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BIOENERGETICS AND PHOTOSYNTHESIS

Remodeled Respiration in ndufs4 with Low Phosphorylation Efficiency Suppresses Arabidopsis Germination and Growth and Alters Control of Metabolism at Night^1,[W],[OA]

Australian Research Council Centre of Excellence in Plant Energy Biology, University of Western Australia, Crawley, Western Australia 6009, Australia (E.H.M., T.T., A.J.C., E.D., S.K.T., I.D.S., A.H.M.); and Australian Research Council Centre of Excellence in Plant Energy Biology, School of Biology, Australian National University, Canberra, Australian Capital Territory 0200, Australia (G.E., B.J.P.)

	ABSTRACT

TOP ABSTRACT RESULTS DISCUSSION CONCLUSION MATERIALS AND METHODS LITERATURE CITED

 
Respiratory oxidative phosphorylation is a cornerstone of cellular metabolism in aerobic multicellular organisms. The efficiency of this process is generally assumed to be maximized, but the presence of dynamically regulated nonphosphorylating bypasses implies that plants can alter phosphorylation efficiency and can benefit from lowered energy generation during respiration under certain conditions. We characterized an Arabidopsis (Arabidopsis thaliana) mutant, ndufs4 (for NADH dehydrogenase [ubiquinone] fragment S subunit 4), lacking complex I of the respiratory chain, which has constitutively lowered phosphorylation efficiency. Through analysis of the changes to mitochondrial function as well as whole cell transcripts and metabolites, we provide insights into how cellular metabolism flexibly adapts to reduced phosphorylation efficiency and why this state may benefit the plant by providing moderate stress tolerance. We show that removal of the single protein subunit NDUFS4 prevents assembly of complex I and removes its function from mitochondria without pleiotropic effects on other respiratory components. However, the lack of complex I promotes broad changes in the nuclear transcriptome governing growth and photosynthetic function. We observed increases in organic acid and amino acid pools in the mutant, especially at night, concomitant with alteration of the adenylate content. While germination is delayed, this can be rescued by application of gibberellic acid, and root growth assays of seedlings show enhanced tolerance to cold, mild salt, and osmotic stress. We discuss these observations in the light of recent data on the knockout of nonphosphorylating respiratory bypass enzymes that show opposite changes in metabolites and stress sensitivity. Our data suggest that the absence of complex I alters the adenylate control of cellular metabolism.

Plant respiratory chains also contain additional, non-proton-translocating, entry points for electrons known as nonphosphorylating bypasses. These NAD(P)H dehydrogenases have been identified and localized either on the cytosolic or the matrix side of the inner membrane and transfer electrons from cytosolic or matrix NADH pools directly to ubiquinone (Rasmusson and Moller, 1991; Rasmusson et al. 2008). In addition, the alternative oxidase (AOX) can bypass the cytochrome pathway by oxidizing ubiquinol and reducing molecular oxygen, and it does this in a nonphosphorylating manner (Lambers, 1982).

The potential for plants to dynamically alter their efficiency of phosphorylation is remarkable when one considers that even small changes in OXPHOS efficiency in animals are associated with disease, aging, and cellular dysfunction (Gellerich et al., 2004). For example, deficiency in complex I function has been associated with several human diseases such as Leber's heredity optic neuropathy (Wallace et al., 1988), Leigh syndrome (Hoefs et al., 2008), and leukodystrophy (Holt et al., 1988), and complete absence of complex I is considered lethal. A number of plant mutants lacking respiratory chain components have been studied, including mutants in complex I (Marienfeld and Newton, 1994; Pla et al., 1995; Lee et al., 2002; Perales et al., 2005) and mutants removing specific nonphosphorylating bypasses such as AOX (Giraud et al., 2008). Mutants lacking complex II are embryo lethal in plants (Leon et al., 2007) and mutants lacking complex III or IV have not been reported, presumably as these are lethal in plants, as are mutants in the assembly of c-type cytochromes (Meyer et al., 2005).

Complex I is especially interesting for respiratory remodeling studies, as its absence will lower the maximal efficiency of OXPHOS by one-third, thus forcing a recalibration of a primary driver in cellular energy homeostasis. Mutants in genes encoding complex I subunits in Arabidopsis (Arabidopsis thaliana) include the 18-kD subunit (Lee et al., 2002) and the plant-specific CA2 subunit (Perales et al., 2005). Natural mitochondrial mutants lacking some of the mitochondrial nad genes as a result of genome rearrangements have been described in maize (Marienfeld and Newton, 1994) and Nicotiana sylvestris (Pla et al., 1995). Finally, several mutants have been identified in genes encoding splicing factors involved in the expression of nad4 in N. sylvestris (Brangeon et al., 2000) and Arabidopsis (Nakagawa and Sakurai, 2006) and of nad1 in Arabidopsis (de Longevialle et al., 2007). These mutants display a whole range of phenotypes, but the only one that has been studied to characterize the effects of the absence of complex I is the cytoplasmic male sterile II (CMSII) mutant in N. sylvestris.

The CMSII mutant is a natural mutant that has lost the nad7 gene after a rearrangement of the mitochondrial genome (Pla et al., 1995). CMSII mutant growth is retarded compared with wild-type plants (Gutierres et al., 1997). In this mutant, complex I is absent, the respiration is rotenone insensitive (rotenone is an inhibitor of complex I), the oxidation of Gly is reduced, and the capacity of the alternative pathway is increased (Sabar et al., 2000). Photosynthesis is reduced by 20% to 30% under atmospheric conditions. This effect can be canceled under high CO₂ or low O₂ (Dutilleul et al., 2003a). The photorespiratory pathway is increased in CMSII via an increased internal resistance to CO₂ diffusion (Priault et al., 2006). A metabolomic study showed that nitrogen metabolism was affected in the mutant with accumulation of nitrogen-rich amino acids (Dutilleul et al., 2005) and that the shoot-root ratio is higher in the CMSII mutant at low nitrogen (Pellny et al., 2008). Finally, the expression of many stress-related genes was modified, resulting in a higher tolerance to ozone and Tobacco mosaic virus (Dutilleul et al., 2003b).

Another approach used to understand the role of complex I is to use inhibitors such as rotenone. Rotenone is an isoflavonoid produced by plants in the legume family and is classically used as an inhibitor of complex I (Ayala et al., 2007). In mammals, rotenone treatment inhibits mitochondrial complex I by blocking electron transfer to ubiquinone, which leads to superoxide production from the dissipation of electrons from complex I and oxidative damage to cell components (Kussmaul and Hirst, 2006). Chronic exposure of rodents to rotenone causes Parkinson-like degenerative syndrome, suggesting a link between this disease and complex I function (Betarbet et al., 2000). We used rotenone treatment on Arabidopsis cell culture to understand the short-term effects of complex I inhibition in plants (Garmier et al., 2008). A transitory decrease in respiration was observed immediately following the treatment, but a return to pretreatment steady-state levels was observed within a few hours. The glycolytic activity associated with mitochondria (Giegé et al., 2003) was lost and tricarboxylic acid (TCA) cycle activity was altered, as shown by the accumulation of many intermediates (Garmier et al., 2008). These data demonstrated that short-term inhibition of complex I caused a remodeling of metabolism.

In order to study the long-term metabolic adaptations resulting from lowering the phosphorylating efficiency of respiration, we have studied an Arabidopsis mutant lacking NDUFS4 (the 18-kD subunit of complex I). This mutant shows Suc-sensitive germination, delayed growth, a modified respiration pathway, and altered stress responses. The lack of complex I has no major influence on the mitochondrial proteome or transcriptome but leads to a lowering of growth-related nuclear transcripts and clearly influences central metabolism, with strong differences between night and day. These results indicate that complex I plays an important role in energy production and the control of metabolite levels, especially at night, and the responses to its absence are consistent with altered adenylate control of cellular metabolism.

