wrinkled1: A Novel, Low-Seed-Oil Mutant of Arabidopsis with a Deficiency in the Seed-Specific Regulation of Carbohydrate Metabolism

doi:10.1104/pp.118.1.91

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wrinkled1: A Novel, Low-Seed-Oil Mutant of Arabidopsis with a Deficiency in the Seed-Specific Regulation of Carbohydrate Metabolism¹

Nicole Focks and Christoph Benning^*

Institut für Genbiologische Forschung Berlin GmbH, Ihnestrasse 63, 14195 Berlin, Germany (N.F., C.B.); and Department of Biochemistry, Michigan State University, East Lansing, Michigan 48824-1319 (C.B.)

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

During oil deposition in developing seeds of Arabidopsis, photosynthate is imported in the form of carbohydrates into theembryo and converted to triacylglycerols. To identify genes essentialfor this process and to investigate the molecular basis for thedevelopmental regulation of oil accumulation, mutants producingwrinkled, incompletely filled seeds were isolated. A novel mutantlocus, wrinkled1 (wri1), which maps to the bottom of chromosome3 and causes an 80% reduction in seed oil content, was identified.Wild-type and homozygous wri1 mutant plantlets or mature plantswere indistinguishable. However, developing homozygous wri1 seedswere impaired in the incorporation of sucrose and glucose intotriacylglycerols, but incorporated pyruvate and acetate at anincreased rate. Because the activities of several glycolytic enzymes,in particular hexokinase and pyrophosphate-dependent phosphofructokinase,are reduced in developing homozygous wri1 seeds, it is suggestedthat WRI1 is involved in the developmental regulation of carbohydratemetabolism during seed filling.

INTRODUCTION

Top
Abstract
Introduction
Methods
Results
Discussion
References

Following morphogenesis, developing embryos of Arabidopsis accumulate lipids in the form of triacylglycerols as the majorcarbon and energy reserves, which are then used for germinationand growth of the young seedling. The triacylglycerols are storedin oil bodies that occupy close to 60% of the cell volume of thecotyledons in mature embryos (Mansfield and Briarty, 1992). Inthis respect, Arabidopsis resembles the closely related crop plantcanola, which is an important source of commercial seed oil. Manyaspects of fatty acid biosynthesis and modification in developingseeds are well established (Miquel and Browse, 1994; Ohlroggeand Browse, 1995; Harwood, 1996), and much of our knowledge isderived from a large number of mutants of the model plant Arabidopsis(Browse and Somerville, 1994). Furthermore, schemes have beendeveloped (and some have already been successfully implemented)to modify the fatty acid composition of seed oils by genetic engineering(Kinney, 1994; Ohlrogge, 1994; Töpfer et al., 1995). Nevertheless,little is known about the molecular basis for the developmentalregulation of triacylglycerol biosynthesis in developing oilseeds(Ohlrogge and Jaworski, 1997). A number of mutants of Arabidopsis,including fus3, lec1, and tag1, that do not accumulate triacylglycerolsin their seeds to the same extent as the wild type have been isolated(Bäumlein et al., 1994; Meinke et al., 1994; Katavic et al.,1995). FUS3 and LEC1 presumably encode more general regulatorsof late embryo development (Parcy et al., 1997) rather than factorsspecifically governing triacylglycerol biosynthesis. On the contrary,TAG1 has been proposed to encode a diacylglycerol acyltransferase(Katavic, 1995), but may also be involved in regulatory aspectsof triacylglycerol biosynthesis, based on the complex phenotypeof developing tag1 mutant seeds.

