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BIOCHEMICAL PROCESSES AND MACROMOLECULAR STRUCTURES

System Analysis of an Arabidopsis Mutant Altered in de Novo Fatty Acid Synthesis Reveals Diverse Changes in Seed Composition and Metabolism^1,[W],[OA]

Interdisciplinary Plant Group and Division of Biochemistry (M.C., B.P.M., M.H., J.J.T.), Computer Science Department (T.J., D.X.), DNA Core Microarray Facility (M.Z.), and Charles Gehrke Proteomics Center (B.P.M.), Christopher S. Bond Life Sciences Center, University of Missouri, Columbia, Missouri 65211

	ABSTRACT

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 
Embryo-specific overexpression of biotin carboxyl carrier protein 2 (BCCP2) inhibited plastid acetyl-coenzyme A carboxylase (ACCase), resulting in altered oil, protein, and carbohydrate composition in mature Arabidopsis (Arabidopsis thaliana) seed. To characterize gene and protein regulatory consequences of this mutation, global microarray, two-dimensional difference gel electrophoresis, iTRAQ, and quantitative immunoblotting were performed in parallel. These analyses revealed that (1) transgenic overexpression of BCCP2 did not affect the expression of three other ACCase subunits; (2) four subunits to plastid pyruvate dehydrogenase complex were 25% to 70% down-regulated at protein but not transcript levels; (3) key glycolysis and de novo fatty acid/lipid synthesis enzymes were induced; (4) multiple storage proteins, but not cognate transcripts, were up-regulated; and (5) the biotin synthesis pathway was up-regulated at both transcript and protein levels. Biotin production appears closely matched to endogenous BCCP levels, since overexpression of BCCP2 produced mostly apo-BCCP2 and the resulting ACCase-compromised, low-oil phenotype. Differential expression of glycolysis, plastid pyruvate dehydrogenase complex, fatty acid, and lipid synthesis activities indicate multiple, complex regulatory responses including feedback as well as futile "feed-forward" elicitation in the case of fatty acid and lipid biosynthetic enzymes. Induction of storage proteins reveals that oil and protein synthesis share carbon intermediate(s) and that reducing malonyl-coenzyme A flow into fatty acids diverts carbon into amino acid and protein synthesis.

Transcriptome analyses of some of these mutants have begun to reveal the cascade of gene regulatory changes that result from such metabolic lesions. A transcriptome study of the wri1 mutant, performed using a cDNA array containing more than 3,500 genes, found that approximately 1% of genes differed by more than 2-fold and most were involved in central lipid and carbohydrate metabolism (Ruuska et al., 2002). These data partly define the downstream response to disruption of the WRI1 gene and provide a basis for comparison of the frequency of differential transcripts in response to a transcription factor that regulates glycolysis during seed development (Cernac and Benning, 2004). The transcriptome of tps1 embryos shows coordinated down-regulation of genes involved in starch and Suc degradation and a concomitant up-regulation of genes involved in lipid mobilization and gluconeogenesis (Gómez et al., 2006). Metabolic profiling of sse1 seeds found that sugars, alcohols, pyruvate, and other organic acids accumulate when carbon demand for lipid synthesis is reduced and more carbon enters the tricarboxylic acid (TCA) cycle downstream of glycolysis (Lin et al., 2006). Thus, mutations at the regulatory or substrate level can produce marked effects on seed metabolism and composition.

Seed-specific overexpression of biotin carboxyl carrier protein 2 (BCCP2) to the heteromeric plastid acetyl-coenzyme A carboxylase (ACCase) produced lower seed oil compared with nontransgenic lines (Thelen and Ohlrogge, 2002a). Immunoblot analyses with antibodies to both biotin and recombinant BCCP2 demonstrated that this phenotype was due to fractional biotinylation of BCCP2. The phenotype, therefore, was attributed to the production of nonbiotinylated ACCase complexes. Activity analysis of ACCase supported this conclusion by revealing a 3-fold reduction in ACCase activity coincident with the temporal expression of BCCP2, driven by the napin storage protein promoter (Thelen and Ohlrogge, 2002a). This mutant is unique in that it disrupts the committed step for de novo fatty acid synthesis, specifically during mid to late seed development, when enzymes of this pathway begin to accumulate (Mansfield and Briaty, 1992). The fractional nature of this ACCase mutant and its seed specificity are two beneficial characteristics of this mutant. Complete or nearly complete loss-of-function mutations for de novo fatty acid synthetic enzymes (or proteins involved in their regulation) produce lethal or retarded growth phenotypes (Shintani et al., 1997; Mou et al., 2000; Bonaventure et al., 2003; Millar et al., 2003). The lethality of knockout mutants for this pathway is likely due to the requirement of acyl chains for membrane lipid production (Thelen and Ohlrogge, 2002b). Unlike vegetative tissues, embryos principally utilize acyl chains for triacylglycerol production. Thus, collateral or pleiotropic manifestations are minimized in this ACCase mutant, allowing for direct analysis of cross talk between de novo fatty acid synthesis in the plastid and other metabolic pathways operating within developing embryos.

The varied "omic" resources available for molecular profiling differ in their target biomolecules (e.g. transcript, protein, metabolites) as well as in their sensitivity, reproducibility, and depth of coverage. Few plant systems biological investigations have studied multiple biomolecules in parallel (Gallardo et al., 2007; Sato et al., 2007). For the current study, we performed oligonucleotide microarray analyses in parallel with iTRAQ and two-dimensional difference gel electrophoresis (2D-DIGE) on this ACCase mutant. Microarrays revealed 375 differentially expressed transcripts. Parallel proteomics approaches collectively revealed a smaller number of differential proteins, some of which were not differentially regulated at the transcriptome level. Many of the protein-specific changes were confirmed by quantitative immunoblotting, suggesting that the transcriptome and proteome differences are biological rather than experimental in nature. It is evident from this study that not all proteins adhere to the assumed stoichiometric relationship between transcript and protein and that quantitative transcriptomics and proteomics, when applied together, can reveal these regulated proteins.