	RESULTS

TOP ABSTRACT RESULTS DISCUSSION CONCLUSION MATERIALS AND METHODS LITERATURE CITED

 

ndufs4 Lacks Complex I and Has a Small Plant Phenotype That Is Recovered by Complementation

Screening of the T-DNA Express database (http://signal.salk.edu/cgi-bin/tdnaexpress) for insertions within exons of nuclear genes encoding complex I subunits in Arabidopsis revealed a mutant from the Syngenta collection (Sessions et al., 2002), SAIL_596_E11, containing a T-DNA inserted in the first exon of the NDUFS4 gene (At5g67590). We obtained plants homozygous for the insertion as well as wild-type plants (ecotype Columbia [Col-0]) by screening plants obtained after self-pollination of heterozygous plants. We confirmed the mutation by reverse transcription (RT)-PCR, showing that transcripts covering the first exon cannot be detected (Supplemental Fig. S1). Grown under normal conditions, these plants are smaller than wild-type plants (Fig. 1A ). To confirm that the observed phenotype was a result of the insertion in NDUFS4, we complemented the homozygous mutant with a full-length cDNA of NDUFS4 expressed under the control of the 35S promoter. The complemented plant does not show the delayed-growth phenotype, indicating that it is caused by the inactivation of the NDUFS4 gene (Fig. 1A). We performed western-blot analysis using a polyclonal antibody against the NDUFS4 protein to confirm the absence of NDUFS4 from a mitochondrial fraction of the mutant (Fig. 1B). Blue-Native gel electrophoresis (Schägger and von Jagow, 1991) was used to investigate the effect of the absence of NDUFS4 on complex I assembly and activity. No complex I activity was detected in the ndufs4 mutant (Fig. 1C, lane 2). In contrast, in the complemented line, complex I activity was restored to wild-type levels (Fig. 1C, lane 3).

View larger version (46K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 1. Characterization of the ndufs4 mutant. A, Image of 4-week-old plants grown under a long-day photoperiod. Comp, ndufs4 mutant complemented with a cDNA corresponding to the NDUFS4 gene. B, Western blots of mitochondrial fractions purified from Col-0 and ndufs4 plants. The mitochondrial matrix enzyme PDC-E1 is used as a loading control. C, Mitochondrial membrane complexes were separated on a Blue Native gel. Following migration, the gel was stained for complex I activity. The stars indicate the position of complex I. The activity stain on the lower part of the gel corresponds to the activity of the dehydrolipoamide dehydrogenase (E.H. Meyer, unpublished data) and can act as a loading control.

As ndufs4 plants are smaller than wild-type plants of the same age (Fig. 1A), we analyzed the growth of the mutant in more detail in order to identify if a specific developmental stage is impaired. Seeds were sown on agar plates, stratified for 2 d at 4°C, and transferred to a long-day photoperiod. The time when the different organs emerged was monitored. The ndufs4 mutant was delayed in all developmental stages of its growth (Fig. 2A ). We analyzed the nuclear mRNA pools using ATH1 GeneChip microarrays in triplicate. Only a small portion of the Arabidopsis genome is differently expressed in the ndufs4 mutant compared with the wild type (1,479 genes; P 0.05). We used MapMan (Thimm et al., 2004) with the Ath_AFFY_TAIR7 mapping file to study functional groups of genes (Supplemental Table S2). Processes involving protein metabolism (BIN 29), the cell cycle (BIN 31.3), as well as RNA metabolism (BIN 27.1, BIN 27.3, and BIN 27.4) and development (BIN 33) were significantly down-regulated. In parallel microarray experiments, similar results were obtained for a ndufa1 mutant, an insertion mutant in At3g08610, a gene encoding another complex I subunit (Supplemental Fig. S4), indicating that these transcript changes are likely due to the lack of complex I rather than the NDUFS4 subunit per se (Supplemental Table S2). These observations are in agreement with the slower growth of both ndufs4 and ndufa1 mutants.

View larger version (27K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 2. Growth analysis of the ndufs4 mutant. A, Comparison of the length of different growth stages in the ndufs4 mutant and wild-type plants (Col-0). Values are means ± SD for n = 50. B, Effect of Suc concentration on germination after 2 d. The data are expressed as percentages of germinated seeds. Means ± SD of three independent experiments are shown. Each experiment involved between 150 and 400 seeds. Comp, Complemented mutant.

ndufs4 Has an Electron Transport Chain Impairment But Wild-Type Respiratory Rate

The ndufs4 mutant is lacking a fully assembled and active complex I based on measurements of NADH-dependent reduction of nitroblue tetrazolium (NBT) in native gels (Fig. 1C). We further investigated the consequences of this mutation on the respiratory activity of the mutant. The total leaf respiration rate was not significantly modified in ndufs4, as shown by measurement of oxygen consumption of leaf discs in the dark (Fig. 3A ). As oxygen reduction is proportional to electron transfer rates, this indicates that a similar electron transfer rate is occurring through the respiratory chains of the ndufs4 mutant and wild-type plants.

View larger version (31K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 3. Characterization of the respiration of the ndufs4 mutant A, Total leaf respiration measurement in the dark (n = 4). FW, Fresh weight. B, Effect of rotenone on respiration of isolated mitochondria. The percentage of inhibition was calculated by the difference in respiration rates before and after the addition of rotenone in the medium (n = 3) when mitochondrial respiration is driven by the TCA cycle (state 3). C, Deamino-NADH oxidation capacity (n = 3) of mitochondrial membranes. D, ADP/O ratio calculated from oxygen consumed for a known addition of ADP in transitions between state 3 and state 4 (n = 3). E, ATP synthesis rate measured using luciferase from extracts of respiring isolated mitochondria. F, Capacity of the different alternative pathways (n = 3) in intact mitochondria: external, external NADH dehydrogenase; internal, internal NADH dehydrogenase (rotenone-insensitive TCA cycle substrate-dependent respiration); AOX, antimycin A-insensitive respiration. G, Western blots of mitochondrial fractions purified from Col-0 and ndufs4 plants. PDC-E1 is used as a loading control.

It is assumed that plants can survive without complex I because of the presence of alternative NADH dehydrogenases in the inner mitochondrial membrane that can complement the loss of complex I by maintaining the oxidation of matrix NADH. We measured the capacity of the internal and external alternative dehydrogenases of purified mitochondria to determine if any compensation in these rates occurred in the mutant. The capacity of the internal dehydrogenases was not affected in ndufs4, whereas the capacity of the external dehydrogenases increased by 15% (Fig. 3F). It has been previously reported in the CMSII mutant that external NADH dehydrogenase activity as well as AOX capacity are increased in isolated mitochondria (Sabar et al., 2000), even though the in vivo flux through the AOX was not increased (Vidal et al., 2007). An increased capacity could be explained by an increased activity or a larger pool of the proteins analyzed. We studied the transcript pools for components of the alternative pathway (Supplemental Table S3), enzyme capacities (Fig. 3F), and protein levels using antibodies (Fig. 3G). There was no induction of any AOX transcripts, but AOX protein is clearly more abundant in the ndufs4 mutant on a mitochondrial protein basis. Among the external NADH dehydrogenase (ND) transcripts, NDA1 was the only one clearly induced by more than 4-fold in ndufs4 (Supplemental Table S3). However, we have recently shown that this protein is dual targeted to mitochondria and peroxisomes in Arabidopsis (Carrie et al., 2008). In isolated mitochondria, NDA1 was in fact less abundant at the protein level in ndufs4 (Fig. 3G). The major external NADH dehydrogenase, NDB2, was not transcriptionally induced (Supplemental Table S3), and there was no change in protein level between Col-0 and ndufs4 (Fig. 3G).

Overall, these data suggest that internal and external dehydrogenases permit considerable flux for the electron transport chain even in the absence of complex I in ndufs4, and even though AOX protein levels are increased, the capacity of this alternative pathway is not significantly altered in ndufs4 (Fig. 3, F and G). Interestingly, the genes encoding components of the mitochondrial respiratory chain (BIN 9) are significantly down-regulated in ndufs4 (Supplemental Table S2), but this down-regulation does not correlate with lower respiratory activity on a mitochondrial protein basis or lowered respiratory rate on a leaf area basis.