Another poorly understood aspect of developing oilseeds is the conversion of carbohydrates provided by photosynthesis intoprecursors of fatty acid biosynthesis. In canola the photoassimilateSuc is produced primarily by the silique wall during the seed-fillingstage and is imported into the embryo, where it is cleaved bySuc synthase into UDP-Glc and Fru (King et al., 1997). The preciseroute(s) of conversion of these two metabolites is less clear.At least two glycolytic pathways, one cytosolic and the otherplastidic, are operational in leaf tissues (Plaxton, 1996), andexperiments with plastids isolated from developing embryos ofcanola suggest that a complete glycolytic pathway is also presentin these plastids (Kang and Rawsthorne, 1994). Of the differentsubstrates supplied to plastids from developing seeds, pyruvateand Glc-6-P supported the highest rates of fatty acid biosynthesis.In the same study it was also shown that plastids of developingseeds contain high pyruvate decarboxylase activity, which is requiredfor the conversion of pyruvate to acetyl-CoA, which is carboxylatedto malonyl-CoA, the precursor for fatty acid biosynthesis. Glc-6-Pwas the most efficient substrate for the biosynthesis of starchthat intermittently accumulates in plastids of canola during seeddevelopment (Kang and Rawsthorne, 1994). Furthermore, Glc-6-Pis thought to be metabolized via the oxidative pentose phosphatepathway, a process that apparently provides NADPH for fatty acidbiosynthesis (Kang and Rawsthorne, 1996).

Although canola seems to be more suitable for the physiological approach described above, its close relative Arabidopsis isthe better genetic model organism. To dissect the pathway(s) ofcarbohydrate metabolism and to identify genes essential for theregulation of carbon partitioning and triacylglycerol biosynthesisin developing oilseeds, we began to search for genetic mutantsof Arabidopsis that would produce seeds with reduced oil content.In an attempt to identify the metabolic defect in these mutants,we determined the amounts of triacylglycerols, proteins, and carbohydrates,as well as the activity of enzymes involved in carbohydrate metabolismin developing seeds of Arabidopsis.

	MATERIALS AND METHODS

Top Abstract Introduction Methods Results Discussion References

Plant Material

Seeds of Arabidopsis ecotypes Columbia (Col-2) or Landsberg erecta (Ler) were surface sterilized according to the method ofEstelle and Somerville (1987)

and germinated on Murashige-Skoogmedium (Murashige and Skoog, 1962

) solidified with 1% agarose.The plates were transferred to growth chambers after a cold treatmentof 1 to 3 d at 4°C in the dark, and incubated at 20°C/15°C day/nighttemperatures under a 16-h/8-h light/dark regime (100 µmol m² s¹). After approximately 2 weeks, the plantlets were transferredto soil (Einheitserde type P: Einheitserde type T:sand [4:2:3],Gebrüder Patzer, Sinntal-Jossa, Germany) and grown under thesame conditions as before. For determination of growth, aerialparts of six different plants per line were weighed every 5 dfor up to 50 d following the transfer to soil. To harvest siliquesof defined developmental stages, individual flowers were taggedusing colored threads on the day of flowering. Only primary shootswere used; secondary shoots were removed.

Mutant Screening and Genetic Mapping

A previously described mutagenized M₂ population of Col-2 was used for the mutant screening (Dörmann et al., 1995

). Putativelow-seed-oil mutants were preselected either by visual examinationof M₂ seeds for wrinkledness or according to density by centrifugationof M₂ seeds in a mixture of 1-bromohexan (density 1.176) and 1,6-dibromohexan(density 1.589). For this purpose, about 8,000 seeds each of the20 independent M₂ batches were suspended in 1 mL of this mixturein a 1.5-mL reaction vessel and centrifuged for 5 min at 16,000g.The ratio of the two solvents was empirically adjusted to givea density such that about 5% of the seeds collected at the bottomof the tube. The bulk of the seeds floating on top was discarded.To remove the organic solvent, the seeds were washed three timesin light silicon oil, which is inert but miscible with the twoorganic solvents. The seeds were surface sterilized and germinatedon Murashige-Skoog medium supplemented with 1% Suc as describedabove.

Prior to detailed analysis selected wri mutants were backcrossed three times to the Col-2 wild type. For mapping purposesthe wri1-1 mutant was crossed with the Ler wild type. WrinkledF₂ seeds were visually selected and germinated. Homozygous mutantplants were confirmed by examining F₃ seeds for wrinkledness andlow-oil content. DNA was isolated from individual F₂ plants accordingto the method of Edwards et al. (1991) and used as a templatefor PCR-based markers, either cut, amplified polymorphic sequences(Konieczny and Ausubel, 1993) or simple-sequence-length polymorphisms(Bell and Ecker, 1994).

