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BIOCHEMICAL PROCESSES AND MACROMOLECULAR STRUCTURES

Arabidopsis Methionine -Lyase Is Regulated According to Isoleucine Biosynthesis Needs But Plays a Subordinate Role to Threonine Deaminase^1,[W],[OA]

Boyce Thompson Institute for Plant Research, Cornell University, Ithaca, New York 14853

	ABSTRACT

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 
The canonical pathway for isoleucine biosynthesis in plants begins with the conversion of threonine to 2-ketobutyrate by threonine deaminase (OMR1). However, demonstration of methionine -lyase (MGL) activity in Arabidopsis (Arabidopsis thaliana) suggested that production of 2-ketobutyrate from methionine can also lead to isoleucine biosynthesis. Rescue of the isoleucine deficit in a threonine deaminase mutant by MGL overexpression, as well as decreased transcription of endogenous Arabidopsis MGL in a feedback-insensitive threonine deaminase mutant background, shows that these two enzymes have overlapping functions in amino acid biosynthesis. In mgl mutant flowers and seeds, methionine levels are significantly increased and incorporation of [¹³C]Met into isoleucine is decreased, but isoleucine levels are unaffected. Accumulation of free isoleucine and other branched-chain amino acids is greatly elevated in response to drought stress in Arabidopsis. Gene expression analyses, amino acid phenotypes, and labeled precursor feeding experiments demonstrate that MGL activity is up-regulated by osmotic stress but likely plays a less prominent role in isoleucine biosynthesis than threonine deaminase. The observation that MGL makes a significant contribution to methionine degradation, particularly in reproductive tissue, suggests practical applications for silencing the expression of MGL in crop plants and thereby increasing the abundance of methionine, a limiting essential amino acid.

The best-studied pathway for Ile synthesis in plants is initiated by Thr dehydratase/deaminase (EC 4.2.1.16; OMR1 or At3g10050 in Arabidopsis [Arabidopsis thaliana]), a Thr catabolic enzyme that produces 2-ketobutyrate and ammonia (Fig. 1 ). Thr deaminase activity is regulated by Ile, and feedback-insensitive Arabidopsis mutants accumulate 20-fold more Ile than the wild type (Mourad and King, 1995). Met -lyase (MGL; EC 4.4.1.11), an enzyme that converts Met to methanethiol and 2-ketobutyrate (Fig. 1), has been studied extensively in microbes and protozoa (Inoue et al., 1995; Faleev et al., 1996; Hori et al., 1996; Dias and Weimer, 1998; McKie et al., 1998; Tokoro et al., 2003; Manukhov et al., 2005). More recently, MGL activity has also been demonstrated in plants. NMR metabolite profiling of Arabidopsis cell suspension cultures labeled with [¹³C]Met showed that MGL produces 2-ketobutyrate for Ile biosynthesis (Rebeille et al., 2006). Under sulfate limitation, but not under normal growth conditions, knockout of the single Arabidopsis MGL gene (At1g64660) significantly increased Met content in leaves (Goyer et al., 2007). Although both of these prior studies in Arabidopsis demonstrate the potential of Ile biosynthesis from Met, the actual function of MGL in Ile biosynthesis and, in particular, the relative importance of Met and Thr as Ile precursors in intact plants remains to be investigated.

View larger version (15K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 1. Pathways for Ile and Gly biosynthesis in plants. 2-Ketobutyrate, a precursor of Ile biosynthesis, can be produced from either Thr or Met. Thr deaminase competes with Thr aldolase for a common substrate. Gly can be synthesized from Thr, Ser, 3-phosphoglycerate (3-PGA), and glyoxylate. The names of Arabidopsis enzymes relevant to this project are indicated in parentheses.

Free amino acid levels increase significantly in Arabidopsis vegetative tissue under drought stress (Nambara et al., 1998), with the greatest changes being observed in the abundance of branched-chain amino acids and Pro. Analysis of publicly available Affymetrix microarray data from drought- and salt-stressed Arabidopsis showed that MGL transcription is induced 4-fold (Less and Galili, 2008), suggesting a role for MGL in elevated Ile biosynthesis. Other studies have also demonstrated transcriptional up-regulation of Arabidopsis MGL in response to abiotic stress (Rizhsky et al., 2004; Peng et al., 2007; Baena-González et al., 2008; Mueller et al., 2008). When amino acid levels were measured in tomato (Solanum lycopersicum) suspension cultures subjected to water stress with polyethylene glycol, discrepancies were observed in the known pathway for Ile biosynthesis (Rhodes et al., 1986). In particular, the rate of Thr synthesis was insufficient to sustain the estimated rate of Ile biosynthesis, indicating that Ile was being made from some other source. Together, these results suggest that MGL may play a significant role in plant Ile biosynthesis during osmotic stress.

Here, we use genetic and biochemical approaches to study the in vivo role of MGL in Arabidopsis amino acid biosynthesis. In particular, we test the hypothesis that Ile biosynthesis from Met plays a significant role during free amino acid accumulation in drought-stressed plants.