	RESULTS

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 

Protein, Glc, and Suc Contents Are Higher in BCCP2 Overexpression Lines

A previous study found that seed-specific overexpression of BCCP2 to the heteromeric plastid ACCase produced 24% lower seed oil compared with nontransgenic lines (Thelen and Ohlrogge, 2002a). To determine if reduced fatty acid biosynthesis in BCCP2 overexpression lines affects other seed storage reserves, protein, starch, and sugar content in mature seeds were quantified in lines 5-2 and 9-5 (Table I ). Protein content in the BCCP2 overexpression lines was 10% and 25% higher in the 5-2 and 9-5 lines, respectively, while Glc and Suc levels were approximately 100% higher in both lines. Starch and Fru were not significantly affected.

Thirteen days after flowering (DAF), seeds were harvested from wild-type plants and two BCCP2 overexpression lines (5-2 and 9-5), and isolated protein was analyzed by 2D-DIGE (Fig. 1 ). The majority of proteins (approximately 1,200 spots) were equivalently expressed on both pH 3 to 10 and pH 4 to 7 gels, indicating accurate developmental staging. Twenty-three total spots were consistently differential between the wild-type and mutant lines (P < 0.05). Most notably, an isoelectric series of proteins at 25 kD were up-regulated in both BCCP2 overexpression lines (Fig. 2 , regions 1 and 2). A prominent but amorphous group of spots around 20 kD also appeared to be up-regulated in the BCCP2 overexpression lines (Fig. 2, B and C, circled regions). However, these spots were large and inconsistent from gel to gel and, therefore, could not be reproducibly quantified. In a global proteomic study of Arabidopsis seed filling, prominent spots in this region have been identified as napin, a 2S seed storage protein (J.J. Thelen, unpublished data).

View larger version (44K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 1. Experimental design used to globally analyze transcript and protein expression in BCCP2 overexpression lines. Proteins isolated from 13-DAF seeds of the wild type (WT) and BCCP2 lines 5-2 and 9-5 were analyzed in biological triplicate by 2-DE. Only those spots present on all three gels were considered for analysis. Relative quantification and expression profiles were determined using Image Master 2-DE Platinum software version 5.0. The same protein preparations also were subjected to iTRAQ analysis and quantification. For transcriptome analysis, total RNA was isolated from 13-DAF seeds of the wild type and BCCP2 line 9-5, mRNA amplified, and then hybridized with the Arabidopsis ATH1 Genome Array in duplicate. SCX, Strong cation exchange.

View larger version (68K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 2. 2D-DIGE analysis of total protein isolated from developing seeds (13 DAF) from the wild type (WT) and BCCP2 transgenic line 9-5. Protein samples were resolved in biological triplicate from the wild type and BCCP2 overexpression lines 5-2 and 9-5 using both pH 3 to 10 (A) and pH 4 to 7 (D) immobilized pH gradient strips to maximize proteome coverage. Representative gels from a comparison of the wild type and line 9-5 are shown. A, DIGE overlay image of Cy3-red/Cy5-green channels separated on DIGE gel pH 3 to 10. B and C, Gray scale images of Cy dye-labeled protein from the wild type and BCCP2 line 9-5 from A. Highlighted regions in images B and C indicate several protein spots that were up-regulated in the BCCP2 transgenic lines but could not be resolved for quantitation. D, DIGE overlay image of Cy3-red/Cy5-green channels separated on DIGE gel pH 4 to 7. Highlighted gel regions (1 and 2) show close-ups of the boxed areas in A and D, respectively, revealing multiple up-regulated proteins at 25 kD. These protein spots were each identified as BCCP2 as indicated in Table II.

Immunoblot Analyses Indicate the Presence of Five Isoelectric Species for BCCP2 and Two for BCCP1

Two functional BCCP isoforms were previously identified in Arabidopsis, BCCP1 and BCCP2 (Thelen et al., 2001). Transgenic up-regulation of BCCP2 produced multiple 25-kD isoelectric species that were identified by MS as BCCP2 (Fig. 2; Table II). This finding is surprising, since the only known posttranslational modification (PTM) for this protein is biotinylation (Thelen et al., 2001). To confirm this observation, two-dimensional electrophoresis (2-DE) protein blotting was performed with anti-BCCP2 and anti-biotin antibodies. The 2-DE immunoblot results demonstrated the presence of two distinct isoelectric species for BCCP1 (35 kD) and as many as six for BCCP2 (23–25 kD; Supplemental Fig. S1), in accordance with the 2D-DIGE results. The multiple isoelectric species for BCCP2 also showed a mass shift when analyzed by 15% SDS-PAGE: BCCP2 appeared as a doublet, while BCCP1 was a single band. The multiple isoelectric species for BCCP1 and BCCP2 could represent transcript splice variants or posttranslationally modified forms of the proteins. An extensive search of the expressed sequence tag databases revealed two splice variants for BCCP1, producing 29.6- and 26.9-kD predicted proteins with pI values of 9.57 and 10.14, respectively. No splice variants were found for BCCP2. The multiple forms of BCCP2, therefore, are likely due to PTM, since all five were induced by a single cDNA transgene. Biotinylation, however, is not the sole PTM, since four spots were also observed with anti-biotin antibodies (Supplemental Fig. S1). Additional PTMs on BCCP2 may point toward another form of regulation for ACCase.

Gel-Free iTRAQ Analysis Identified 50 Differentially Expressed Proteins

Gel-free iTRAQ was also employed with the same protein samples used for 2D-DIGE. This approach identified one of the differential proteins also detected by 2D-DIGE (BCCP2), but mostly the data set of differentially expressed proteins was distinct from 2D-DIGE (Supplemental Table S1). iTRAQ showed a BCCP2 (At5g15530) peptide that was strongly up-regulated in line 9-5, but no iTRAQ signal was detected for line 5-2, for unclear reasons. Cruciferin and napin storage proteins were found to be 37% to 156% and 47% to 64% higher, respectively, in 5-2 and 9-5 BCCP2 lines. Putative napin 2S seed storage proteins were also higher in BCCP2 lines by 2D-DIGE (Fig. 2, B and C, circled dots), but not consistently. Plastid pyruvate dehydrogenase β-subunit (E1β; At1g30120) and plastid Fru-bisP aldolase (FBA; At3g52930) were down-regulated in BCCP2 lines, while malate dehydrogenase (At1g04410), enolase (At1g74030), and Ala-2-oxoglutarate aminotransferase 2 (AOAT2; At1g70580) were up-regulated. E1β is a subunit to the plastid pyruvate dehydrogenase complex (PDC), which produces acetyl-CoA for de novo fatty acid synthesis. Enolase catalyzes the production of phosphoenolpyruvate, the penultimate step in glycolysis, and AOAT2 converts pyruvate into Ala. Thus, it appears that pyruvate production and steps peripheral to pyruvate production were also affected. In Brassica napus embryos, an alternative metabolic route for the generation of carbon for fatty acid synthesis is the Rubisco bypass (Schwender et al., 2004). Two enzymes involved in this bypass (Rubisco small subunit 1A [At1g67090] and transketolase [At3g60750]) were down-regulated in BCCP2 overexpression lines.