Lipid and Protein Analysis

For triacylglycerol quantification, 10 seeds were ground in a 1.5-mL polypropylene test tube with a glass rod, and lipidswere extracted in 50 µL of chloroform:methanol:formic acid (10:10:1,v/v). Following the extraction with 12.5 µL of 1 M KCl and 0.2M H₃PO₄ and separation of the organic and aqueous phases by centrifugationat 16,000g for 5 min, the lipids in the lower phase were separatedon a silica TLC plate (Si 250 PA, J.T. Baker, Philipsburg, NJ)developed with hexane:diethylether:acetic acid (60:40:1, v/v).Lipids were visualized by staining with iodine vapor. For quantificationof triacylglycerols by GLC of the corresponding fatty acyl methylesters, 10 seeds were ground directly in a glass reaction tubeand incubated in 1 mL of 1 N methanolic HCl at 80°C for 2 h. Fattyacyl methyl esters were extracted into 1 mL of hexane followingthe addition of 1 mL of 0.9% (w/v) NaCl. Myristic acid was usedas an internal standard and GLC was performed as described previously(Rossak et al., 1997

For quantification of total seed protein, 20 seeds were homogenized in 250 µL of acetone in a 1.5-mL polypropylene test tube.Following centrifugation at 16,000g, the supernatant was discardedand the vacuum-dried pellet was resuspended in 250 µL of extractionbuffer containing 50 mM Tris-HCl, pH 8.0, 250 mM NaCl, 1 mM EDTA,and 1% (w/v) SDS. Following incubation for 2 h at 25°C, the homogenatewas centrifuged at 16,000g for 5 min and 200 mL of the supernatantwas used for protein measurements employing the Lowry DC proteinassay (Bio-Rad). Protein in enzyme extracts of developing seedswas quantified using the Bradford assay (Bio-Rad). In both assays $gamma$ -globulin was used for calibration.

Carbohydrate Analysis

For the extraction of soluble sugars and starch, 50 seeds were homogenized in 500 µL of 80% (v/v) ethanol in a 1.5-mL polypropylenetest tube and incubated at 70°C for 90 min. Following centrifugationat 16,000g for 5 min, the supernatant was transferred to a newtest tube. The pellet was extracted twice with 500 µL of 80% ethanol.The solvent of the combined supernatants was evaporated at roomtemperature under a vacuum. The residue was dissolved in 50 µLof water, representing the soluble carbohydrate fraction. Thepellet left from the ethanol extraction, which contained the insolublecarbohydrates including starch, was homogenized in 200 µL of 0.2N KOH, and the suspension was incubated at 95°C for 1 h to dissolvethe starch. Following the addition of 35 µL of 1 N acetic acidand centrifugation for 5 min at 16,000g, the supernatant was usedfor starch quantification.

To quantify soluble sugars, 10 µL of the sugar extract was added to 990 µL of reaction buffer containing 100 mM imidazole,pH 6.9, 5 mM MgCl₂, 2 mM NADP, 1 mM ATP, and 2 units mL¹ of Glc-6-P dehydrogenase. For enzymatic determination of Glc,Fru, and Suc, 4.5 units of hexokinase, 1 unit of phosphoglucoisomerase,and 2 µL of a saturated fructosidase solution were added in succession.The production of NADPH was followed photometrically at a wavelengthof 340 nm. Similarly, starch was assayed in 30 µL of the insolublecarbohydrate fraction with a kit from Boehringer Mannheim.