Changes in the Mitochondrial Proteome in ndufs4 Are Limited to Complex I

Given that in the ndufs4 mutant complex I was absent and the respiration chain was altered, we performed a differential proteomic analysis using the fluorescence difference gel electrophoresis (DIGE) CyDye fluorophore technology in order to determine if the effects we noted in the mutant could be due to major modifications of other mitochondrial functions rather than simply the loss of complex I. Three independent experiments were run to compare Col-0 and ndufs4 mitochondrial samples, and we identified spots that were consistently decreased more than 2-fold over all experiments in the ndufs4 sample compared with the Col-0 sample (Fig. 4 ). No spots were consistently increased in abundance. The spots decreasing in abundance were excised and analyzed by liquid chromatography-tandem mass spectrometry. The identities of the corresponding proteins are summarized in Table I. Spot 3 corresponded to NDUFS4, confirming that the protein was highly reduced (below the limits of detection) in the mutant. Three spots identified, namely spots 1, 5, and 8, contained a total of four complex I subunits. Spot 7 corresponds to a chloroplastic carbonic anhydrase that is probably a contaminant of the mitochondrial preparation. We were not able to positively identify the last three proteins decreasing in abundance. These results indicate that, within the detection range of the DIGE technique, the only change in the mitochondrial proteome observed is the reduction in the abundance of complex I subunits. As the DIGE approach involves isoelectric focusing (IEF)-SDS-PAGE, this gel technique is not suitable for the visualization of highly hydrophobic proteins such as mitochondria-encoded complex I subunits. In order to determine if any feedback control of the expression of the mitochondria-encoded complex I subunits was occurring due to the absence of the fully assembled complex, we measured the relative abundance of all mitochondrial transcripts in the ndufs4 mutant by RT-PCR. The only modification of the expression of nad genes in the ndufs4 mutant is the overaccumulation of nad6 transcripts (Fig. 5 ). Similarly, there was little if any response in the transcripts for nucleus-encoded components for complex I (Supplemental Table S4). Thus, it appears that loss of complex I in ndufs4 does not lead to retrograde signals affecting the expression of nucleus-encoded complex I components and has little systematic impact on the mitochondrial proteome outside of other subunits in complex I, even though there is some measurable response in the transcript pool of a mitochondria-encoded complex I subunit.

View larger version (69K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 4. Differential gel electrophoresis of changes in the mitochondrial proteome between the ndufs4 mutant and wild-type plants. Mitochondrial proteins were bound to different fluorescent dyes: Cy2 (red fluorescence) for wild-type samples and Cy5 (green fluorescence) for the ndufs4 samples. Yellow spots, Both dyes are present in equal abundance; green spots, up-regulated spots; red spots, down-regulated spots. Three independent sets of mitochondrial isolates and a set of three gels were run and analyzed using DeCyder quantification software. Protein spots that reproducibly changed in abundance were selected for further analysis (numbered arrows; see Table I for identification). The molecular mass scale (kD) is indicated on the left, and pI values are indicated on the top.

View larger version (13K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 5. Changes in mitochondrial gene expression. Quantitative RT-PCR was performed to estimate the abundance of mitochondrial transcripts for the nad genes in the ndufs4 mutant and wild-type plants. Data are expressed with a log2 scale as the ratio of ndufs4 to Col-0 signal (n = 3).

In order to understand the cellular response to the modified respiration in the ndufs4 mutant, we analyzed the abundance of major metabolites using gas chromatography-mass spectrometry (GC-MS). Leaves from 6-week-old plants were harvested at the end of the night and at the end of the day, and the metabolites were extracted and analyzed. Figure 6A shows two-dimensional principal components analyses (2D PCA) of these data for Col-0, ndufs4, and the complemented line (fold changes and P values are given in Supplemental Table S5). This shows that the major variance in the overall metabolome was in the ndufs4 genotype at night and that this variance was eliminated in the complemented line. Two additional experiments were performed using leaves from 4-week-old plants during two successive nights, and the metabolome data were compared during each night for Col-0, ndufs4, and ndufa1. Again, the 2D PCA plots show clear separation of the genotypes (Fig. 6, B and C). The differences between the mutants on the two successive nights were largely the fold differences observed in metabolites (fold changes and P values are given in Supplemental Table S6). As there is some variation between experiments in the fold changes of specific metabolites, we have sought to combine the data by exploring the lists of compounds with the largest loadings in the first and second components that account for 40% to 70% of the variation in each experiment. The tabulated list is presented in Figure 6D. The accumulation of organic acids and amino acids was pronounced and is consistent with an alteration of central metabolism. Notable among the amino acids higher at night are substrates for mitochondrial respiration, and their oxidation bypasses complex I of the respiratory chain. The branched chain amino acids (Leu and Val) accumulate during the night, and their degradation transfers electrons directly to ubiquinone via the electron transfer flavoprotein (Ishizaki et al., 2006). Transcripts for a number of the components of this branched chain amino acid degradation pathway are induced in ndufs4 (Supplemental Table S2). The accumulation of organic and amino acids suggests no shortage of substrate for glycolysis; indeed, a higher flux may operate as glycolysis and the TCA cycle are freed up from adenylate control by the lower OXPHOS efficiency in ndufs4.

View larger version (20K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 6. Metabolite changes in the ndufs4 and ndufa1 mutants predominate at night. A, 2D PCA displays of the GC-MS metabolomic data sets (Supplemental Table S5) from Col-0, ndufs4, and the complemented (comp) line during the day and the night (6-week-old plants). B and C, 2D PCA displays of the GC-MS metabolomic data sets (Supplemental Table S6) from Col-0, ndufs4, and ndufa1 during two successive nights (4-week-old plants). Data for four to five plants are shown, and genotype/treatment separations from the wild type are shown by the hatched boxes. D, The 20 metabolites most important for the variance in each data set were identified from PC1/PC2 component weights. Ranges of the ratios of abundance between the wild type and ndufs4/ndufa1 mutants are shown for all metabolites that appeared in these lists in at least two out of three experiments (combined from Supplemental Tables S5 and S6).

View larger version (20K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 7. Altered adenylate levels in ndufs4. A, ATP content. B, ADP content. C, ATP/ADP ratio. Data are expressed as means of three biological replicates. Asterisks indicate significant differences (P < 0.05) between Col-0 and ndufs4 or the complemented (Comp) line. FW, Fresh weight.

From our microarray data, a large set of transcripts for photosynthesis (BIN 1) are significantly up-regulated (Supplemental Table S2). Modification of photosynthetic activity has been reported in the tobacco (Nicotiana tabacum) complex I mutant, CMSII (Dutilleul et al., 2003a). Thus, loss of mitochondrial complex I does appear to have some retrograde action that influences nuclear gene expression of some plastid functions. Investigating this further in ndufs4, we found that subgroups of genes involved in photosynthesis responded differently: genes involved in the light reactions (BIN1.1) were significantly up-regulated, whereas the expression of genes involved in photorespiration (BIN1.2), the Calvin cycle (BIN1.3), and the reductive pentose phosphate cycle (BIN1.4) was not significantly changed. Analysis of transcription from the chloroplast genome showed no major modification of the expression of chloroplast genes, and overall the plastid transcription seems to be slightly down-regulated in ndufs4 compared with the wild type (Supplemental Fig. S2). We looked at the abundance of some proteins involved in the light reactions of photosynthesis by western-blot analysis of cellular fractions. No visible differences at the protein level were observed between the ndufs4 mutant and the Col-0 control (Fig. 8A ).

View larger version (32K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 8. Impact of the ndufs4 mutation on photosynthetic proteins and photosynthesis. A, Analysis of the protein abundance of chloroplast proteins by western blot on whole cell fractions. PC, Plastocyanin; LHCB5, light-harvesting complex subunit B5; Cyt b6, cytochrome b6; PsbA, PSII subunit A; PsaA, PSI subunit A; PCOR, protochlorophyllide oxidoreductase. B, Plants were grown for 4 weeks at 22°C, 12 h of light and dark, under 120 µE m–2 s–1 light. Graphs represent the variation of quantum efficiency () of photochemical energy dissipation (PSII), light-dependent thermal dissipation (NPQ), light-independent thermal dissipation, and fluorescence energy dissipation (f,D) over a range of light intensities. White circles, Col-0; gray squares, ndufs4. The stars indicate statistically significant differences using Student's t test (P < 0.05).