In contrast to the increase in storage proteins, ribosome structural constituents, Gly-rich RNA-binding proteins, and an elongation factor were down-regulated. RNA-binding proteins are involved in posttranscriptional processes such as pre-mRNA processing, splicing, RNA editing, and mRNA stability (Fedoroff, 2002). Although storage proteins increased and ribosomal proteins decreased, it should be noted that the capacity of protein synthesis (i.e. mRNA abundance) is another important factor. Since the mRNA of storage genes increases later and remains high (Ruuska et al., 2002), this could explain why storage proteins are up-regulated as the translation machinery is decreasing. Two proteins involved in chromatin modification, histone H2B (At5g22880) and ATP-dependent helicase (At1g54270), were found to be down-regulated and up-regulated, respectively, suggesting that gene regulation may take place at the chromatin level to modify transcriptional activity.

Interestingly, three oleosins were down-regulated in both BCCP2 transgenic lines. Oleosins are proteins associated with oil bodies that have been shown to play an important role in oil body structure and size, and their expression appears to be directly correlated with seed oil content (Leprince et al., 1998; Siloto et al., 2006).

Microarray Analysis Identified 375 Differential Genes

Current proteomic approaches offer only a fractional view of the proteome. In contrast, contemporary microarrays are capable of providing a nearly comprehensive assessment of the transcriptome. For comparison with the two proteomics approaches and to obtain a more inclusive assessment of collateral changes resulting from a reduction in ACCase activity in developing seeds, oligonucleotide microarrays were performed with the wild type and line 9-5. Exactly 375 of the 22,810 transcripts assayed (1.65% of the transcriptome) were differentially expressed (P < 0.05) between the BCCP2 9-5 line and wild-type 13-DAF seeds (Supplemental Table S2). The most prominent up-regulated transcript was BCCP2. Interestingly, none of the other nuclear-encoded ACCase subunits was differentially expressed. Transcripts for biotin synthase (Bio2; At2g43360), 7-keto-8-aminopelargonic acid (KAPA) synthase (At5g04620), and biotin/lipoic acid attachment domain-containing protein (At1g52670) were also prominently up-regulated. KAPA synthase and biotin synthase catalyze the first and last steps of the biotin synthesis pathway, respectively. Asparagine synthetase (ASN2; At5g65010), which catalyzes the formation of Asn from Asp, was also significantly up-regulated. Asn is an important nitrogen transport amino acid. Overexpression of its paralog ASN1 (At3g47340) has been reported to increase total seed protein content (Lam et al., 2003). It is possible that overexpression of ASN2 has a similar effect on storage synthesis and may contribute to the higher protein content in this mutant.

Transcripts for fatty acid synthesis and modification enzymes located downstream of ACCase (i.e. acyl carrier protein [At5g27200], acyl-ACP desaturase [At5g16240], enoyl-ACP reductase [At2g05990], β-hydroxyacyl-ACP dehydratase [At2g22230 and At5g10160], acyl-CoA desaturase [At1g06080], long-chain acyl-CoA synthetase [At1g77590], lecithin:cholesterol acyltransferase [At5g13640], and phosphatidic acid phosphatase-related [At3g15820]) were each induced in the 9-5 line. Collectively, this suggests a feed-forward or "starvation" response due to the limitation of fatty acid precursor supply for lipid synthesis. Additionally, five genes annotated as lipid transfer proteins were differentially expressed: At3g22620, At2g48140 (EDA4), and At3g22620 (LTP4) were down-regulated, while At3g51600 (LTP5) and At5g01870 (LTP6) were up-regulated.

Forty-three genes involved in carbohydrate metabolism were also differentially expressed in the BCCP2 transgenic line. Most (33 of 43 genes) showed up-regulation in the mutant. Thirteen genes for amino/organic acid metabolism were differentially expressed, and most (10 of 13) were up-regulated in the mutant. Malate dehydrogenase (At1g04410) was up-regulated at the mRNA level, in accordance with the cognate protein (Supplemental Tables S1 and S2).

A plastidic Glc-6-P/phosphate translocator (GPT; At1g61800) was transcriptionally up-regulated in the 9-5 BCCP2 overexpression line. Increased GPT expression suggests that reduced flux through fatty acid synthesis alters the subcellular partitioning of Glc-6-P between the plastid and the cytosol. How the pool size was affected in plastid and cytoplasm still remains unclear, since the direction of Glc-6-P transport must also be considered (Kammerer et al., 1998).

Interestingly, late embryogenesis-associated proteins (At3g22500, At3g22490, At2g40170, At4g36600, and At3g53040) and senescence-associated family protein (At2g17850) were down-regulated at the mRNA level (Supplemental Table S2). This finding suggests that seed maturation might be delayed in this mutant. In another low-oil mutant with a lesion in the diacylglycerol acyltransferase gene, seed maturation was delayed in comparison with the wild type (Katavic et al., 1995; Zou et al., 1999).