	RESULTS

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 

MGL Mutants Accumulate Excess Met in Flowers and Seeds

A T-DNA insertion in the second exon of Arabidopsis MGL (mgl-1, SALK_040380; Supplemental Fig. S1) has been reported previously (Goyer et al., 2007). To increase the reliability of further experiments, we isolated a second mutant allele in the Columbia-0 (Col-0) genetic background (mgl-2, SALK_103805), which has a T-DNA insertion in the first exon, 17 bp after the MGL start codon (Supplemental Fig. S1). RT-PCR of leaf and flower tissue showed that the mutant does not accumulate any MGL transcript, suggesting complete knockout of the gene. As in the case of mgl-1, no visible phenotypes were observed at the whole-plant level in the mgl-2 mutant, and in subsequent experiments, the two independent mutations showed similar effects on Arabidopsis amino acid metabolism.

Under normal growth conditions, there were no significant changes in the free amino acid content of mgl-2 mutant leaves (Table I ). Since flowers and seeds have elevated accumulation of MGL mRNA compared to leaves (Rebeille et al., 2006; Goyer et al., 2007; Supplemental Fig. S2), we also measured amino acid levels in these tissues. Compared to the wild type, mgl-2 mutant flowers accumulated not only significantly higher Met, but also Gly, Leu, Phe, Ser, and Asp. These latter amino acid changes are difficult to explain at this point, though it is possible that excess Met resulted in elevated S-adenosylmethionine (AdoMet), which can feedback-inhibit Asp kinase and thereby increase Asp accumulation (Curien et al., 2007). A similar Asp increase in plants with high Met was reported by Hacham et al. (2008), who also suggested that increasing Met or associated metabolites beyond a certain threshold may serve as a signal that affects other amino acid biosynthesis pathways. Dry mgl-2 mutant seeds contained 3-fold more Met than the wild type, but, opposite to what was observed in the flowers, the levels of Asp, Glu, and Gly were significantly reduced (Table I). Notably, there was no significant reduction in the Ile content of leaves, flowers, or seeds due to the mgl-2 mutation.

Increased accumulation of Met in mgl mutants could have broad effects on the transcription of other genes involved in Met metabolism. In plants, Thr and Met are synthesized from a common branch point intermediate, O-phosphohomoserine. Met is produced in three steps from O-phosphohomoserine by the enzymes cystathionine -synthase (CGS), cystathionine β-lyase, and Met synthase (Hesse and Hoefgen, 2003; Supplemental Fig. S3). Most Met produced in plants is converted to AdoMet by AdoMet synthase (Giovanelli et al., 1985), which competes with MGL for a common substrate. To study the effects of Met overaccumulation, expression levels of CGS (At3g01120), three Met synthases (ATMS, At5g17920; ATMS2, At3g03780; and ATMS3, At5g20980), and four AdoMet synthases (SAM-1, At1g02500; SAM-2, At4g01850; SAM-3, At3g17390; and SAM-4, At2g36880) were measured in the flowers and siliques of mgl-2 and wild-type Col-0 using real-time quantitative RT-PCR. Unlike MGL, which is expressed most strongly in the siliques, all of these genes show predominant expression in flowers (Supplemental Figs. S2 and S4; www.genevestigator.ethz.ch; Zimmermann et al., 2004).

In mgl-2 flowers, there is a significant reduction in the expression levels of Met biosynthetic genes ATMS1, ATMS2, and CGS (Fig. 2A ). Although transcriptional regulation of Met synthases by Met or AdoMet has not been shown previously in plants, excess Met reduces mRNA accumulation and enzymatic activity of CGS in Arabidopsis (Inaba et al., 1994; Chiba et al., 1999; Bartlem et al., 2000). This transcriptional down-regulation of Met biosynthesis genes may be a direct response to the increased accumulation of Met in mgl mutant flowers. However, unlike flowers, expression levels of CGS, ATMS1, and ATMS2 were up-regulated in siliques (Fig. 2B). Expression of three of Met-degrading AdoMet synthases (SAM-2, SAM-3, and SAM-4) was found to be down-regulated only in flowers but remained unaffected in siliques (Fig. 2, A and C).

View larger version (23K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 2. Relative mRNA accumulation of genes related to Met synthesis (ATMS1, ATMS2, ATMS3, and CGS) and degradation (SAM-1, SAM-2, SAM-3, and SAM-4) in flowers (A) and siliques (B and C) of wild-type Col-0 and mgl-2 plants. Flowers and siliques of 30-d-old plants were used to extract total RNA and used for real-time quantitative PCR to obtain relative mRNA expression levels. Expression levels of all genes were normalized with respect to the internal control UBQ10. The y axes are in arbitrary units. Note different scales for each y axis. Data are mean ± SD of n = 3 samples. *, P < 0.05, Student's t test.