Impact of ndufs4 on Stress Tolerance

The microarray analysis showed that the expression of the stress-related genes (BIN 20) was significantly increased (Supplemental Table S2), and the metabolite analysis shows elevation of the antioxidant ascorbate and the osmoprotectant compounds putrescine and Pro (Supplemental Tables S5 and S6). The in situ NBT staining technique was used to confirm increased superoxide production in ndufs4 that was observed in other complex I mutants, including CMSII (Dutilleul et al., 2003b), and in a point mutation in the same gene in Arabidopsis, fro1 (Lee et al., 2002; Fig. 9A ). This increased NBT staining is indicative of either increased superoxide production or altered antioxidant defense enzymes in the mutant. To determine if the stress tolerance was altered, we performed a series of whole plant stress assays to monitor the behavior of the ndufs4 mutant and the complemented line under three different stresses: cold, salt, and osmotic stress. The root length was measured and compared with control plants grown under nonstressed conditions. The percentage of growth inhibition by the stress treatment was then measured. The growth of the ndufs4 roots was less inhibited under cold, osmotic, or moderate salt stress (Fig. 9B), suggesting some form of stress tolerance. Under high salt concentrations, the ndufs4 mutant behaved like wild-type plants. In all cases, the complemented line was indistinguishable from Col-0.

View larger version (60K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 9. Stress tolerance of the ndufs4 mutant. A, NBT stain for superoxide in leaves. Three examples are shown for each ecotype, and the average amount of superoxide was estimated by quantifying the coloration (n = 20). B, In vitro analysis of root growth under stress conditions. Data are expressed as the ratio between the root length of plants grown under control conditions and those of plants grown under stress conditions (n = 20). Comp, Complemented mutant. C, Drought stress assay in individual pots. After 10 d of withholding water from 40-d-old plants, the viability was assessed visually (Exp. 1; a representative image is shown) and by monitoring chlorophyll fluorescence (Exp. 2). D, Drought stress assay with plants staggered (the mutant was sown 10 d before Col-0) and grown in the same pot under normal conditions. The last watering occurred at day 28 after transfer to soil. A photograph was taken every 3 d, and the soil water content was measured.

	DISCUSSION

TOP ABSTRACT RESULTS DISCUSSION CONCLUSION MATERIALS AND METHODS LITERATURE CITED

 
When the nonphosphorylating pathways of plant respiration were first identified, their most intriguing characteristic was considered to be decreased efficiency of phosphorylation, because this was seen as such a pivotal factor in animal respiration and respiratory disease research (Gellerich et al., 2004). Lowered efficiency was also seen as a wasteful process; hence, elimination of the nonphosphorylating pathways in plants was for a time seen as desirable. The potential for AOX to lower phosphorylation efficiency and enable increased flux through glycolysis and the TCA cycle for providing carbon skeletons for biosynthesis without the stricture of adenylate control was the first general role proposed for this bypass (Lambers, 1982). However, the stress induction of nonphosphorylating pathways and the potential of AOX to limit ROS production from the ubiquinone pool has dominated the study of this nonphosphorylating pathway for many years.

Recently, it was shown that knockout of Aox1a leads to stress sensitivity in high light and drought in Arabidopsis and a stress-induced accumulation of sugars and depletion of organic and amino acids compared with the wild type (Giraud et al., 2008). This suggested a constriction of primary metabolism in the absence of AOX, which is consistent with the concept of nonphosphorylating respiration as a loosener of adenylate restriction on metabolism. In this study, we have characterized an insertion mutant in the ndufs4 gene and have shown that this plant lacks a fully assembled and active complex I. However, it exhibits few other significant changes in mitochondrial composition or respiratory function. Thus, the additional responses observed are likely to be primarily due to the lack of proton translocation by complex I and a concomitant lowering of phosphorylating efficiency rather than a restriction on respiratory rate. In this mutant, the same photosynthesis-derived organic acids will yield approximately one-third less ATP during their oxidation to drive growth and maintenance operations, and consistent with this, there were significant and dynamic alterations of the ATP and ADP pools in ndufs4 (Fig. 7; Supplemental Tables S5 and S6). The mutant exhibits a slower growth rate at all stages of development, and many of the transcripts for housekeeping functions (RNA and protein metabolism, cell cycle) are decreased in abundance, indicating a slower pace of cellular function. This growth delay has also been observed in other characterized plant complex I mutants, such as the CMSII tobacco mutant (Gutierres et al., 1999) and the Arabidopsis ca2 (Perales et al., 2005), otp43 (de Longevialle et al., 2007), and fro1 (Lee et al., 2002) mutants.

Delayed Germination and the Impact of Sugars and GA

We have shown that the germination of the ndufs4 mutant is affected. Germination is the transition from a dormant stage during which the metabolic activity is kept to its minimum to a stage of highly active cell division and expansion, requiring efficient energy production. In a dry seed, mitochondria are barely functional, but during the very early stages of germination, mitochondria are transformed into a mature active form (Howell et al., 2006). During the first few hours, they are mainly powered by external alternative dehydrogenases (Logan et al., 2001) to allow the import of energy-producing components such as the TCA cycle enzymes or the respiratory chain complexes (Howell et al., 2006). It could be predicted that a complex I mutant should not be affected at this stage of germination. Once the mitochondria are functional, the embryonic cells start to rapidly divide and expand. These energy-requiring processes are more likely to be affected in mutants lacking complex I, and this would explain why ndufs4 germination and early seedling growth are delayed. This is confirmed by the facts that mature seeds are not accumulating ATP and that ATP concentration increases during the early stages of germination (Perl, 1986). The mutant's germination is also inhibited at high Suc concentrations. This has also been observed in the fro1 mutant (Lee et al., 2002) and in the css1 mutant, which is affected in the splicing of nad4 (Nakagawa and Sakurai, 2006). There is a strong relationship between sugar and abscisic acid (ABA) signaling, as many Suc-insensitive mutants are unable to synthesize or insensitive to ABA (Dekkers et al., 2008). We have shown that external GA is able to complement the sugar sensitivity of the ndufs4 mutant; thus, we can postulate that this phenotype arises from the mutant being either more sensitive to ABA or less sensitive to GA. Early studies of Brassica napus germination and its control by ABA clearly show the correlation between respiration rate, ATP content, and the inhibitory influence of ABA (Schopfer and Plachy, 1984). While the causative factor in these correlations is not known, lowered ATP synthesis in ndufs4 would be consistent with slower germination and higher ABA (that could be overcome by GA-induced germination, as was observed). Interestingly, a relationship between GA synthesis and impaired respiration has been postulated in the CMSII mutant but in a different context. Under low-nitrogen conditions, which enhanced levels of GA, the CMSII mutant has a similar phenotype to wild-type plants (Pellny et al., 2008), while under normal nitrogen nutrition and with lower GA, a delayed growth phenotype was observed (Gutierres et al., 1997; Pellny et al., 2008). These data suggest that GA signaling or ABA depletion is partially impaired in mutants lacking complex I and that efficient ATP production by respiration is crucial for rapid germination.

Effects on Photosynthesis

In the ndufs4 mutant, the expression of nuclear genes encoding proteins needed for the light reactions of photosynthesis is significantly up-regulated, and while no effect could be shown at the protein level, fluorescence measurements suggest impaired photochemical efficiency. In the CMSII mutant, photosynthesis is reduced by 20% to 30% under normal conditions, but this phenomenon remains unexplained, as photosynthetic capacity, stomatal parameters, and O₂ sensitivity are normal in the mutant (Dutilleul et al., 2003a). Interestingly, induction of photosynthetic genes has been shown previously in Chlamydomonas when the mitochondrial respiratory chain is inhibited (Matsuo and Obokata, 2006), whereas we have previously shown that there was an early transcriptional decrease in photosynthetic light reaction gene expression in response to rotenone inhibition (Garmier et al., 2008).