Quantitative Immunoblotting Confirms Omics Results

Microarray, 2D-DIGE, and gel-free iTRAQ data indicated that expression of some enzymes of glycolysis and de novo fatty acid synthesis pathways were induced when ACCase was attenuated. To confirm this observation, antibodies were developed to these proteins to quantify expression during seed development by immunoblotting. Fructokinase-1 (FK; At2g31390), plastid phosphoglycerate mutase (pdPGAM; At1g09780), cytosolic phosphoglucomutase (cytoPGM; At1g23190), and enolase (At2g36530) expression peaked at 11 DAF and then declined in wild-type seeds (Fig. 3 ). Expression of plastid phosphoglucomutase (pdPGM; At5g51820) and cytosolic triose-P isomerase (cytoTPI; At3g55440) peaked earlier at 9 DAF and then decreased at subsequent stages. Comparison of these trends in the wild type and two lines overexpressing BCCP2 revealed reproducible differences. Expression levels of FK and pdPGAM were approximately 50% lower in both transgenic lines at 13 and 15 DAF. In contrast, expression of cytoPGM and enolase increased between 15% and 100% in both transgenic lines at 13 and 15 DAF. No consistent changes in expression levels were observed with cytoTPI (Fig. 3). Interestingly, pdPGM was 40% to 60% down-regulated (depending upon line) at the onset of BCCP2 accumulation at 11 DAF (Fig. 3). By 13 and 15 DAF, wild-type levels of this protein were approximately 15% of the peak at 9 DAF and transgenic lines contained approximately half. Therefore, pdPGM was one of the earliest responding activities to the dominant-negative mutation in ACCase, which, given its previously established role in starch biosynthesis (Huber and Hanson, 1992; Harrison et al., 1998), suggests that it could also have regulatory/sensing roles in carbon partitioning. Glycolysis and starch synthesis diverge after the synthesis of Glc-6-P. Conversion of Glc-6-P to Glc-1-P by pdPGM commits carbon to starch synthesis. Thus, down-regulation of pdPGM will limit carbon flux into starch biosynthesis, which might explain why starch content was not higher in BCCP2 transgenic plants (Table I).

View larger version (53K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 3. Quantitative immunoblot analysis of glycolytic enzymes during seed filling in Arabidopsis. A, Protein expression during seed development was detected by immunoblotting with 20 µg of protein from 9-, 11-, and 13-DAF seeds from the wild type (ecotype Columbia [Col]) and BCCP2 overexpression lines 5-2 and 9-5. B, Quantitative, densitometric analysis of protein expression from immunoblots (A) in biological triplicate. To control for blot-to-blot variation, expression data were normalized to the highest value to obtain relative units. Data points are averages of three biological replicates, and error bars indicate SD. White triangles, Wild type; black squares, 5-2; black circles, 9-5.

The plastid PDC catalyzes the oxidative decarboxylation of pyruvate to form acetyl-CoA for de novo fatty acid synthesis in developing seeds and is composed of four subunits assembled into a complex over 4 MD in size (Mooney et al., 2002). In wild-type seeds, expression of plastid PDC subunits E1 (At1g01090), E1β (At1g30120), and E2 (At3g25820) peaked at 9 DAF, while E3 (At4g16155) peaked at 11 DAF. Compared with the wild type, all four plastid PDC subunits in both transgenic lines were coordinately reduced between 25% and 70% of wild-type levels beginning at 13 DAF, a 2-d delay from the induction of BCCP2 expression (Fig. 4 ).

View larger version (48K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 4. Quantitative immunoblot analysis of plastid PDC subunits during seed filling in Arabidopsis. A, Protein expression during seed development was detected by immunoblotting with 20 µg of protein from 9-, 11-, and 13-DAF seeds from the wild type (ecotype Columbia [Col]) and BCCP2 overexpression lines 5-2 and 9-5. E1, E1β, E2, and E3 refer to plastid pyruvate dehydrogenase subunits. B, Quantitative, densitometric analysis of protein expression from immunoblots (A) in biological triplicate. Expression data were normalized to the highest value to obtain relative units. Data points are averages of three biological replicates, and error bars indicate SD. White triangles, Wild type; black squares, 5-2; black circles, 9-5.

View larger version (51K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 5. Quantitative immunoblot analysis of plastid ACCase subunits during seed filling in Arabidopsis. A, Protein expression during seed development was detected by immunoblotting with 20 µg of protein from 9-, 11-, and 13-DAF seeds from the wild type (ecotype Columbia [Col]) and BCCP2 overexpression lines 5-2 and 9-5. -CT, β-CT, BC, and BCCP2 represent plastid ACCase subunits. B, Quantitative, densitometric analysis of protein expression from immunoblots (A) in biological triplicate. Expression data were normalized to the highest value to obtain relative units. Data points are averages of three biological replicates, and error bars indicate SD. White triangles, Wild type; black squares, 5-2; black circles, 9-5.

View larger version (29K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 6. Quantitative immunoblot analysis of cruciferin (CRA1) and oleosin during seed filling in Arabidopsis. A, Protein expression during seed development was detected by immunoblotting with 20 µg of protein from 9-, 11-, and 13-DAF seeds from the wild type (ecotype Columbia [Col]) and BCCP2 overexpression lines 5-2 and 9-5. B, Quantitative, densitometric analysis of protein expression from immunoblots (A) in biological triplicate. Expression data were normalized to the highest value to obtain relative units. Data points are averages of three biological replicates, and error bars indicate SD. White triangles, Wild type; black squares, 5-2; black circles, 9-5.

View larger version (47K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 7. Quantitative analysis of enzymes involved in fatty acid synthesis and modification. A, Protein expression during seed development was detected by immunoblotting with 20 µg of protein from 9-, 11-, and 13-DAF seeds from the wild type (ecotype Columbia [Col]) and BCCP2 overexpression lines 5-2 and 9-5. B, Quantitative, densitometric analysis of protein expression from immunoblots (A) in biological triplicate. Expression data were normalized to the highest value to obtain relative units. Data points are averages of three biological replicates, and error bars indicate SD. White triangles, Wild type; black squares, 5-2; black circles, 9-5.

	DISCUSSION

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

Disrupting a gene's expression and then comparing the metabolic changes between the wild type and knockout or loss-of-function mutants is a widely used approach for studying metabolic regulation. Since most metabolic activities play fundamental roles in cell function and therefore are expressed in multiple tissues and during different developmental stages, mutations such as T-DNA knockouts could have a profound impact on the plant, including cell death, making it difficult to distinguish between cause and consequence of the lesion (Mou et al., 2000). Conversely, other knockout mutations do not show any phenotype due to gene redundancy (Mhaske et al., 2005).

The reduced seed oil transgenic plants analyzed in this study have multiple unique properties that distinguish them from other metabolic mutants and make them attractive for studying carbon assimilation and partitioning in seeds. First, the perturbation is targeted to developing embryos instead of whole plants. Second, the disruption occurs in a rapid, temporal manner in 11-DAF seeds, approximately when reserve deposition begins. Third, protein complex activity is attenuated, not silenced, by a novel mechanism that we term "holo-protein competition." And fourth, a well-known complex, ACCase, the committed and highly regulated step for de novo fatty acid synthesis, is disrupted. However, as we are dealing with a transgenic mutation, it is possible that any phenotypic observation could be due to gene position effects. To control for this, two independent lines were analyzed. Systems biological analysis of this mutant allowed us to extract meaningful information about metabolic cross talk and the regulatory network surrounding fatty acid synthesis for oil reserve deposition in developing seeds, while eliminating the myriad pleiotropic consequences resulting from a true knockout or whole plant mutation. Even with this specific mutant, an unexpectedly complex picture emerges, which likely reflects the convoluted nature of plant metabolism.