In response to drought stress, there are large increases in the abundance of branched-chain amino acids in Arabidopsis: 90-fold Ile, 150-fold Leu, and 25-fold Val (Nambara et al., 1998). These dramatic changes were suggested to result from up-regulation of amino acid biosynthesis in response to dehydration, rather than a more general change in protein synthesis and degradation. Gene expression profiles of MGL and OMR1 in publicly available microarray databases show that both genes are expressed in all tested plant parts (Supplemental Figs. S3 and S4; www.genevestigator.ethz.ch; Zimmermann et al., 2004). To characterize Ile biosynthesis during drought stress, relative mRNA expression levels of MGL and OMR1, which both encode enzymes leading to Ile biosynthesis (Fig. 1), were measured by real-time quantitative PCR in fresh and drought-stressed flowers of wild-type Col-0, mgl-2, and the Ile feedback-insensitive omr1-5 mutant. Relative mRNA expression levels were compared to the control housekeeping gene UBQ10, as its expression is relatively unaffected by abiotic stress (www.genevestigator.ethz.ch). MGL expression was significantly reduced in the omr1-5 mutant background (Fig. 3A ), which has 20-fold higher Ile levels (Mourad and King, 1995). However, this low MGL expression increased 3-fold during drought stress. When dehydrated flowers were compared to fresh flowers, the OMR1 mRNA expression was significantly increased in Col-0, mgl-2, and omr1-5 (Fig. 3B), suggesting regulation in response to increased need for Ile biosynthesis. These results were also confirmed by RT-PCR of other mutants defective in Thr and Ile metabolism (tha1-2, tha2, and icl-2; Supplemental Fig. S5). MGL expression is elevated after desiccation in all tested mutants, even in the high-Ile conditions (Fig. 3) of the omr1-5 mutant background. Therefore, drought-induced up-regulation of MGL transcription occurs independently of Ile abundance.

View larger version (14K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 3. Relative amounts of MGL (A) and OMR (B) transcripts in fresh and drought-stressed flowers of wild-type Col-0, mgl-2, and omr1-5. Relative expression levels on the y axis are in arbitrary units. Values are mean ± SD of n = 3 samples. *, P < 0.05 relative to fresh tissue for each genotype, Student's t test.

As both MGL transcription and Ile accumulation are strongly induced in response to osmotic stress (Nambara et al., 1998; Less and Galili, 2008), we determined whether the mgl-2 mutant shows any increased susceptibility to salt and desiccation. Compared to other tissue types, MGL expression is significantly higher in seedlings and reproductive tissue (Supplemental Fig. S4). Moreover, MGL protein accumulation is strongly increased during seed imbibition, suggesting an important role of this enzyme in the germination process (Rebeille et al., 2006). Therefore, we investigated the role of MGL in seedlings and reproductive tissue subjected to salt and drought stress, respectively.

Wild-type seedlings, along with mgl-1, mgl-2, omr1-9, omr1-5, tha2, omr1-5, tha1-2, and icl-2 mutants, were grown on Murashige and Skoog (MS) plates containing 100 mM NaCl (Fig. 4A ). No significant differences were seen in the root lengths of mgl and omr1-9 lines compared to the wild type. However, Ile overproducing omr1-5 and tha2 omr1-5 mutants show significantly longer roots than the wild type, implying a role for Ile in salt tolerance. In control experiments on MS agar without added NaCl, root lengths of all mutants were not significantly different from wild-type Col-0 (Supplemental Fig. S6A). Two- and four-week-old mgl mutants growing in soil were also irrigated with 50 and 100 mM NaCl, but no visible salt stress phenotypes were observed relative to wild-type controls.

View larger version (26K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 4. Salt sensitivity and drought-induced amino acid accumulation. A, Salt sensitivity of amino acid mutants. Seeds were planted on MS medium with 100 mM NaCl. Roots of 10-d-old seedlings were measured. Mean ± SD of n = 7. B, Amino acid accumulation in drought-stressed wild-type and mgl-2 flowers. Amino acids were quantified from fresh and dehydrated flowers of wild-type Col-0 and mgl-2. Fold-change due to dehydration was calculated. Mean ± SD of n = 4 to 6. *, P < 0.05, relative to wild-type Col-0, Student's t test.

Incorporation of ¹³C from Met into Ile Shows MGL Activity

Incorporation of labeled Met into Ile would provide direct evidence of MGL function in intact plants. Since MGL shows high expression in desiccation-stressed tissue (Fig. 3; Supplemental Fig. S5), these conditions were used for labeling experiments. [¹³C₅ ¹⁵N]Met was fed to wild-type Col-0, mgl-2, and icl-2 flower stalks for 24 h. Subsequently, siliques and flowers were harvested and dehydrated for another 18 h before extracting amino acids.

During Ile biosynthesis from [¹³C₅ ¹⁵N]Met, the ¹⁵N label is lost as ¹⁵NH₃ due to deamination by MGL, one ¹³C atom is incorporated into methanethiol, and the four remaining ¹³C atoms end up in Ile (pathway in Supplemental Fig. S7). The Ile content in flowers and siliques of Col-0 and mgl-2 labeled with [¹³C₅ ¹⁵N]Met was compared by mass spectrometry. After derivatization with Waters AccQ-tag reagent, native Ile has a mass-to-charge ratio (m/z) of 302, and Ile derived from [¹³C₅ ¹⁵N]Met has an expected m/z of 306. [¹³C₅ ¹⁵N]Met-labeled Col-0 flowers and siliques show significantly more m/z 306 ion than those of mgl-2 mutants (Fig. 5 ). The m/z 306 ion in [¹³C₅ ¹⁵N]Met-labeled mgl-2 mutant tissue was almost undetectable (Supplemental Figs. S8 and S9), consistent with only the Arabidopsis gene encoding MGL. In addition, there was no significant difference in the recovery of labeled Ile from wild-type Col-0 and icl-2 mutants, which have an elevated expression of MGL (Cornah et al., 2004). Together, these data provide evidence that MGL contributes to Ile biosynthesis in desiccated Arabidopsis tissue.

