy C‐trap dissociation (HCD). The resolution of the mass spectrometer (FTMS) was set to 60 000. Divalent or trivalent ions were subjected to MS/MS analysis in dynamic exclusion mode, and proteins were identified with Proteome Discoverer v. 1.1 software and the SEQUEST search tool (Thermo Fisher Scientific) using the UniProt (http://www.uniprot.org/) O. sativa subsp. japonica database (63 535 proteins) with the following parameters: enzyme, trypsin; maximum missed cleavages site, 2; peptide charge, 2+ or 3+; MS tolerance, 10 ppm; MS/MS tolerance, ±0.8 Da; dynamic modification; carboxymethylation (C); oxidation (H, M, W); iTRAQ 4‐plex (K, Y, N‐terminus). False discovery rates were <5%.
mRNA analysis
Sample tissues (0.1 g) were ground in liquid nitrogen to fine powder and suspended in an extraction buffer consisting of 2% (w/v) cetyl trimethyl ammonium bromide, 100 mm Tris·HCl (pH 8.0), 20 mm EDTA and 1.4 m NaCl. The homogenates were mixed with 1/2 volumes of phenol and chloroform/isoamyl alcohol (25:24:1, v/v), centrifuged at 10 000 g at 4 °C for 5 min, and total RNA was extracted with RNeasy Plant Mini Kit (Qiagen, Tokyo, Japan) according to the manufacturer's instructions. Ten ng of total RNA was applied to a real‐time quantitative reverse transcription PCR using SsoFast Eva Green Supermix (Bio‐Rad) and CFX96 real time PCR system/C1000TM Thermal Cycler (Bio‐Rad) with the PCR primer sets listed in Table S3. The mRNA contents in each sample were normalized against those of constitutive 18S rRNA gene (Accession no. AK059783).
Supporting information
Acknowledgements
This research was supported by a Grant for Promotion of KAAB Projects (Niigata University), Scientific Research on Innovative Areas (22114507) and Grants‐in‐Aid for Scientific Research (B) (22380186) from the Ministry of Education, Culture, Sports, Science and Technology, Japan to T. M. This work was also supported in part by a grant from the Ministry of Agriculture, Forestry and Fisheries of Japan (Genomics for Agricultural Innovation, AMR‐0001) to H. I. We are indebted to Dr. A. Nakano (The University of Tokyo, Japan) for providing pST‐mRFP, pMT121‐ARF1 T31N, pMT121‐ARF1 Q71L and pMT121‐SAR1 H74L.
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