The up-regulation of photosynthetic light reaction gene expression in ndufs4 could be explained by a higher light sensitivity of the photosynthesis apparatus in the ndufs4 mutant. Consistent with this, we noted that genes encoding elements for signaling by light (BIN 30.11) are up-regulated in ndufs4 (Supplemental Table S2) and that the mutant has a "curly leaf" phenotype that is stronger when plants are grown in a long-day photoperiod than in a short-day photoperiod (Supplemental Fig. S3). The overexpression of genes encoding PSII subunits could be a response to a higher light sensitivity. PSII is the protein complex with the highest turnover in plants, and its subunits, especially D1, have to be synthesized continuously to replace photodamaged components. As metabolites known to act in shuttling reducing equivalents from the chloroplast to the mitochondria accumulated in the mutant (e.g. malate used in the malate-oxaloacetate shuttle), perhaps impaired metabolite shuttling from the chloroplast to the mitochondria may be inducing a stress on photosynthetic activity in the mutant. Alternatively, the change in photosynthetic gene transcription may reflect the alterations to mitochondrial function and not any change in the chloroplast. The effect of mitochondrial defects on retrograde signals that can modulate chloroplast gene expression has been observed previously in AOX mutants (Giraud et al., 2008).

There is no apparent photorespiratory blockage at Gly decarboxylase in ndufs4, as Gly levels are not significantly higher than in the wild type in the day (Supplemental Tables S5 and S6). Such a block might be expected given the high rate of NADH production in the mitochondrial matrix and the need for the mitochondrial electron transport chain to oxidize this pool. Notably, deletion of AOX did cause a clear accumulation of Gly and a decrease in Ser (Giraud et al., 2008), showing that loss of the nonphosphorylating components of ETC limits photorespiration but the loss of the classical proton-pumping complex I does not.

Consequences on Respiration at Night

The measurement of respiratory activity in leaves kept in the dark showed no change in oxygen uptake (Fig. 3A), but as the ATP level was lowered in the mutant at the end of the night, this was likely to be occurring with lower phosphorylation efficiency and hence yielding less ATP for growth and maintenance of plants at night. Such conditions may allow a Pasteur effect and elevated glycolytic activity, providing substrate-level phosphorylation to supplement the ATP pool generated by OXPHOS but also leading to higher levels of carbon intermediates requiring respiration. As the rate of respiration did not increase, these would be expected to accumulate; consistent with this scenario, amino acids derived from the convergence of glycolysis and the pentose phosphate pathway in the shikamate pathway (Tyr and Phe) and TCA cycle intermediates were seen to accumulate. Two studies have previously sought to understand the consequences of complex I loss through a broad analysis of metabolite levels: the treatment of Arabidopsis cell culture by rotenone (Garmier et al., 2008) and the characterization of a natural complex I mutation in tobacco (Dutilleul et al., 2005). The results obtained in these studies were starkly different. After inhibition of respiration in Arabidopsis cells by rotenone, the amino acid pools decreased, glycolysis became disconnected from the mitochondria, and there was an activation of cytoplasmic pathways such as fermentation (Garmier et al., 2008). In the CMSII mutant from tobacco, an accumulation of amino acids was observed (Dutilleul et al., 2005).

Our study shows a strong accumulation of amino acids and is in accordance with the CMSII tobacco data, suggesting that the effects of complex I mutations in different species show more similarity to each other than do comparisons of short-term and long-term inhibition studies in the same species. Our metabolomic study shows that the abundance of many more metabolites is significantly changed at night than during the day in both ndufs4 and ndufa1 lines. This observation highlights the important role of mitochondrial respiration in controlling metabolic fluxes at night and the masking of many of the effects of complex I loss during photosynthesis in the day period.

Stress Responses in ndufs4

The T-DNA insertion studied in this report is in the same gene as an ethyl methanesulfonate mutant, fro1, characterized from a screen for plants showing reduced cold induction of stress-responsive genes (Lee et al., 2002). This mutant was named frostbite1 due to a leaf phenotype resembling leaves after freezing (Lee et al., 2002). While we were unable to reproduce this leaf phenotype here in the T-DNA insertion mutant ndufs4, the lack of cold inhibition of root growth we note may be linked to the suggestion by Lee et al. (2002) that cold induction of nuclear gene expression is modulated by mitochondrial function through complex I function. This study and the fro1 mutant thus link mitochondrial respiration, especially changes in complex I activity, with lack of response to environmental changes. Similarly, the CMSII mutant has a higher tolerance to ozone and Tobacco mosaic virus (Dutilleul et al., 2003b), and the ccs1 mutant is more resistant to an inhibitor of cellulose synthesis (Nakagawa and Sakurai, 2006). The ndufs4 mutant has a higher tolerance of cold, osmotic, and moderate salt stress based on root growth assays and shows significant induction of stress-related transcripts (Supplemental Table S1) and metabolites such as Pro and putrescine. The mutant will thus be predisposed to cope with a stress and might not be as affected as the wild type. Taken together, these data clearly indicate that mutants with decreased OXPHOS are more tolerant to moderate stresses.

	CONCLUSION

TOP ABSTRACT RESULTS DISCUSSION CONCLUSION MATERIALS AND METHODS LITERATURE CITED

 
We have shown that the loss of one subunit of complex I can remove complex I function without significant changes in other mitochondrial functions, and we investigated the wider effects of this loss on nuclear and organellar transcript pools and the cellular metabolome. We have described what are, to our knowledge, new phenotypes for complex I mutants such as exogenous GA-stimulated germination and root growth tolerance to abiotic stresses. Overall, we show that the efficiency of ATP production by OXPHOS is lowered in ndufs4 but that this can be tolerated in Arabidopsis through broad rearrangements in cellular metabolism and development, which lead to altered tolerance to moderate abiotic stresses. This constitutive decreased efficiency of phosphorylation gives us insights into the value of the transient modulation of phosphorylation efficiency afforded to plants through the dynamic up-regulation of nonphosphorylating respiratory bypasses during abiotic stress (Clifton et al., 2005) and even during the diurnal cycle (Escobar et al., 2004) that are consistent with the decreased stress tolerance and lowered metabolic pools of knockouts of nonphosphorylating pathways (Giraud et al., 2008).

	MATERIALS AND METHODS

TOP ABSTRACT RESULTS DISCUSSION CONCLUSION MATERIALS AND METHODS LITERATURE CITED

 

Plant Growth

Arabidopsis (Arabidopsis thaliana) seeds were surface sterilized in a solution containing 70% (v/v) ethanol and 0.1% (v/v) Tween 20 for 5 min, washed first in 70% (v/v) ethanol and then in 100% (v/v) ethanol, dried, and plated onto plates of 0.5x Gamborg B5 medium, 1% (w/v) Suc, and 1% (w/v) agar. Plates were cold stratified at 4°C for 2 d. Two-week-old seedlings were transferred on soil and grown in growth chambers under a long-day photoperiod of 16 h of light (150 µE cm^–2, 22°C) and 8 h of dark (18°C). Plants used for isolation of mitochondria were grown under a short-day photoperiod (8 h of light and 16 h of dark). Plants used for metabolite extraction were grown under a medium-day photoperiod (12 h of light and 12 h of dark).

Transcript Analysis

Total RNA from leaves harvested in the middle of the light period was extracted using the plant RNeasy kit (Qiagen), and genomic DNA was removed by two DNase treatments using RNase-free DNase (Ambion). Complete removal of both mitochondrial and nuclear DNA was checked by PCR on diluted RNA. Microarray ATH1 chip hybridizations were conducted following Affymetrix instructions. All of the experiments were done on three biological replicates. Microarray data analysis was conducted using AVADIS software (Strands). Arrays were normalized using GC-RMA. A stringent false discovery rate correction was applied to P values when individual fold changes were studied (Nettleton, 2006) but not when genes were studied in functional groups. The latter tests were conducted using MapMan (Thimm et al., 2004; http://gabi.rzpd.de/projects/MapMan/) with the Ath_AFFY_TAIR7 mapping file. A Benjamini-Hochberg correction was applied to the P values calculated by the Wilcoxon rank sum test. Primary data are available at Array Express (www.ebi.ac.uk/microarray/) as E-MEXP-1967 for ndufs4 and E-MEXP-2178 for ndufa1; P < 0.05 data sets are provided in Supplemental Data S1.