View larger version (20K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 5. 13C incorporation from Met into Ile. Flower stalks of 30-d-old plants of Col-0, mgl-2, and icl-2 plants were labeled with [13C5 15N]Met for 24 h. Siliques and flowers were harvested and dehydrated for 18 h before extracting amino acids. [13C4]Ile recovered from siliques and flowers was measured by HPLC-mass spectrometry. Mean ± SD of n = 3. *, P < 0.05 relative to wild-type Col-0, Student's t test.

Thr deaminase, the first enzyme in the Ile synthesis, is considered indispensible for normal plant growth. An auxotrophic Nicotiana plumbaginifolia mutant was rescued with exogenous Ile and by complementation with yeast Thr deaminase (ILV; Colau et al., 1987). In another report, Nicotiana attenuata plants with silenced gene expression and no detectable Thr deaminase activity were severely stunted (Kang et al., 2006). We were unable to confirm any homozygous or heterozygous mutations in Arabidopsis lines predicted to have insertions in the coding region of OMR1 (SAIL_32_BO2 and WiscDsLox36707_043; Sessions et al., 2002; Woody et al., 2007). However, we found homozygous T-DNA insertions located 110 and 78 bp upstream from the OMR1 start codon in the T-DNA lines SAIL_609_GO3 (omr1-9; Sessions et al., 2002) and SGT 576 (omr1-10, Landsberg erecta background; Parinov et al., 1999), respectively (Supplemental Fig. S10A). Both insertions cause a bushy and stunted appearance (Supplemental Fig. S10B), the plants flower late, and seed set is reduced compared to the wild type. Spraying mutant plants at 3-d intervals up to an age of 4 weeks with 1 and 4 mM of either Ile or Met did not rescue these visible mutant phenotypes. Leaves and siliques of omr1-9 plants have lower levels of OMR1 transcript than the wild-type control, and no changes in the transcript accumulation of MGL, THA1, and THA2 were detected (Supplemental Fig. S10C). Amino acid analysis of flowers, leaves, and seeds showed that the omr1-9 mutant accumulated significantly lower amounts of all branched-chain amino acids (Fig. 6 ), suggesting reduced Thr deaminase activity. Somewhat surprisingly, Thr levels in mutant leaves and seeds were also significantly reduced. Further evidence of reduced Ile biosynthesis in omr1-9 mutants comes from the observation that mutant seedlings exhibit a greater tolerance of 1 mM Ile in MS medium than wild-type Col-0 (Supplemental Fig. S11).

View larger version (25K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 6. Amino acid profiles of a Thr deaminase knockdown mutant. Amino acid abundance in leaves (A) and flowers (B) of the wild type and omr1-9. Mean ± SD of n = 4 to 6. *, P < 0.05, Student's t test. C, Rescue of omr1-9 seed amino acid phenotypes by MGL overexpression. Lines omr1-9 MGL-A and omr1-9 MGL-B are independent p35S:MGL transformations. Mean ± SD of n =3. Only amino acids with significant changes in abundance, as well as Met, are shown. *, P < 0.05 relative to wild-type Col-0, Student's t test.

The [¹³C₅ ¹⁵N]Met assay described above was used to monitor incorporation of label from Met into Ile in omr1-9 and omr1-5 plants. The incorporation of label in the knockdown mutant (omr1-9) was not significantly different from the wild type (Fig. 7 ). However, in the feedback-insensitive Thr deaminase mutant (omr1-5), which has elevated Ile levels, the accumulation of labeled Ile (m/z 306) is reduced to about 15% of wild-type levels in siliques and flowers (Fig. 7). This result is consistent with the reduced MGL transcription in the omr1-5 mutant background (Fig. 3; Supplemental Fig. S5).

View larger version (18K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 7. Met incorporation into Ile in Thr deaminase mutants. Flower stalks of Thr deaminase feedback-insensitive (omr1-5) and knockdown (omr1-9) mutants were labeled with [13C5 15N]Met. Accumulation of [13C4]Ile was measured in siliques and flowers. Mean ± SD of n = 3. *, P < 0.05, relative to wild-type Col-0, Student's t test.