Complementary Omics Techniques Indicate That Metabolic Regulation in Developing Seeds Occurs at Both Gene and Protein Levels

Transcriptional profiling with microarrays makes it possible to simultaneously analyze changes in mRNA levels for thousands of genes (Meyers et al., 2004). This method has already successfully confirmed that transcriptional regulation plays a major role in the control of countless processes involved in plant development and metabolism (Hennig, 2007). However, mRNA levels are not always reflective of changes in protein levels or enzyme activity; thus, this method also has its limitations (Gallardo et al., 2007; Sato et al., 2007). Proteomic approaches, on the other hand, allow one to directly investigate changes in protein expression, rather than to predict them from transcriptional data. Moreover, posttranslational modification of proteins can be directly detected using 2-DE, and when coupled to DIGE, over 1,000 protein spots can be resolved with only 50 µg of protein, ideal for diminutive Arabidopsis seeds. Since enzymes are the key control mechanisms for metabolic flow, in vivo proteomic data more closely reflect the situation in planta and therefore provide better insight into metabolic processes.

However, most proteomic approaches preferentially detect abundant proteins, frequently neglecting low-copy regulatory proteins. Likewise, protein detection may be saturated for highly abundant proteins, causing the differential expression of these proteins to be underestimated. Furthermore, 2D gel electrophoresis often underrepresents proteins with extreme hydrophobicity, mass, or pI (Santoni et al., 2000; Görg et al., 2004). Therefore, non-gel-based proteomics approaches, such as iTRAQ, are also needed, as we demonstrate here. The different results obtained by 2D-DIGE, gel-free iTRAQ, and microarray analyses highlight the technical advantages and limitations of each approach while simultaneously demonstrating the need to employ multiple approaches.

Our microarray findings and those of others (Ruuska et al., 2002) show that extensive transcriptional remodeling occurs in response to the attenuation of oil synthesis in developing Arabidopsis seeds. However, only a fraction of these differentially expressed transcripts were confirmed at the protein level by 2D-DIGE and iTRAQ, perhaps reflecting the incomplete nature of these approaches. In contrast, these proteomic approaches identified some differential proteins that were unaffected transcriptionally (e.g. oleosin, cruciferin, PDC subunits). To better clarify some of these discrepancies and to verify the reliability and reproducibility of the 2D-DIGE and iTRAQ results, quantitative protein blotting was performed.

Each of the four subunits to plastid PDC was down-regulated beginning at 13 DAF without a corresponding transcriptional change; therefore, posttranslational regulation may play some role in regulating protein turnover. In humans, the E1β-subunit to mitochondrial PDC is regulated by ubiquitination and proteasome-mediated degradation (Han et al., 2008). It is possible that plants have a similar mechanism for the regulation of this complex in plastids. The apparent posttranslational decrease in oleosin expression could be due to proteolysis, although there is no prior evidence for this. Conversely, the storage protein CRA1 cruciferin might be up-regulated through a different posttranscriptional or posttranslational mechanism, perhaps related to its sequestering in a specific subcellular compartment that allows it to avoid protein turnover.

Specific Glycolytic Activities Were Differentially Expressed in Response to Reduced Carbon Flow through de Novo Fatty Acid Synthesis

Considering the importance of glycolysis for providing acetyl-CoA precursors in developing B. napus embryos (Schwender and Ohlrogge, 2002), it is reasonable that glycolysis may exert distant control on fatty acid synthesis through carbon partitioning. This view is supported by a number of genetic studies. For example, mutation of pdPGM, an enzyme involved in controlling photosynthetic carbon flow in Arabidopsis, results in low oil content (Caspar et al., 1985; Periappuram et al., 2000). Similarly, a number of glycolytic enzymes (e.g. hexokinase, FK, phosphofructokinase, FBA, phosphoglycerate kinase, pdPGAM, enolase, and pyruvate kinase) were shown to be reduced in the wri1 mutant (Focks and Benning, 1998), although activity analyses were unable to discriminate between cytosolic and plastid forms. Proteomic analysis of nearly isogenic sunflower (Helianthus annuus) varieties differing in seed oil content also demonstrated that glycolytic enzymes, including enolase, FK, phosphofructokinase, phosphoglycerate kinase, and cytoplasmic PGM, are up-regulated in high-oil versus low-oil varieties (Hajduch et al., 2007). In BCCP2 overexpression lines, we found plastid glycolytic enzymes (i.e. pdPGM, PGAM, and FBA) to be down-regulated at the protein level and cytosolic glycolytic enzymes (i.e., cytoPGM and enolase) to be up-regulated (Fig. 3; Table II; Supplemental Table S1). Together, these findings suggest that glycolysis and de novo fatty acid synthesis pathways cross talk in developing Arabidopsis seeds. Our results further indicate that the status of de novo fatty acid synthesis may act as a "rheostat" on the expression of glycolytic enzymes.

The Biotin Synthesis Pathway Is Up-Regulated in Response to BCCP2 Overexpression

Biotin, a water-soluble vitamin synthesized by plants, some fungi, and most bacteria, is required by all living organisms for normal cellular function and growth. Biotin is a cofactor that plays a critical role in the catalytic mechanism for a number of enzymes that are essential in both catabolic and anabolic processes (Moss and Lane, 1971). A recent study indicated that biotin has multiple roles in regulating gene expression (Che et al., 2003). Interestingly, we also observed that overexpression of BCCP2 can stimulate biotin synthesis.