Feeding of Labeled Precursors

For incorporation studies, 20 Arabidopsis seeds of each of the developmental stages were removed from two tagged siliquesand transferred to 100 µL of 100 mM Hepes buffer, pH 7.4. Theseed coat was not removed. The following ¹⁴C-labeled compounds were added in the concentrations and specificactivities indicated: [U-¹⁴C]Suc (DuPont/NEN), 34 mM, 2.5 GBq mol¹; D-[U-¹⁴C]Glc (Amersham), 34 mM, 2.5 GBq mol¹; [2-¹⁴C]pyruvate (DuPont/NEN), 1 mM, 25 GBq mol¹; or [1-¹⁴C]acetate (Amersham), 1 mM, 90 GBq mol¹. If not otherwise mentioned in the text, the seeds were incubatedunder gentle rocking for 18 h in the light (100 µmol m² s¹). Following incubation, the seeds were washed with 800 µL ofwater. Triacylglycerols were extracted and separated by TLC asdescribed above. Silica material containing the triacylglycerolswas transferred from the TLC plate into scintillation cocktailand radioactivity was determined by scintillation counting.

Preparation of Protein Extracts and Enzyme Assays

To determine the activity of different enzymes in developing embryos, approximately 400 seeds from 12 to 15 siliques taken9 to 11 d after flowering (if not otherwise indicated) were transferredinto 100 µL of chilled (4°C) extraction buffer containing 50 mMHepes-KOH, pH 7.4, 5 mM MgCl₂, 1 mM EDTA, 1 mM EGTA, 1 mM DTT,2 mM benzamidine, 2 mM $epsilon$ -amino-n-caproic acid, 0.5 mM PMSF, 0.1%(w/v) fatty acid-free BSA, 10% (v/v) glycerol, and 0.1% (w/v)Triton X-100 (Geigenberger and Stitt, 1993

). The subsequent manipulationswere at 4°C. Seeds were homogenized in 1.5-mL polypropylene testtubes using a motor-driven mortar. Following the addition of 400µL of chilled buffer, gentle rocking for 10 min, and centrifugationat 16,000g for 10 min at 4°C, the supernatant was desalted onNAP-5 columns (Pharmacia) equilibrated with the extraction buffer.The proteins were eluted with 1 mL of extraction buffer, and 200-µLaliquots were frozen in liquid nitrogen prior to storage at $-$ 70°C.

The following enzymes were assayed as previously described: hexokinase (EC 2.7.1.1) and fructokinase (EC 2.7.1.4) accordingto the method of Renz et al. (1993); phosphoglucoisomerase (EC5.3.1.9), ATP-dependent 6-phosphofructokinase (EC 2.7.1.11), pyrophosphate-dependent6-phosphofructokinase (EC 2.7.1.90), Fru-1,6-bisphosphate aldolase(EC 4.1.2.13), triose phosphate isomerase (EC 5.3.1.1), glyceral-3-Pdehydrogenase (EC 1.2.1.12), phosphoglycerate kinase (EC 2.7.2.3),phosphoglycerate mutase (EC 5.4.2.1), enolase (EC 4.2.1.11), andpyruvate kinase (EC 2.7.1.40) according to the method of Burrellet al. (1994); and UDP-Glc-pyrophosphorylase (EC 2.7.7.9) accordingto the method of Zrenner et al. (1995). In the pyruvate kinaseassay, the reaction buffer was modified to a pH of 7.25. Differentamounts of extract were used, depending on the enzyme activity,to give a linear reaction for over 5 min. All assays were performedin a double-beam spectral photometer (model Uvicon 930, KontronInstruments, Milano, Italy) equipped with a cell changer (model900, Kontron).

	RESULTS

Top Abstract Introduction Methods Results Discussion References

Isolation of wri Mutants

For the isolation of low-oil-seed mutants, one has to take into consideration that tissues of different genetic constitutionare involved in the photoassimilation and import of carbohydratesand their conversion into oil. In Arabidopsis, photoassimilatesare produced primarily by maternal tissues, but the biosynthesisof seed oil is a function of embryonic tissues. Accordingly, withthe possible exception of apoplastic carbohydrate-modifying enzymessuch as invertases or carbohydrate transporters in the adjacentmaternal tissues, the genome of the embryo encodes the enzymesrequired for the conversion of carbohydrates into triacylglycerols.Thus, screening of M₂ seeds permits the identification of embryosthat carry a homozygous recessive mutation specifically affectingthe accumulation of oil.