	DISCUSSION

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

Although both Met and Thr serve as precursors for Ile biosynthesis in Arabidopsis, the existence of alternative plant metabolic pathways leading to Ile formation in plants cannot be ruled out at this point. Precursors for Thr- and Met-independent Ile biosynthesis in microorganisms include Glu, 2-methylbutyrate, propionate, homolanthionine, and citramalate (Phillips et al., 1972; Kisumi et al., 1977; Monticello et al., 1984; Hochuli et al., 1999; Xu et al., 2004; Krömer et al., 2006; Risso et al., 2008). Metabolite profiling experiments have shown the presence of citramalate in Arabidopsis (Fiehn et al., 2000; Roessner-Tunali et al., 2003), and it has therefore been proposed that citramalate may also serve as a precursor for Ile biosynthesis in plants (de Kraker et al., 2007).

The experiments in Figures 4B, 6, and Supplemental Figure S12 show coregulation of Ile, Leu, and Val production. Under conditions where Ile is expected to be up- or down-regulated, similar effects are seen on Leu and Val accumulation. Although such tight control over branched-chain amino acid biosynthesis in plants is commonly observed in studies involving biosynthetic mutations or osmotic stress, the mechanism of this regulation has not yet been identified. However, since the Ile, Leu, and Val biosynthetic pathways share four enzymes, biosynthesis could be coordinately regulated by either feedback inhibition or at the level of transcription.

Accumulation of Pro and branched-chain amino acids is commonly observed in plants subjected to osmotic stress (Rhodes et al., 1986; Shen et al., 1989; Girousse et al., 1996; Nambara et al., 1998; Székely et al., 2008). In addition to de novo synthesis, these elevated amino acid pools could result from reduced protein synthesis (Good and Zaplachinski, 2006) or general protein breakdown during drought stress. However, Less and Galili (2008) studied the expression of all annotated Arabidopsis proteases in response to drought and other abiotic stress and came to the conclusion that protein breakdown does not contribute significantly to amino acid accumulation.

Elevated free amino acids are hypothesized to act as osmolytes that protect plant cells against dehydration. Research to increase osmotic tolerance in plants through regulation of amino acid biosynthesis has been focused primarily on Pro (Hong et al., 2000). However, our results showing elevated salt tolerance in omr1-5 mutants (Fig. 4A) suggest that it may also be beneficial to manipulate the biosynthesis of branched-chain amino acids. Although MGL contributes to increased Ile biosynthesis under osmotic stress, we were not able to find changes in drought or salt tolerance in mgl mutants (Fig. 4A). This absence of a phenotype could be due to a compensatory increase in OMR1 transcription (Fig. 3) and therefore increased synthesis of Ile from Thr in desiccated mgl mutant tissue. Nevertheless, MGL overproduction, if it has similar effects as feedback insensitive mutations in OMR1 (Fig. 4A), could provide a mechanism for increasing salt or drought tolerance in plants.

Several studies have indicated transcriptional regulation of MGL in response to drought, salt, and other abiotic stress (Rizhsky et al., 2004; Peng et al., 2007; Baena-González et al., 2008; Less and Galili, 2008; Mueller et al., 2008). However, although our semiquantitative RT-PCR experiments suggested desiccation-induced MGL up-regulation (Supplemental Fig. S5), we were unable to reject the null hypothesis (no difference between drought-stressed and unstressed wild-type flowers) under our growth conditions using quantitative RT-PCR experiments (Fig. 3A). The observation that there is nevertheless a significant decrease in Ile content in drought-stressed mgl-2 mutant flowers relative to the wild type (Fig. 4B) is consistent with the previously proposed hypothesis of MGL posttranscriptional regulation in Arabidopsis (Rebeille et al., 2006). Moreover, the relatively small (<50%) decrease in Ile accumulation in mgl-2 mutant flowers (Fig. 4B) suggests that MGL is of lesser importance than OMR1 for drought-induced production of Ile.

The results in Figure 2 indicate a complex regulation of Met biosynthesis and degradation that cannot be fully explained by our current knowledge of these pathways. However, the observed effects on transcription, in particular down-regulation of Met synthases and CGS in mgl-2 flowers, suggest a broader role of MGL in regulating Met metabolism. To date, not much is known about the transcriptional regulation of Met synthase in plants. However, CGS in Arabidopsis is transcriptionally and posttranscriptionally regulated by Met or one of its metabolites (Hesse et al., 2004).

There are potential practical applications to manipulating MGL activity in crop plants. For instance, since Met is considered a limiting essential amino acid in potatoes, there have been several attempts to increase potato Met accumulation by altering the activity of biosynthetic enzymes. So far, this has met with only limited success. Increasing the expression of homoserine kinase did not increase Met levels (Rinder et al., 2008). Knockdown of Thr synthase greatly increased Met levels but caused severe phenotypic defects (Zeh et al., 2001). Increased production of CGS caused only moderate increases in tuber Met accumulation (Di et al., 2003; Kreft et al., 2003; Dancs et al., 2008), perhaps due to elevated Met catabolism in the transgenic lines. If this is the case, silencing MGL expression in potato lines with elevated Met biosynthesis might further increase accumulation of this essential amino acid. A similar approach, increased biosynthesis combined with reduced catabolism, has been used to successfully increase Lys levels 80-fold in Arabidopsis and 40-fold maize (Zhu and Galili, 2003; Frizzi et al., 2008).