The biotin synthesis pathway in plants has been established, and the precursor for this pathway is Ala (Shellhammer and Meinke, 1990; Patton et al., 1996, 1998). Differentially expressed proteins and genes mapping to the biotin synthesis pathway are shown in Supplemental Figure S2; each is elevated in response to BCCP2 overexpression. The precursor Ala has two biosynthetic routes. In developing Arabidopsis seeds, pyruvate transamination is likely the primary path, as evidenced by the up-regulation of AOAT2 (At1g70580) at the protein level in transgenic BCCP2 seeds. In contrast, no gene is affected for the second pathway, a multistep pathway that converts Cys into Ala. Overexpression of BCCP2 and the concomitant attenuation of ACCase and plastid PDC (Fig. 5) likely results in a buildup of pyruvate, which could be transaminated into Ala for biotin synthesis. This view is supported by the up-regulation of genes and/or proteins beginning at the aminotransferase step and continuing with almost every step in the biotin synthesis pathway (Supplemental Fig. S2). Interestingly, BCCP2 and Bio2 transcription are coordinately regulated by WRI1 during seed maturation (Baud et al., 2007). Coregulation of BCCP2 and Bio2 may allow for biotin production in vivo to closely match the principal protein and enzyme complex requiring this cofactor.

A Metabolic Shift from Oil to Storage Protein Likely Goes through the TCA Cycle

In response to reduced ACCase activity in BCCP2 overexpression lines, expression levels of all four plastid PDC subunits were reduced, presumably reducing acetyl-CoA production and thereby increasing plastid pyruvate levels. Down-regulation of the upstream plastid glycolytic proteins FBA and PGAM may further reduce carbon flow into de novo fatty acid synthesis. In contrast to plastid glycolysis, expression of cytosolic glycolytic enzymes was enhanced, which may reflect a shift in metabolism toward organic and amino acid production for increased storage protein synthesis. Due to the down-regulation of PDC and ACCase (Fig. 8 ), it is possible that pyruvate is converted into acetyl-CoA in the mitochondria and enters the TCA cycle by forming citrate. Up-regulation of ATP-citrate lyase (At3g06650) and cytosolic malate dehydrogenase (At1g04410) suggests that a portion of the citrate is transported into the cytoplasm to produce acetyl-CoA by ATP-citrate lyase. The oxaloacetate that is produced can also be converted into malate by cytosolic malate dehydrogenase and transported into mitochondria. The metabolic consequence is to increase TCA cycle intermediates and cytosolic acetyl-CoA. This finding is also supported by a metabolic study of sse1, another low-oil mutant (Lin et al., 2006). In sse1, a decrease in fatty acid synthesis results in an increase in carbon into the TCA cycle, causing the total amount of TCA cycle intermediates to rise (Lin et al., 2006). A partial TCA cycle model is also consistent with the carbon shift away from fumarate in the TCA cycle, as observed in the metabolic study of sse1 (Lin et al., 2006). The TCA cycle and glycolysis help provide carbon skeletons for amino acid synthesis. The increase in TCA cycle intermediates as well as the up-regulation of aminotransferase class I and II family proteins (At5g04620; Supplemental Table S2) may increase free amino acid pools for enhanced storage protein synthesis (e.g. CRA1). Unlike the sse1 mutant, whose total seed protein is reduced, storage protein levels in BCCP2 transgenic lines are up-regulated during development. Thus, even though both of these mutants share a similar low seed oil phenotype, the effect on storage proteins appears to be different.

View larger version (71K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 8. Summary of global transcript and protein changes resulting from overexpression of BCCP2 within developing Arabidopsis seed. The plus symbol represents up-regulation in BCCP2 overexpression lines, and the minus symbol represents down-regulation for the indicated gene or protein. Black and red symbols represent transcript and protein changes, respectively. UDP-D-glu, UDP-D-Glc; G-1-P, β-D-Glc-1-P; F-6-P, D-Fru-6-P; F1,6-P, Fru-1,6-bisP; G-6-P, β-D-Glc-6-P; DHAP, dihydroxyacetone phosphate; GAP, D-glyceraldehyde-3-P; 3-PGA, 3-phosphoglycerate; 1,3-BPG, 1,3-diphosphoglycerate; 2-PGA, 2-phosphoglycerate; PEP, phosphoenolpyruvate; Pyr, pyruvate; Ac-CoA, acetyl-CoA; OAA, oxaloacetate; Cit, citrate; IsoCit, isocitrate; -KGA, -ketoglutarate; Suc-CoA, succinyl-CoA; Suc, succinate; Fum, fumarate; Mal, malate; Mal-CoA, malonyl-CoA; 1,2-DAG, 1,2-diacylglycerol; PC, phosphatidylcholine; TAG, triacylglycerol; VLCFA, very-long-chain fatty acid; E-4P, erythrose-4-P; R-5P, Rib-5-P; Ru-1,5-P2, ribulose-1,5-bisP; Ru-5P, ribulose-5-P; S-7P, sedoheptulose-7-P; Xu-5P, xylulose-5-P; PSV, protein storage vacuole; ER, endoplasmic reticulum; FADH, flavin adenine dinucleotide.

13

Summary of Metabolic Changes Resulting from Reduced Flux through de Novo Fatty Acid Synthesis in Developing Seeds

Extensive analysis of the targeted perturbation of ACCase enzyme activity in developing seeds suggests a coordinated series of metabolic changes in response to the attenuation of fatty acid synthesis (Fig. 8). Overexpression of BCCP2 did not affect the expression of other subunits (BC, -CT, and β-CT) in the ACCase complex. This lack of coordinated transcriptional regulation for other components in this complex is in contrast to the coordination with other enzyme complexes and in some cases pathways (e.g. biotin synthesis), and is the main reason for the dominant-negative nature of this mutation.

Fatty acid synthesis in developing seeds appears to be coordinated with precursor supply, produced by glycolysis and plastid PDC. When ACCase activity is attenuated, upstream enzymes and pathways respond, as revealed by a reduction in plastid PDC, Rubisco, and transketolase as well as an increase in cytosolic glycolytic activities. Additionally, many downstream de novo fatty acid and lipid synthesis enzymes were induced in response to the ACCase mutation.

Induction of many enzymes of the biotin synthesis pathway, in response to BCCP2 overexpression, provides another example of coordinated expression in closely related pathways (Fig. 8; Supplemental Fig. S2). This suggests that biotin synthesis and biotin-requiring proteins might undergo similar transcriptional regulation or share a transcriptional regulatory element or factor.

The major oil body protein, oleosin, was substantially down-regulated in both BCCP2 lines, although the transcript was invariant. At the same time, production of multiple storage proteins was enhanced, although no differences were observed for these genes by transcriptomics. Since storage proteins are the major protein component of mature seeds, collectively representing as much as 70% of the total protein composition in plant seeds (Hajduch et al., 2005, 2006), up-regulation of this class of proteins in addition to various amino acid biosynthetic activities (Fig. 8) appears to be the major metabolic response to reduced flux through de novo fatty acid synthesis.