Following selfing, the corresponding homozygous M₂ plants should exclusively produce seeds with low-oil content. To avoidthe redundant isolation of embryo-lethal mutants with defectsin many different aspects of development (Müller, 1963; Meinke,1991), we did not examine developing M₂ seeds still attached tothe M₁ plants, but screened bulked M₂ seeds and assumed that thosewith low-oil content were still able to germinate in the presenceof an external carbon source. To identify M₂ seeds with low-oilcontent, we used two selection procedures, one based on the assumptionthat seeds with reduced storage material accumulation are notcompletely filled and look wrinkled, and a second that assumedthat seeds with reduced oil content should be slightly more densedue to the low specific gravity of oil. For this purpose we centrifugedbulked M₂ seeds in a mixture of 1-bromohexan and 1,6-dibromohexan,adjusting the ratio of both solvents to an overall density suchthat approximately 5% of the seeds collected at the bottom ofthe tube, whereas 95% floated on top of the solvent. Afterward,the toxic solvent was removed by repeated suspension in lightsilicone oil. We used this nonaqueous system to avoid changesin seed density due to the uptake of water during the procedure.

Regardless of the chosen selection procedure, M₂ seeds were germinated in the presence of Suc and M₃ seeds were examined foroil content by TLC. Screening 8000 seeds each of 20 independentM₂ batches, we recovered 300 putative M₂ mutant plants, 30 ofwhich produced a large fraction (more than 50%) of wrinkled seeds.Figure 1 shows homozygous seeds of two allelic lines, designatedwri1-1 and wri1-2. The average weight of air-dried seeds was reducedfrom 17 µg per seed for the Col-2 wild type to approximately 14µg per seed for both mutant lines (50 seeds were weighed; n =3; SE < 1 µg). TLC of lipid extracts showed a reduction of theseed-oil content in homozygous wri1 seeds, as depicted in Figure2, and quantification of the fatty acids bound in triacylglycerolsconfirmed an 80% reduction in oil content from approximately 3.2µg for a single mature wild-type seed to 0.6 µg for a wri1 seed.Apparently, the observed reduction in seed weight can be attributedto the loss of seed oil.

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Figure 1. Appearance of wild-type (A), wri1-1 (B), and wri1-2 (C) mature seeds.

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Figure 2. TLC of lipid extracts from mature seeds of wild type, homozygous mutant wri1-1 and wri1-2 seeds, and F₁ seeds derived from reciprocal crosses between wild-type (Col-2) and mutant plants as indicated. Only the upper portion of the TLC plate is shown. Triacylglycerols (TAG) were visualized by exposure to iodine vapor.

Inheritance of the Low-Oil, Wrinkled Seed Trait and Mapping of wri1-1

Unfortunately, a number of unfavorable environmental factors, including poor watering, aphid infections, or temperature increasesin the greenhouse during seed setting, can cause Arabidopsisto produce wrinkled seeds. Furthermore, during the course of thisstudy we discovered that Col-2 wild-type plants often producea few slightly wrinkled seeds. Thus, to sort out false-positiveputative wri mutants, we had to apply a rigorous genetic analysis.Contrary to many of the other putative wri mutant lines, the phenotypeof wri1-1 and wri1-2 could be easily followed through multiplerounds of backcrosses. As shown in Figure 2, F₁ seeds derivedfrom backcrosses contained oil amounts comparable to those ofthe wild type. The segregation of wrinkled seeds in differentF₂ populations following reciprocal crosses with wild-type plantsof ecotypes Col-2 and Ler is shown in Table I. Visual examinationrevealed the fraction of wrinkled seeds to be between 25% and18%, close to the 3:1 ratio expected for the segregation of asingle recessive nuclear mutation. However, presumably due tothe low germination rate (20%-50%, depending on the storage time)of homozygous wri1 seeds, the recovery of homozygous wri1 F₂ plantsproducing exclusively wrinkled seeds was less than 10%.

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Table I. Segregation of F₂ seeds according to seed shape determined by visual examination under a dissecting microscope

Values shown in parentheses are percentage of total.