The results presented here show that OMR1 and MGL have partially overlapping functions in Ile biosynthesis. Although both MGL and OMR1 transcription is regulated by the Ile needs of the plant, our results do not rule out further regulation of these enzyme activities through translation or allosteric mechanisms in Arabidopsis. Given that, unlike omr1 knockdown mutants, mgl knockout mutants have no visible phenotypes or growth defects, Thr deaminase activity likely predominates during Ile biosynthesis in vegetative tissue. However, in reproductive tissue and under osmotic stress conditions, biosynthesis of Ile from Met can play a significant role in Arabidopsis amino acid metabolism.

	MATERIALS AND METHODS

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 

Plant Material

Wild-type Arabidopsis (Arabidopsis thaliana) Col-0 seeds, as well as T-DNA insertion lines SALK_103805 (mgl-2; CS16492), SAIL_609_GO3 (CS16487), and SAIL_32_BO2 (CS16488; Sessions et al., 2002; Alonso et al., 2003), gene trap line SGT_576 (CS16489; Parinov et al., 1999), and WiscDsLox36707_043 (CS16490; Woody et al., 2007), were obtained from the Arabidopsis Biological Resource Center (http://www.arabidopsis.org). Other seeds were kindly supplied to us by Y. Shachar-Hill, Michigan State University (mgl-1; SALK_0400380; CS16491), J. Cornah, University of Edinburgh (icl-2), and G. Mourad, Indiana-Purdue University (omr1-5 mutant and p35S-omr1 transgenics).

Growth Conditions

Plants were grown in Cornell Mix with Osmocoat fertilizer (Landry et al., 1995) in 20- x 40-cm nursery flats in Conviron growth chambers. Photosynthetic photon flux density was 200 µmol m^–2 s^–1, the photoperiod was 16:8 day:night, the temperature was 23°C, and the relative humidity was 50%. Seeds were cold-stratified at 4°C in 0.1% Phytagar (Gibco BRL Life Technologies) for 3 d. For growth on agar plates, 1x MS medium (Murashige and Skoog, 1962) with or without 1% Suc was used, and the plates were placed the same growth chambers as the soil-grown plants. For the salt tolerance experiment, mutant and wild-type seeds were surface sterilized with a 1 min wash of 70% ethanol, followed by 50% bleach and 0.01% Triton X-100 for 10 min. Seeds were then rinsed four to five times with sterilized water, and seeds were suspended in 0.1% sterile phytagar. Sterilized seeds were placed on MS medium with 0, 50, 100, or 150 mM of NaCl and 500 µM and 1 mM Ile. Plates were placed vertically to measure the root lengths after 2 weeks.

For experiments to rescue the omr1-9 phenotype, 10-d-old plants were sprayed with 1 or 4 mM Met and Ile at 3-d intervals up to an age of 4 weeks. For the drought tolerance experiment, the wild type and mutants were grown in the same flat, and irrigation to 30-d-old plants was withheld for 6 to 10 d, until complete wilting. For salt tolerance tests in soil, 2- and 4-week-old plants were irrigated with 50 and 100 mM NaCl for 3 to 4 d. For dehydration experiments, tissue was detached from 30-d-old plants and dehydrated on paper towels for 18 h under ambient humidity. Plant tissue was weighed before and after the dehydration treatments.

Amino Acid Analysis by HPLC

For free amino acid analysis, plant tissue was preweighed and was frozen in liquid nitrogen along with 3-mm steel balls (Abbott Ball Company) and was homogenized using a Harbil 5G-HD paint shaker (Fluid Management). Amino acids levels were analyzed as described previously (Joshi et al., 2006) using an AccQ-fluor reagent kit (Waters). Aliquots (10 µL) were used for HPLC analysis using a Waters 2790 separation module. Separation was performed on 3.9- x 150-mm AccQ-Tag column (Waters) at 38°C, and amino acids were detected using a Waters 2487 dual-wavelength absorbance detector at 280 nm and a Waters 2475 photodiode array detector with excitation at 280 nm and emission at 395 nm. Eluent A (sodium acetate and trimethylamine, pH 5.04; Waters) and solution B (60% acetonitrile:40% water) were used at a 1 mL min^–1 flow rate with the following gradient: 0 to 0.01 min, 100% A; 0.01 to 5.0 min, linear gradient to 97% A, 3% B; 5 to 12 min, to 95% A, 5% B; 12 to 15 min, 92% A, 8% B; 15 to 45 min, 65% A, 35% B; 45 to 49 min, to 65% A, 35% B; 49 to 50 min, to 100% B; 50 to 60 min, to 100% B, 61 to 68 min, 100% A. Standard curves were prepared using amino acids purchased from Sigma-Aldrich. Amino acid concentrations were calculated by comparing peak areas to those of standard curves and normalized using L-norleucine as an internal control.