Organellar Transcript Analysis

Quantitative RT-PCR was performed using a Roche LightCycler 480 Real Time PCR system as described previously (de Longevialle et al., 2008). The mitochondrial transcriptome analysis was conducted in the same way as the chloroplastic transcriptome analysis, except that primers from Supplemental Table S7 were used.

Isolation of Mitochondria from Arabidopsis Plants

The aerial parts of plants grown under a short-day photoperiod were used as starting material for isolation of mitochondria. Plants were ground at 4°C in extraction buffer (0.3 M Suc, 5 mM tetrasodium pyrophosphate, 10 mM KH₂PO₄, pH 7.5, 2 mM EDTA, 1% [w/v] polyvinylpyrrolidone 40, 1% [w/v] BSA, 5 mM Cys, and 20 mM ascorbic acid) using a Polytron (40 mL of buffer for 10 g of plants, three bursts of 10 s, speed 4). The homogenate was centrifuged for 5 min at 3,000g, and the supernatant was centrifuged for 10 min at 20,000g. The pellet was resuspended in wash buffer (0.3 M Suc, 1 mM EGTA, and 10 mM MOPS/KOH, pH 7.2) and subjected to the same low-speed (3,000g) and high-speed (20,000g) centrifugations. The pellet was then resuspended in a small volume of wash buffer and loaded on top of a Percoll step gradient (from bottom to top: 1 volume of 50%, 5 volumes of 25%, and 1 volume of 18% Percoll in wash buffer, equivalent to 20 g of plant loaded per gradient). The gradient was centrifuged at 40,000g for 45 min. The fraction located at the interface between the 50% and 25% layers was collected and washed three times in wash buffer. The mitochondrial suspension was divided into aliquots and stored at –80°C.

Measurements of Oxygen Consumption

Oxygen consumption was measured using a Clark-type oxygen electrode (Hansatech Instrument). Respiration on whole Arabidopsis leaves was performed in the dark at 25°C by adding leaf discs (between 15 and 25 mg fresh weight) in the chamber containing 1 mL of distilled water. Respiration rates on isolated mitochondria were determined at 25°C on 100 µg of mitochondrial proteins suspended in 1 mL of respiration buffer (0.3 M Suc, 5 mM KH₂PO₄, 10 mM TES, 10 mM NaCl, 2 mM MgSO₄, and 0.1% [w/v] BSA, pH 6.8). Different substrates, cofactors, and inhibitors were successively added to the reaction medium to modulate oxygen consumption by mitochondria. Complex I inhibition was measured in the presence of Glu (10 mM), malate (10 mM), CoA (12 µM), TPP (0.2 mM), NAD⁺ (2 mM), and ADP (0.3 mM) in order to initiate electron transport through the TCA cycle. Rotenone (5 mM) was then added. The fraction of rotenone-insensitive respiration was calculated by the ratio of the rates after and before rotenone addition and expressed as the percentage of respiration inhibition. Complex I activity was measured on mitochondrial membranes obtained after freezing/thawing of the mitochondria, 1 mM deamino-NADH was added to the chamber, and oxygen consumption measured. Rotenone (5 mM) was then added. The capacity of internal NADH dehydrogenases was measured in the presence of Glu (10 mM), malate (10 mM), CoA (12 µM), TPP (0.2 mM), NAD⁺ (2 mM), ADP (0.3 mM), and rotenone (5 mM). n-Propylgallate (0.5 mM) and KCN (1 mM) were then added to inhibit the terminal oxidases and stop the reaction. The capacity of mitochondria to use external NADH was measured by addition of rotenone (5 mM), NADH (1 mM), CaCl₂ (0.1 mM), ADP (0.3 mM), and ATP (0.5 mM). nPG (0.5 mM) and KCN (0.1 mM) were added to stop the reaction. The maximal capacity of AOX was measured in the same buffer but at pH 7.2 in the presence of succinate (10 mM) and ATP (0.5 mM) and after successive additions of the complex III inhibitor myxothiazol (2.5 µM) and the AOX activators pyruvate (10 mM) and dithiothreitol (DTT; 5 mM). Finally, the AOX inhibitor nPG (0.5 mM) was added. The ADP/O ratio was measured when mitochondrial respiration was run through the TCA cycle (state 3) in the presence of Glu (10 mM), malate (10 mM), CoA (12 µM), TPP (0.2 mM), and NAD⁺ (2 mM). State 4 was reached by the addition of ADP (200 µmol), and the amount of oxygen consumed during state 4 was monitored and used to calculate the ADP/O ratio by dividing 200 (the amount of ADP) by two times the amount of oxygen consumed. Mitochondrial integrity was measured following oxygen uptake after addition of ascorbate (10 mM), cytochrome c (25 µM), and Triton X-100 (0.05%, w/v). In all experiments, it was consistently better than 90%.

Measurements of Adenylate Concentrations

Production of ATP by isolated mitochondria was measured using the ATP Bioluminescent Assay Kit (Sigma). Mitochondria were incubated in respiration buffer containing Glu (10 mM), malate (10 mM), CoA (12 µM), TPP (0.2 mM), NAD⁺ (2 mM), and ADP (1 mM) for exactly 10 min. Then, TCA was added to a final concentration of 2.3% (v/v). After centrifugation for 15 min at 20,000g, the supernatant was used for ATP production estimation. To extract adenylates, frozen leaves (about 80 mg) were ground and resuspended in 500 µL of 2.3% (v/v) TCA. After centrifugation for 15 min at 20,000g, the supernatant was recovered and neutralized using a few drops of 2.5 M K₂CO₃. Adenylates were measured according to Ford and Leach (1998) using the ATP Bioluminescent Assay Kit (Sigma).

Protein Overexpression and Antibody Production

A cDNA encoding for the C-terminal part of the NDUFS4 protein (E37-N154) was cloned in the Gateway entry vector pDONR207 (Invitrogen) and transferred to the destination vector pDEST15 (Invitrogen), which allows the expression of the chimeric protein glutathione S-transferase::NDUFS4. This protein was overexpressed in Escherichia coli BL21 pLysS cells and purified on glutathione S-transferase-Sepharose. The purified protein was injected into a rabbit (four doses of 250 µg). The serum was used unpurified in western-blot experiments.

One-Dimensional SDS-PAGE and Immunodetection

Mitochondrial proteins (20 µg) were solubilized in sample buffer (2% SDS, 125 mM Tris-HCl, 10% glycerol, 10% β-mercaptoethanol, and 0.002% bromphenol blue, pH 6.8) and heated at 95°C for 5 min. The fractions were loaded on 12% (w/v) polyacrylamide/0.1% (w/v) SDS gels. For immunodetection, separated proteins were transferred onto a polyvinylidene difluoride membrane (Immobilon-P; Millipore) and incubated with the primary antibody. A secondary antibody linked to horseradish peroxidase was used, and the signal was detected by chemiluminescence (GE Healthcare). The image was recorded using a Luminescent Image Analyser (LAS 100; Fuji). The list of antibodies used is given in Supplemental Table S1.

Blue Native-PAGE and Complex I Activity Assay

Blue Native-PAGE was performed according to the method described by Jänsch et al. (1996). Mitochondrial proteins (200 µg) were solubilized with dodecyl maltoside (1% [w/v] final) in ACA buffer (750 mM amino caproic acid, 0.5 mM EDTA, and 50 mM Tris-HCl, pH 7.0) and incubated for 20 min at 4°C. The samples were centrifuged for 10 min at 20,000g, and Serva Blue G (0.2% [v/v] final) was added to the supernatant. The samples were loaded onto a 4.5% to 16% gradient gel. Gels were directly used for in-gel complex I activity assay according to Zerbetto et al. (1997). The gel was washed three times for 5 min with distilled water and incubated in the reaction medium (0.14 mM NADH, 1.22 mM NBT, and 0.1 M Tris-HCl, pH 7.4). When the dark blue stain was strong enough, the reaction was stopped by transferring the gel to 40% methanol/10% acetic acid (v/v).