	MATERIALS AND METHODS

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 

Plant Material

Wild-type and transgenic, napin-BCCP2 (T3 homozygous) Arabidopsis (Arabidopsis thaliana var Columbia) seeds were sown in moistened Pro-mix soil (Premier Horticulture) and grown under a 16-h-light/8-h-dark cycle, 23°C day/20°C night, 50% humidity, and light intensity of 200 µmol m^–2 s^–1. Flowers were tagged prior to opening, and siliques were harvested and seeds dissected at 9, 11, 13, or 15 DAF.

Lipid, Protein, and Carbohydrate Analysis

Mature seeds were harvested and air dried for analysis. Five or eight biological replicates for each line were used, and results were expressed on a dry mass basis. Sample preparation and analysis were conducted by following the procedure described by Siloto et al. (2006).

Total RNA Isolation, RNA Amplification, Biotin Labeling, and Hybridization to the Arabidopsis ATH1 GeneChips

One microgram of seed total RNA was used to make the biotin-labeled antisense RNA (aRNA) target using the MessageAmp II-Biotin Enhanced Single Round aRNA amplification kit (Ambion) following the manufacturer's procedures. Briefly, the total RNA was reverse transcribed to first-strand cDNA with an oligo(dT) primer bearing a 5'-T7 promoter using ArrayScript reverse transcriptase. The first-strand cDNA then underwent second-strand synthesis and cleanup to become the template for in vitro transcription. Biotin-labeled aRNA was synthesized using T7 RNA transcriptase with biotin-NTP mix. After purification, aRNA was fragmented in 1x fragmentation buffer at 94°C for 35 min. Ten micrograms of fragmented aRNA in 200 µL of hybridization solution was hybridized to Arabidopsis ATH1 GeneChips (Affymetrix) at 45°C for 20 h. After hybridization, chips were washed and stained with R-phycoerythrin-streptavidin on Affymetrix fluidics station 450 using fluidics protocol EukGE-WS2v4. Image data were acquired by Affymetrix GeneChip scanner 3000.

Microarray Data Analysis

Microarray data analysis for the two biological replicates for each of the wild-type and napin-BCCP2 line 9-5 samples was performed using GeneSpring GX 7.3 software (Silicon Genetics). Raw data (CEL files) were loaded into GeneSpring using Robust Multichip Average preprocessing. Array intensities were normalized using data transformation to set measurements of less than 0.01 to 0.01 per chip normalization to the 50th percentile and per gene normalization to median. Normalized data were log transformed to natural log values to calculate the expression value. Scatterplots of replicate arrays made after normalization showed highly reproducible data. After normalization, criteria of Student's t test with a P value cutoff of 0.05 and 1.5-fold changes were applied to identify significantly differentially expressed genes. Exactly 375 of the 22,810 transcripts (1.65%) were differentially expressed between the BCCP2 9-5 line and the wild type.

2D-DIGE

Total protein from approximately 0.1 g of 13-DAF wild-type and napin BCCP2 (both 5-2 and 9-5 lines) seeds was isolated as described previously (Mooney and Thelen, 2004). Protein labeling with N-hydroxysuccinimide-activated fluorescent dyes was performed according to the manufacturer's instructions (GE Healthcare). Sample was then applied to a 24-cm immobilized pH gradient strip (GE Healthcare), focused, and resolved by 12% SDS-PAGE as described previously (Hajduch et al., 2007). Preparative 2-DE with 1 mg of protein was performed as described by Hajduch et al. (2005).

DIGE Gel Imaging, 2-DE Analysis, and Protein Identification

DIGE gels were scanned using an FLA-5000 laser scanner (Fuji Medical). Images (16 bit TIFF) were analyzed using ImageMaster 2-D Platinum software (GE Healthcare). Protein abundance was expressed as relative volume according to the normalization method provided with ImageMaster software. Statistically significant (P < 0.05) differentially expressed proteins were selected using the t test algorithm in ImageMaster. Differentially expressed protein spots were excised from a corresponding preparative Coomassie Brilliant Blue-stained 2-DE gel and digested by trypsin as described previously (Hajduch et al., 2005). Liquid chromatography-MS/MS using an LTQ ion trap (Thermo-Fisher) was performed as described previously for 2-DE spots (Hajduch et al., 2006).

Tandem mass spectral data were searched against the protein complement of the Arabidopsis gene index version 6. Database searches were performed on a local licensed copy of SEQUEST as part of the BioWorks 3.2SR1 software suite (Thermo-Fisher). Search parameters were as follows: enzyme, trypsin; number of internal cleavage sites, 2; mass range, 400 to 2,000; threshold, 500; minimum ion count, 35; peptide mass tolerance, 1.50; variable modification, oxidation (M); static modification, carboxyamidomethylation (C). Matching peptides were filtered according to correlation scores (XCorr at least 1.5, 2.0, and 2.5 for +1, +2, and +3 charged peptides, respectively). For all protein assignments, a minimum of two unique, nonoverlapping peptides were required.

Peptide Labeling with iTRAQ Reagents

Protein was recovered from DIGE lysis buffer (30 mM Tris-HCl, pH 8.5, 7 M urea, 2 M thiourea, and 4% [w/v] CHAPS) by phenol extraction and methanol/ammonium acetate precipitation as described previously (Mooney and Thelen, 2004). The washed protein pellets were resuspended in buffer (8 M urea, 50 mM HEPES-KOH, pH 8.0, and 10 mM dithiothreitol) in a minimal volume and protein was quantified. An aliquot of each sample equivalent to 40 µg of protein was placed in a clean tube. Following reduction and alkylation of Cys residues and overnight trypsin digestion, iTRAQ labeling was performed according to the manufacturer's instructions (Applied Biosystems) with the following modification: in order to preserve the 60% ethanol conditions for iTRAQ labeling, each labeling reagent aliquot was resuspended in 300 µL of 100% ethanol and the entire contents of the vial was added to each sample as follows. The wild-type seed proteins were labeled with iTRAQ reagent 114, line 5-2 was labeled with reagent 115, and line 9-5 was labeled with reagent 116.