Crosses between homozygous wri1-1 and wri1-2 plants produced only seeds with low oil contents (Fig. 2), indicating the lackof complementation and suggesting that the two lines harbor differentmutant alleles of wri1. From a cross between wri1-1 and the Lerwild type, we collected 49 F₂ plants homozygous for wri1-1 asconfirmed by analysis of F₃ seeds. These F₂ plants provided thebasis for a mapping population that was tested with 16 differentPCR-based DNA markers mapping at locations spread over the completegenome. Of all of the markers tested, we observed tight linkageof wri1-1 to nga707 placed at 110.1 cM on chromosome number threeaccording to the map posted by the Arabidopsis Genome Center atthe University of Pennsylvania (http://cbil.humge.upenn.edu/atgc/images/chr3map.gif; as of February, 1998) and less tight linkage to AthGAPabplaced at 77.1 cM. Based on our data, the calculated map distancebetween wri1-1 and nga707 was 6.4 ± 2.6 cM and between wri1-1and AthGAPab, 43.6 ± 9.7 cM.

The Primary Phenotype of wri1 Mutants

The morphology and growth of wri1 mutant plants was not affected. Figure 3 shows time courses of fresh weight gainsduring plant development of backcrossed wri1 mutants and the Col-2wild type. No striking differences between the mutants and thewild type were observed. Photosynthetic quantum yields as determinedfrom steady-state chlorophyll fluorescence measurements were indistinguishablefor the wild-type and mutant lines (data not shown). Furthermore,the number of siliques per plant as well as the number of seedsper silique were not altered in the wri1 mutants (data not shown).Early morphogenesis of the embryo as observed by light microscopywas indistinguishable in the mutants and the wild type (data notshown); however, during the seed-filling stage triacylglycerolsaccumulated at a much lower rate in the mutant, and the finalamount of triacylglycerols in mature wri1 mutant seeds was reducedby approximately 80% (Fig. 4A). A comparison of the fatty acidcomposition of triacylglycerols extracted from mature wild-typeand homozygous wri1 mutant seeds is shown in Table II. The relativeamounts of end products of desaturation and elongation, 18:3 (linolenicacid) and particularly 22:1 (erucic acid), were drastically increasedin the remaining seed oil of the mutants, whereas the relativeamounts of the intermediates of desaturation, 18:1 (oleic acid)and 18:2 (linoleic acid), were strongly reduced.

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Figure 3. Growth of wild-type ( $black-square$ ), wri1-1 ( $open circle$ ), and wri1-2 ( $triangle$ ) mutant plants in soil. For each time point, the fresh weights of aerial parts from six plants were averaged and the SEs are indicated.

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Figure 4. Time courses of triacylglycerol (TAG), protein, and carbohydrate accumulation in developing seeds of the wild type ( $black-square$ ), wri1-1 ( $open circle$ ), and wri1-2 ( $triangle$ ) mutant. A, Triacylglycerols; B, total protein; C, starch; D, Suc; E, Glc; F, Fru. Each time point represents duplicate (A-C) or triplicate (D-F) measurements and SEs are indicated.

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Table II. Fatty acid composition of mature wild type and mutant wri 1-1 and wri 1-2 seeds

Values are ±SE; n = 3.

As shown in Figure 4B, there were only subtle differences in the time courses of protein accumulation during seed developmentbetween the mutants and the wild type. It appears that young mutantseeds contain more protein, whereas mature mutant seeds containslightly less than wild-type seeds. Because the amount of totalprotein was determined, we confirmed by PAGE of the extracts thatthe bulk of the protein in mature seeds is represented by thedifferent 12S and 2S storage proteins (data not shown).