Isotope Labeling and Liquid Chromatography-Mass Spectrometry Analysis

For stable isotope experiments L-[¹³C₅ ¹⁵N]Met was purchased from Cambridge Isotope Laboratories. Flower stalks of 30-d-old plants were cut above the rosette leaves, and the bases of the stalks were inserted into 15-mL polypropylene tubes containing 1 mM of labeled Met in water and were left for 24 h under continuous light at 23°C. At the end of the treatment, flowers and siliques were harvested and dehydrated for another 18 h. Amino acids were extracted in 40% methanol and evaporated completely under vacuum. The residue was resuspended in a proportion based upon tissue amount in 20 mM HCl and derivatized with AccQ-Flour reagent, and samples were separated by HPLC as described above. Solutions A (100 mM sodium acetate, pH 5.04) and B (60% acetonitrile:40% water) were used at a 0.3 mL min^–1 flow rate with following gradient: 0 to 0.01 min 100% A, 0.01 to 0.5 min, 98% A; 0.5 to 20 min, linear gradient to 94.5% A, 5.5% B; 20 to 24 min, to 85% A, 15% B; 24 to 60 min, to 75% A, 25% B; 60 to 62 min, 100% B, 62 to 65 100% B, and 65 to 75 min, 100% A. For HPLC-mass spectrometry analysis, conditions described previously (Lee et al., 2008) were used with some modifications. Outflow from the column was split and directed into a Varian 1200 L triple quadrupole mass spectrometer with an electrospray ionization source at a 300 µL min^–1 flow rate. The mass spectrometry was controlled using MS Workstation version 6 (Varian) and set up using the following conditions: drying gas (N₂) 185°C and 19 p.s.i., capillary voltage 30 V, needle voltage 5,000 V, housing temperature 50°C, main gas pressure 66 p.s.i., and nebulizing gas pressure 56 p.s.i.

Verification of T-DNA Insertions in MGL and OMR1

For identification of T-DNA insertions, DNA was extracted from mutants and Col-0 (Ausubel et al., 1998; Weigel and Glazebrook, 2002). Sequences of oligonucleotide primers used in this study are listed in Supplemental Table S1. The T-DNA insertion in line SALK_103805 (mgl-2) was confirmed using gene-specific primers (MGL-2RP and MGL-2LP) and the insert-specific primer LBa1. For Thr deaminase T-DNA insertions, the following primer pairs were used: for SAIL_609_GO3, gene-specific primers S609LP and S609RP and vector-specific primer and Lb3; for gene trap line SGT 576, gene-specific primers SGT LP and SGT RP and vector-specific primer SGT DS3.2; for WiscDsLox36707_043, WISC LP and WISC RP and vector-specific primer WISC745. T-DNA insertions in SAIL lines growing on soil were selected by spraying with 300 µM glufosinate ammonium (Finale; Farnam Companies). For SALK T-DNA insertion lines, seedlings were selected on MS medium supplemented with 25 to 30 µg/mL kanamycin.

Transcription Analysis Using RT-PCR

Total RNA was extracted using the RNeasy plant mini kit (Qiagen) and RNase-free DNase (Qiagen) according to the manufacturer's protocol. The reverse transcription reaction was performed using 2 µg of total RNA to synthesize cDNA with an oligo(dT)₁₅ primer (Promega) and SuperScript III reverse transcriptase (Invitrogen). PCR was conducted with 1 µL of RT reaction at 94°C for 30 s, 56°C for 30 s, and 72°C for 50 s. The number of cycles was 27 in the drought experiment (Fig. 2) and 25 in the omr1-9 experiment (Supplemental Fig. S6). To check the transcript abundance, gene-specific primers were designed spanning an intron to reduce the possibility of DNA contamination. The following pairs of primers were used: MGL (MGL R1 and MGL R2), OMR1 (OMR1 R1 and OMR1 R2), ICL (ICL R1 and ICL R2), THA1 (THA1 R1 and THA1 R2), and THA2 (THA2 R1 and THA2 R2). Expression levels of genes of interest were compared to a control gene UBQ10, which was amplified using primers UBQ1 and UBQ2. The DNA sequences of all primers are listed in Supplemental Table S1.

Quantitative Real-Time RT-PCR Analysis

For quantitative real-time RT-PCR analysis, total RNA was isolated using the Qiagen RNeasy kit according to the manufacturer's instructions and was on-column treated with RNAse-free DNase (Qiagen). One microgram of DNA-free RNA was then reverse transcribed with a 2.5 µM oligo(dT)₁₅ primer (Promega) and SMART MMLV reverse transcriptase (Clontech) following the manufacturer's recommendations. Samples were incubated at 42°C for 90 min, and reaction was terminated by heating at 70°C for 15 min. Real-time quantitative PCR was performed in an optical 384-well plate with an ABI PRISM 7900 HT sequence detection system (Applied Biosystems) and SYBR Green qPCR SuperMix (Applied Biosystems). The final PCR reaction volume was 15 µL and comprised 1 µL of reverse transcribed cDNA, 200 nM of each gene-specific primer, 7.5 µL of 2x SYBR Green Master Mix reagent (Applied Biosystems), and water. The PCR gradient was set as follows: 50°C for 2 min, 95°C for 10 min, 40 cycles of 95°C for 30 s, 56°C for 30 s, and 72°C for 30 s. Experiments were set and analyzed using the SDS 2.1 software (Applied Biosystems).