Liquid Chromatography of iTRAQ-Labeled Peptides

Following labeling, all reactions were combined and subjected to cation-exchange chromatography according to the manufacturer's instructions (iTRAQ reagent chemistry reference guide; Applied Biosystems). Six salt steps (750 µL each) were used to elute peptides from the column: 50, 100, 150, 200, 250, and 300 mM KCl in load buffer. The flow-through (unbound) fraction was also collected and analyzed. A further lyophilization step was included followed by reverse-phase column chromatography using a Dionex Ultimate 3000 HPLC system (Dionex) connected to a Probot Microfraction Collector (Dionex) for automated matrix-assisted laser-desorption ionization (MALDI) target spotting. Peptides were separated on a C18 PepMap 100 analytical column (15 cm long, 300 µm i.d., 3-µm particles; Dionex) using a continuous 30-min gradient of increasing acetonitrile. The Probot collected 400 fractions over 30 min (5 s per fraction) adding 1-cyano-4-hydroxycinnamic acid matrix (5 mg mL^–1 final concentration) directly to the column flow. Each salt step was fractionated onto a single OptiTOF MALDI target.

MALDI-Time of Flight-Time of Flight MS Analysis of iTRAQ Peptides and Database Querying

The instrument (Applied Biosystems 4700 Proteomics Analyzer) acquired spectra from 700 to 4,000 D. Peptide calibration standards (4700 calibration mix; Applied Biosystems) were used to calibrate the instrument in MS and MS/MS modes. Sample spots were then acquired, and spectra were processed to detect peaks with signal:noise > 5. Precursor ions for MS/MS were determined by a "job-wide" interpretation method as follows: signal:noise > 10, all common trypsin ions excluded within a 0.5-D mass tolerance, and no retention time filtering of trypsin ions. Precursor ions were excluded if within a resolution of 200 (full width at half maximum) and a fraction-to-fraction precursor mass tolerance was set at 200 ppm. A maximum of 10 precursors were selected per spot (fraction), and the minimum chromatogram peak width was set to 2 (spots/fractions) for MS/MS acquisition with collision-induced dissociation off. The National Center for Biotechnology Information nonredundant database limited to Viridiplantae (November 24, 2007 update) was searched using the MS/MS utility of GPS Explorer version 3.6 with integrated MASCOT search engine version 2.1. All peptide data (including intensity, ion score, iTRAQ ratios, etc.) were exported to Excel for calculation of average iTRAQ ratios for proteins.

Antibody Production

To produce antibody against pdPGM (At5g51820), cytoPGM (At1g23190), TPI (At3g55440), phosphoribulokinase (At1g32060), enolase (At2g36530), FK (At2g31390), PGAM (At1g09780), and β-glucosidase (At3g21370), the gene-coding sequences were PCR amplified from their cDNA clones using the primers listed in Supplemental Table S3.

Pfu DNA polymerase (Stratagene)-generated PCR fragments were directionally cloned into the Champion pET200 TOPO vector (Invitrogen). For expression, constructs were transformed into BL21 Star (DE3) One Shot cells. Recombinant proteins were purified under native or denaturing conditions using nickel-nitrilotriacetic acid agarose (Qiagen).

For antibody production, 500 µg of recombinant protein was provided to Cocalico Biologicals for rabbit antibody production. Native cytoTPI, enolase, and FK were used as antigen, and other proteins were provided denatured. Rabbits were boosted three times before exsanguination. Antibody quality was screened by western blotting against dilutions of recombinant protein.

Peptide antibodies against BHACP (At2g22230), BCCP-like (At1g52670), PAP2 (At3g15820), Bio2 (At2g43360), ADS1 (At1g06080), SAD (At5g16240), MOD1 (At2g05990), LACS9 (At1g77590), ATPDAT (At5g13640), FBA (At3g52930), and CRA1 (At5g44120) were developed by Sigma Genosys. Peptide sequences are listed in Supplemental Table S3.

Quantitative Immunoblot Analysis of Seed Proteins

Arabidopsis seeds from different developmental stages were harvested and homogenized in 400 µL of SDS-PAGE sample buffer (60 mM Tris-HCl, pH 6.8, 60 mM SDS, 5% [v/v] glycerol, and 100 mM dithiothreitol), heated at 95°C for 5 min, and centrifuged at 15,000g for 10 min. Protein (20 µg) from the supernatants was resolved by SDS-PAGE and transferred to nitrocellulose under standard conditions. Blots were probed as described previously (Thelen and Ohlrogge, 2002a) using horseradish peroxidase-conjugated secondary antibody and then covered with developing buffer for 1 min (Pierce ECL western blotting substrate; Thermo Scientific), after which the solution was removed and the blots were exposed to film. Images were quantified by ImageQuant TL software (GE Healthcare). Blotting was performed in biological triplicate, and protein volumes were normalized to the highest value in the experimental series.

Supplemental Data

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

Supplemental Figure S1. Two-dimensional gel immunoblot analyses to confirm BCCP induction and isoelectric species diversity in developing seeds of wild-type and BCCP2 overexpression lines.

Supplemental Figure S2. Biotin synthesis pathway and differentially expressed genes in the pathway.

Supplemental Table S1. Summary of differentially expressed proteins between wild-type and BCCP2 transgenic plants identified by gel-free iTRAQ.

Supplemental Table S2. Transcriptional profiling with 375 microarray-identified genes differentially expressed between the wild type and BCCP2 overexpression line 9-5 based on 1.5-fold change.

Supplemental Table S3. Oligonucleotide primers and synthetic peptides used for heterologous expression of Arabidopsis proteins and peptide antibody production, respectively.

	ACKNOWLEDGMENTS

 
We thank Melody Kroll for editing this manuscript.

Received December 30, 2008; accepted February 27, 2009; published March 11, 2009.

	FOOTNOTES

 
¹ This work was supported by the National Science Foundation (Plant Genome Research Program Young Investigator award no. DBI–0332418 to J.J.T.) and by a University of Missouri Life Science Fellowship to M.C.

² Present address: Institute of Plant Genetics and Biotechnology, Slovak Academy of Sciences, Akademicka 2, P.O. Box 39A, SK–650 07 Nitra, Slovak Republic.

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: Jay J. Thelen (thelenj{at}missouri.edu).

^[W] The online version of this article contains Web-only data.

^[OA] Open Access articles can be viewed online without a subscription.

www.plantphysiol.org/cgi/doi/10.1104/pp.108.134882

^* Corresponding author; e-mail thelenj{at}missouri.edu.

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