Soon after flowering, wild-type seeds of Arabidopsis accumulate starch that is degraded during maturation of the seeds (Fig.4C). This starch is present in the plastids of embryo cells butalso in seed coat cells, as was confirmed by microscopy followingstarch-specific iodine staining (data not shown). The maximalamount of starch was observed on d 7 after flowering. Higher amountsof starch intermittently accumulated in wri1 mutant seeds witha maximum on d 9, but the same low amounts of starch were observedin mature seeds of the wild type and the wri1 mutants. Furthermore,the amounts of soluble sugars, including Suc, Glc, and Fru, wereelevated throughout development of wri1 mutant seeds (Fig. 4,D-F). At d 11 after flowering, the relative amounts of all threesoluble sugars were more than 5-fold increased in the mutant seeds.Mature mutant seeds contained approximately twice as much Suc.Unlike triacylglycerols, Suc is dissolved in water that is partiallylost during maturation of the seed. The resulting reduction inseed volume in combination with a low elasticity of the seed coat,may be the cause for the wrinkled appearance of the mutant seeds(Fig. 1). By a similar reasoning, the appearance of wrinkled peaseeds, which was originally studied by Mendel, has been explained(Wang and Hedley, 1991).

Incorporation of Different Precursors into Triacylglycerols

The reduced accumulation of oil but increased accumulation of carbohydrates in developing wri1 mutant seeds suggested thatthe conversion of carbohydrates into precursors of fatty acidand triacylglycerol biosynthesis may have been adversely affected.To investigate this possibility, we isolated seeds of differentdevelopmental ages from siliques and incubated them with radioactivelylabeled Suc, Glc, acetate, and pyruvate for 18 h in the light.Subsequently, we determined the incorporation of label into triacylglycerols.Taking samples at different times during the 18-h incubation periodand testing the four labeled precursors at various specific activities,we ensured that the incorporation rate was linear during the courseof the entire experiment under the conditions used (data not shown).The results of one representative experiment for each compoundtested are given in Figure 5.

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Figure 5. Incorporation of different precursors into triacylglycerol by developing embryos of the wild type ( $black-square$ ), wri1-1 ( $open circle$ ), and wri1-2 mutant ( $triangle$ ). Tested compounds were Suc (A), Glc (B), pyruvate (C), and acetate (D). The rates are expressed as picomoles of precursor converted to triacylglycerol per 20 seeds per hour. Single representative experiments are shown.

Following the course of triacylglycerol accumulation during development (Fig. 4A), the incorporation of each of the compoundsinto triacylglycerols reached a maximum at d 11 after flowering.The wri1 mutant seeds showed a drastically decreased incorporationof the carbohydrates Suc and Glc (Fig. 5, A and B) and a similarlydrastic increase in the incorporation of the precursors of fattyacid biosynthesis, acetate and pyruvate (Fig. 5, C and D). Inthe case of the two carbohydrates, one could assume that the labeledsugar molecules were diluted in the mutant seeds due to increasedsoluble sugar pools (Fig. 4, D and E). However, the developmentalprofile of the differences in soluble sugar content between wild-typeand mutant seeds did not match the profile for the incorporationof labeled carbohydrates, with a sharp maximum at around d 11(Fig. 5, A and B). Therefore, the results are in agreement witha block in the conversion of carbohydrates into precursors offatty acid biosynthesis such as pyruvate or acetate.

The increased incorporation of pyruvate and acetate into triacylglycerols by the mutant seeds suggested that fatty acid biosynthesisand triacylglycerol assembly are not affected in the mutant. Furthermore,we assume that the pools of precursors for fatty acid biosynthesismay be decreased in the mutant seeds as a possible cause for theincreased incorporation of these two precursors. However, thedetermination of pyruvate or acetyl-CoA pools in the limited amountof tissue provided by developing seeds of Arabidopsis is currentlybeyond our technical abilities.

Activity of Different Carbohydrate-Metabolizing Enzymes

The accumulation of carbohydrates in developing seeds of the two wri1 mutants (Fig. 4) and the results of the incorporationexperiments (Fig. 5) suggested that the primary metabolic defectis in the conversion of carbohydrates into precursors of fattyacid biosynthesis. To identify the biochemical lesion in the wri1mutants, we determined the activity of different glycolytic enzymesin developing seeds collected during the peak of metabolic activityas indicated by the precursor incorporation rates (9-11 d afterflowering). In addition, we measured the activity of UDP-Glc pyrophosphorylase,which catalyzes the conversion of UDP-Glc to Glc-1-P. The activitieswere normalized on the basis of the total protein content of theextracts, which did not differ between the mutants and the wildtype (Fig. 4B). The results of these experiments are summarizedin Table III. It is immediately apparent that several glycolyticenzymes are affected in the wri1 mutants. In particular, the activityof hexokinase was reduced to approximately 17% and that of pyrophosphate-dependentphosphofructokinase to approximately 38% in the wri1 mutants.