To obtain expression levels of Met synthases, CGS, and AdoMet synthases, total RNA extraction was carried out from flowers and siliques of 30-d-old wild-type (Col-0) and mgl-2 plants. The following pairs of gene-specific primers were used for this experiment: QMS P1, QMS P2 (ATMS1; At5g17920), QMS2 P1, QMS2 P2 (ATMS2; At3g03780), QMS3 P1, QMS3 P2 (ATMS3; At5g20980), QCGS P1, QCGS P2 (CGS; At3g01120), QSAM1 P1, QSAM1 P2 (SAM-1; At1g02500), QSAM2 P1, ASAM2 P2 (SAM-2; At4g01850), QSAM3 P1, QSAM3 P2 (SAM-3; At3g17390), and QSAM4 P1 and QSAM4 P2 (SAM-4; At2g36880) (Supplemental Table S2). Ct values for all the genes of interest were normalized by subtracting the mean of reference gene UBQ10 (At4g05320) amplified using as gene-specific primers QUBQ10-L and QUBQ10-R as described by Czechowski et al. (2004, 2005). The expression level of each gene was calculated as the relative amount compared to the wild-type control using the formula: expression level = 2^{–(Ct (target) – Ct (control))}, as recommended by the instrument manufacturer. For the drought tolerance experiment, tissue collection and total RNA extraction from the wild type (Col-0), mgl-2, and omr1-5 was carried out as described above. Primer pairs QMGL P1 and QMGL P2 and QOMR P1 and QOMR P2 were used to amplify the endogenous MGL and OMR1 transcripts, respectively. The fold change of transcript accumulation in dehydrated tissue compared to fresh tissue in each sample was calculated based on the efficiency calibrated model (Yuan et al., 2006) and a previously described equation (Pfaffl, 2001).

MGL Cloning and Complementation by Plant Transformation

An MGL open reading frame/cDNA clone (stock no. 3G15166; The Arabidopsis Information Resource accession no. 3510684848) in the entry vector pENTR223 was obtained from the Arabidopsis Biological Resource Center. Gene integrity was confirmed by DNA sequencing using M13 F and R universal primer pairs. The cloned DNA was transferred to destination vector pMDC32 using the LR reaction as in the manufacturer's instructions (Invitrogen), and colonies showing kanamycin resistance were selected. Sequencing was repeated to confirm the ends using pMDC32-specific and gene-specific primers (PMDC3235S, MGL SEQ, and PMDC32NOS; Supplemental Table S1), and sequencing data were analyzed using Lasergene 6 software (DNAstar). The binary vector was then transformed into Agrobacterium tumefaciens strain GV3101 and subsequently used to transform SAIL_609_GO3 (omr1-9) plants (Clough and Bent, 1998). T1 plants were screened on MS agar plates for hygromycin resistance (20–100 µg/µL), and green, healthy plants were transferred to soil.

Sequence data from this article can be found in the GenBank/EMBL data libraries under accession numbers NM_105141 (At1g64660) and NM_111840 (At3g10050).

Supplemental Data

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

Supplemental Figure S1. Identification of a homozygous mgl-2 T-DNA insertion.

Supplemental Figure S2. Tissue-specific expression patterns of Met synthases and Thr deaminase.

Supplemental Figure S3. Pathway showing proteins involved in Arabidopsis Met metabolism.

Supplemental Figure S4. Tissue-specific expression patterns of MGL and AdoMet synthases.

Supplemental Figure S5. MGL and OMR1 transcription under drought stress.

Supplemental Figure S6. Controls for salt sensitivity experiment and amino acid accumulation in drought-stressed leaves.

Supplemental Figure S7. Possible pathway of label incorporation in Ile after feeding the plant tissue [¹³C₅ ¹⁵N]Met.

Supplemental Figure S8. Detection of isotopically labeled Ile in wild-type and mgl siliques.

Supplemental Figure S9. Detection of isotopically labeled Ile in wild-type and mgl flowers.

Supplemental Figure S10. omr1-9 mutant phenotypes and expression profiling.

Supplemental Figure S11. Ile tolerance of wild-type Col-0 and omr1-9.

Supplemental Figure S12. Rescue of omr1-9 amino acid deficits by omr1-1 overexpression.

Supplemental Table S1. Sequences of oligonucleotide primers.

Supplemental Table S2. Sequences of oligonucleotide primers used for quantitative PCR.

	ACKNOWLEDGMENTS

 
We thank Y. Shachar-Hill for the mgl-1 mutant, J. Cornah for the icl-2 mutant, and G. Mourad for omr1 mutants and plasmid constructs.

Received March 13, 2009; accepted June 22, 2009; published July 1, 2009.

	FOOTNOTES

 
¹ This work was supported by the Binational Agricultural Research and Development Fund (grant no. US–3910–06) and the National Science Foundation (grant nos. MCB–0416567 and DBI–050050).

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: Georg Jander (gj32{at}cornell.edu).

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www.plantphysiol.org/cgi/doi/10.1104/pp.109.138651

^* Corresponding author; e-mail gj32{at}cornell.edu.

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