2D DIGE

Mitochondrial proteins from control plants (Col-0) and ndufs4 plants were precipitated overnight at –20°C in 100% (v/v) acetone. After centrifugation at 20,000g and 4°C for 20 min, pellets were resuspended in 10 µL of DIGE lysis buffer (8 M urea, 4% [w/v] CHAPS, and 40 mM Tris, pH 8.5) and centrifuged again at 12,000g and 4°C for 10 min in order to remove insoluble material. Fifty micrograms of proteins from each sample was labeled with a different Cy dye (Cy-3 or Cy-5) by addition of 400 pmol of dye (freshly prepared in dimethylformamide according to the manufacturer's instructions) on ice in the dark for 30 min. The reaction was stopped by addition of Lys (10 mM) for 10 min on ice in the dark. An equal volume (12 µL) of DIGE lysis buffer with 22 mM DTT was added to each sample. Each of the labeled protein samples was mixed, and rehydration buffer (8 M urea, 4% [w/v] CHAPS, 0.5% [v/v] 3–10 nonlinear immobilized pH gradient buffer, 18 mM DTT, and 0.001% [w/v] bromphenol blue) was added to give a final volume of 450 µL. The mix was loaded onto a 24-cm-long strip with immobilized nonlinear pH gradient of 3 to 10 (Immobiline DryStrip; GE Healthcare). Rehydration of the strips and the first IEF dimension electrophoresis were performed on an IPGphor unit (GE Healthcare) using the following settings: 12 h at 30 V (rehydration step), 1 h at 500 V, 1 h gradient from 500 V to 1,000 V, 1 h gradient from 1,000 V to 3,000 V, 2 h gradient from 3,000 V to 8,000 V, and 5 h at 8,000 V. After IEF, strips were incubated for 15 min in an equilibration buffer (6 M urea, 2% [w/v] SDS, 26% [v/v] glycerol, 65 mM DTT, 0.001% [w/v] bromphenol blue, and 50 mM Tris-HCl, pH 8.8) and then for 15 min in an equilibration buffer containing iodoacetamide (6 M urea, 2% [w/v] SDS, 26% (v/v) glycerol, 135 mM DTT, 0.001% [w/v] bromphenol blue, and 50 mM Tris-HCl, pH 8.8). The equilibrated strips were then loaded on top of a 12% (w/v) acrylamide gel. Following separation, gels were scanned using the Typhoon Trio Variable Mode Imager at a resolution of 100 (pixel size) with the photomultiplier tube set to 500 V. Proteins were processed (quantification) using the DeCyder 2-D Differential Analysis software version 6.5 (GE Healthcare). In order to get statistical significance from these experiments, three sets of proteins from three independent experiments were labeled and submitted to electrophoresis. Standard gels were also performed, and precipitation, IEF, and SDS-PAGE were run in parallel with labeled samples. These standard gels were loaded with a mix of 150 µg of each protein sample. After electrophoresis, proteins were visualized by colloidal Coomassie Brilliant Blue (G250) staining. The aim of the standard gel is to allow identification of proteins by excision gel spots followed by mass spectrometry.

Identification of Proteins by Liquid Chromatography-Tandem Mass Spectrometry

Gel spots to be analyzed were cut from colloidal Coomassie Brilliant Blue-stained gels. Proteins were digested with trypsin (trypsin sequencing grade; Roche Diagnostic) according to Sweetlove et al. (2001). Prior to mass spectrometry, peptides were resuspended in 5% acetonitrile/0.1% formic acid. The samples were analyzed with an Agilent 1100 series capillary liquid chromatography system and an Agilent Technologies XCT Ultra IonTrap with an electrospray ionization source equipped with a low-flow nebulizer in positive mode controlled by Chemstation (Rev B.01.03 [204]; Agilent Technologies) and MSD Trap Control version 6.0 (Build 38.15) software (Bruker Daltonik). Samples were loaded with an Agilent 1100 series capillary liquid chromatography system onto a 0.5- x 50-mm C18 (5 µm, 100 Å) reverse-phase column (Higgins Analytical) with a C18 OPTI-GUARD guard column (Optimize Technologies) at 10 µL min^–1 equilibrated with 5% acetonitrile and 0.1% formic acid under a regulated temperature of 50°C. Peptides were eluted from the C18 reverse-phase column at 10 µL min^–1 into the XCT Ultra by a 9-min acetonitrile gradient (5%–60%) in 0.1% formic acid at 50°C. Initial ion detection utilized a mass range of 200 to 1,400 mass-to-charge ratio (m/z) with a scan mode set to 8,100 m/z per second. Ions reaching an intensity of 80,000 cps were sent to tandem mass spectrometry (MS/MS) analysis, and two precursors were selected for the initial MS scan. MS/MS conditions employed SmartFrag for ion fragmentation (scan range 70–2,200 m/z). The resulting MS/MS spectra were exported from the Data Analysis for LC/MSD Trap version 3.3 (Build 149) software package (Bruker Daltonik) using default parameters for AutoMS(n) and compound Export. For protein identification, data generated from MS/MS spectra were matched against The Arabidopsis Information Resource (release 8) Arabidopsis database using the Mascot search engine (Matrix Sciences). Searches were conducted at parameters set at error tolerances of ±1.2 for MS and ±0.6 for MS/MS; "Max Missed Cleavages" were set to 1. Results were filtered using "Standard scoring," "Max. number of hits" set to 20, and "Significance threshold" at P < 0.05.

Metabolite Extraction and GC-MS Analysis

Frozen leaves (approximately 100 mg) were ground to a fine powder (without thawing) in a ball mill and extracted with metabolite extraction medium (85% [v/v] HPLC-grade methanol [Sigma], 15% [v/v] untreated MilliQ water, and 100 ng µL^–1 ribitol) for 15 min at 65°C with 1,400 rpm shaking. Tubes were centrifuged for 10 min at 20,000g and 4°C in order to pellet cell debris. Supernatants (50 µL) were dried in a speed vac system. Prior to GC-MS analysis, a first derivatization was performed by addition of 20 µL of methoxyamine hydrochloride (stock solution of 20 mg mL^–1 in pyridine) on the dry metabolite pellet and incubation for 90 min at 30°C with shaking (1,400 rpm). A second derivatization was performed by addition of 30 µL of N-methyl-N-(trimethylsilyl)trifluoroacetamide (Sigma-Aldrich) and incubation for 30 min at 37°C with shaking (1,400 rpm). Ten microliters of a retention time standard mixture (0.29% [v/v] n-dodecane, 0.29% [v/v] n-pentadecane, 0.29% [w/v] n-nonadecane, 0.29% [w/v] n-docosane, 0.29% [w/v] n-octacosane, 0.29% [w/v] n-dotriacontane, and 0.29% [w/v] n-hexatriacontane dissolved in anhydrous pyridine) was then added to each tube, and the samples were transferred to GC-MS vials for analysis. Metabolites were analyzed on an Agilent GC/MSD system composed of an Agilent GC 6890N gas chromatograph fitted with a 7683B Automatic Liquid Sampler and a 5975B Inert MSD Quadrupole MS Detector (Agilent Technologies). The GC apparatus was fitted with a 0.25-mm i.d., 0.25-µm film thickness, 30-m Varian FactorFour VF-5ms capillary column with 10m integrated guard column (Varian). GC-MS run conditions were essentially as described for GC-quadrupole-MS metabolite profiling on the Golm Metabolome Database Web site (http://csbdb.mpimpgolm.mpg.de/csbdb/gmd/analytic/gmd_meth.html; Kopka et al., 2005). Samples were injected into the split/splitless injector operating in splitless mode with an injection volume of 1 µL, purge flow of 50 mL min^–1, purge time of 1 min, and a constant inlet temperature of 300°C. Helium carrier gas flow rate was held constant at 1 mL min^–1. The GC column oven was held at the initial temperature of 70°C for 1 min before being increased to 76°C at 1°C min^–1 and then to 325°C at 6°C min^–1 before being held at 325°C for 10 min. Total run time was 58.5 min. Transfer line temperature was 300°C. MS source temperature was 230°C. Quadrupole temperature was 150°C. Electron impact ionization energy was 70 eV, and the MS detector was operated in full-scan mode in the range 50 to 600 m/z with a scan rate of 2.6 Hz. The MSD was pretuned against perfluorotributylamine mass calibrant using the "atune.u" autotune method provided with Agilent GC/MSD Productivity ChemStation software (version D.02.00 SP1; Agilent Technologies). Raw GC-MS data preprocessing and statistical analysis was carried out using in-house MetabolomeExpress software (version 1.0). Peak detection settings were as follows: slope threshold = 200; minimum peak area = 5,000; minimum peak purity factor = 2; minimum peak width (scans) = 5. Peak lists were then selected for library matching against an in-house library of mass spectra and Kovat's retention index information for authentic metabolite standards and "unknown" metabolites observed in biological samples. Library-matching settings were as follows: retention index (RI) window = 2 RI units; mass spectral tag centroid distance = ±1 RI unit; minimum peak area = 25,000 arbitrary peak area units; MS qualifier ion ratio error tolerance = 30%; minimum number of correct ratio qualifier ions = 2; maximum average MS ratio error = 40%. Each positively matched analyte was quantified based on a particular analyte-specific, library-specified quantifier ion. For each run, Kovat's retention indices were internally calibrated against n-alkane internal standard retention times automatically determined using supplied approximate retention times and prominent extracted ion chromatogram peaks at m/z = 85. After library matching, a complete, normalized (analyte x sample) data matrix was constructed from the library-matching report. This matrix construction process included an automated quality-control step (designed to remove technically spurious samples) to ensure that only runs with a positively identified ribitol internal standard peak with a peak area of at least 10⁶ arbitrary peak area units and with an absolute deviation from the median detected ribitol peak area that was less than 50% of that median were used. Missing signal intensity values were automatically filled (prior to normalization) by retrieving, from raw data files, the total signal of the relevant quantifier ion between the average start and stop times of peak integration of the relevant metabolite. Metabolite signal intensities were normalized to fresh tissue mass and internal standard (ribitol) peak area. Metabolite signal intensity ratios were then calculated by dividing the mean normalized signal intensity for each metabolite in ndufs4, complemented, and ndufa1 samples by its corresponding value in Col-0 samples. The statistical significance of each ratio was determined by a two-tailed Welch's t test with P < 0.05 being considered significant (n = 4–5). Tables of all the metabolites identified, their ratios between genotypes, P values, GC-MS retention times, retention indices, and quantifier ion information are given in Supplemental Tables S5 and S6. PCA were carried out on internal standard- and tissue mass-normalized data matrices filtered to exclude analytes of nonbiological origin and include only one GC-MS signal per metabolite. PCA analyses were initiated via the MetabolomeExpress interface, which uses the prcomp() function of the open-source statistical package, R (version 2.5.1), with scaling of all variables to unit variance.

Photosynthesis Measurements

Fluorescence induction kinetics at room temperature (22°C) were measured using a pulse amplitude modulation fluorometer (PAM101; H. Walz) on 32-d-old seedlings as described previously (Giraud et al., 2008). After a 30-min dark acclimation, the F_v/F_m (maximum photochemical efficiency of PSII in the dark-adapted state) was measured as (F_m – F₀)/F_m, where F_m is the maximum PSII fluorescence in the dark-adapted state and F₀ is the initial (minimum) PSII fluorescence in the dark-adapted state (Butler, 1978). Subsequent to illumination, the utilization of absorbed photons by the PSII antennae in photosynthetic electron transport and thermal dissipation was assessed from the quantum efficiency () of photochemical energy dissipation (_PSII), light-dependent (_NPQ) and light-independent thermal dissipation, and fluorescence energy dissipation (_f,D), with _f,D + _NPQ + _PSII = 1 (Hendrickson et al., 2004). Fluorescence measurements were made on four plants for each of the Col-0 and ndufs4 lines.

Root Growth Stress Assays

Surface-sterilized ndufs4 and Col-0 seeds (approximately 200 seeds each) were sown onto a 1% Suc agar plate. When the cotyledons were fully opened, individual plantlets were transferred to 1% Suc agar plates at 22°C (control), 1% Suc agar plates for 48 h at 4°C for cold stress, or 1% Suc agar plates supplemented with 100, 200, 300, or 400 mM mannitol for osmotic stress or 50, 75, 100, 125, or 150 mM NaCl for salt stress (18 plantlets per treatment) at 22°C. Plantlets were kept at long-day growth conditions in a vertical position, and root growth were measured 9 d later.

NBT Detection of Superoxide in Leaves

In accordance with a previously described method (Lee et al., 2002), leaves of 4-week-old wild-type and ndufs4 plants grown under long-day conditions were detached and incubated in a superoxide staining solution (0.1 mg mL^–1 NBT in 25 mM HEPES buffer, pH 7.6). As a control, wild-type and ndufs4 leaves were incubated in superoxide staining solution containing 10 mM MnCl₂ and 10 units mL^–1 superoxide dismutase. Leaves were left in staining solution for 2 h at room temperature in darkness. Chlorophyll was then removed from leaves via transfer to an 80% ethanol solution (70°C) for 10 min, and leaves were mounted onto glass slides in the presence of 40% (v/v) glycerol and scanned. Three leaves per plant, three genotypes per experiment, were assayed for superoxide. Each experiment was repeated three times, and representative images are shown for both experiments. Pixel densitometric analysis for determination of amounts of NBT precipitate in leaves was carried out using ImageJ.

Supplemental Data

The following materials are available in the online version of this article.

Supplemental Figure S1. RT-PCR analysis of ndufs4.

Supplemental Figure S2. Changes in chloroplast gene expression in ndufs4.

Supplemental Figure S3. Phenotype of Col-0 and ndufs4 plants under long- and short-day photoperiod.

Supplemental Figure S4. Characterization of ndufa1.

Supplemental Figure S5. Drought stress assays of Col-0, ndufs4, and ndufa1 in individual pots.

Supplemental Table S1. Antibodies and dilution used in this work.

Supplemental Table S2. Microarray analysis of ndufs4 and ndufa1.

Supplemental Table S3. Expression of the alternative pathway genes in ndufs4 and ndufa1.

Supplemental Table S4. Expression of complex I subunits in ndufs4 and ndufa1.

Supplemental Table S5. Measurements of the metabolite levels in ndufs4 and complemented line versus Col-0.

Supplemental Table S6. Measurements of the metabolite levels in ndufs4 and ndufa1 versus Col-0.

Supplemental Table S7. Primers used for quantitative RT-PCR.

Supplemental Data S1. Microarray data on ndufs4 and ndufa1 versus Col-0.

Received May 20, 2009; accepted August 10, 2009; published August 12, 2009.

	FOOTNOTES

 
¹ This work was supported by the Australian Research Council Centre of Excellence (grant no. CEO561495) and by an Australian Research Council Australian Professorial Fellowship to A.H.M., a Western Australia State Premier's Fellowship to I.D.S., and a Ph.D. scholarship from the Grains Research and Development Corporation to A.J.C.

The author responsible for distribution of materials integral to the findings presented in this article in accordance with the policy described in the Instructions for Authors (www.plantphysiol.org) is: A. Harvey Millar (harvey.millar{at}uwa.edu.au).

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www.plantphysiol.org/cgi/doi/10.1104/pp.109.141770

^* Corresponding author; e-mail harvey.millar{at}uwa.edu.au.

	LITERATURE CITED

TOP ABSTRACT RESULTS DISCUSSION CONCLUSION MATERIALS AND METHODS LITERATURE CITED

 
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