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Table III. Activities of different enzymes involved in Glc metabolism in the wild type and in wri1 mutants

Values are ± SE; n = 3.

Furthermore, five enzymes (fructokinase, aldolase, phosphoglycerate mutase, enolase, and pyruvate kinase) showed a reductionin activity to 60% in the mutants. The activity of phosphoglyceratekinase was only slightly reduced to 84%, whereas the activitiesof phosphoglucose isomerase, ATP-dependent phosphofructokinase,triose phosphate isomerase, and glyceraldehyde dehydrogenase remainedunchanged within the statistical limitations of the experiment.Of all of the enzymes tested, only the activity of UDP-Glc pyrophosphorylaseshowed a slight increase in the wri1 mutants. To examine the effecton the developmental regulation of enzyme activity, we determinedthe activity of the two most severely affected enzymes duringthe course of seed development in the wild type and the wri1-1mutant. As indicated in Figure 6A, the activity of hexokinaseincreased during wild-type seed development and approached a maximum11 d after flowering. On the contrary, no increase in hexokinaseactivity was observed in the mutant.

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Figure 6. Activity of hexokinase (A) and pyrophosphate-dependent phosphofructokinase (PFP) (B) in developing embryos of the wild type ( $black-square$ ) and the wri1-1 ( $open circle$ ) mutant. Measurements were done in triplicate and SEs are indicated. Prot., Protein.

Similarly, the activity of pyrophosphate-dependent phosphofructokinase increased in the wild type during seed developmentbut decreased in the wri1 mutant. These results suggest that basicactivities of both enzymes are maintained, but that the seed-specificdevelopmental regulation of their activity is abolished in thewri1 mutants. In an attempt to provide corroborating evidencefor this hypothesis, we examined the activity of these two enzymesin leaves of the wild type and the wri1 mutants. The activityof hexokinase in leaves of the wild type and the mutants was identicalwithin the statistical limitations (0.9 nmol min¹ mg¹ protein), and the activity of pyrophosphate-dependent phosphofructokinasewas below the detection limit in both.

	DISCUSSION

Top Abstract Introduction Methods Results Discussion References

The wri1 Phenotype Is Seed Specific

Employing a simple screening procedure based on density centrifugation and visual examination of M₂ seeds, wri1, a novel mutantlocus of Arabidopsis that causes wrinkledness of the seed anda strong reduction in the accumulation of seed oil, has been identified.No differences between the wild-type and mutant plants were observed,in particular with respect to the number of siliques or seeds,a factor that could affect seed filling. In addition, geneticanalysis revealed that the genotype of the embryo but not thatof the maternal tissues determines the observed seed phenotype.Thus, a deficiency in maternal tissues causing a limitation inthe supply of photosynthate to the embryo can be ruled out asthe cause for the low-oil content of homozygous wri1 seeds.

Carbohydrate Metabolism Is Affected in the wri1 Mutant

Several lines of evidence suggest that the wri1 mutant is not directly affected in fatty acid or triacylglycerol biosynthesis,but is affected in the conversion of Glc into fatty acid precursors.First, the amounts of hexoses and Suc are increased in developingwri1 mutant seeds. Second, labeled Suc or Glc supplied to developingseeds are incorporated at reduced rates into triacylglycerolsby the mutant. However, the incorporation of labeled pyruvateand acetate is increased in developing wri1 mutant seeds. Third,the total activity of several glycolytic enzymes is decreasedin developing wri1 seeds. In principle, glycolytic pathways inthe plastid or the cytosol could contribute precursors to fattyacid biosynthesis in developing oilseeds. The reduction in theactivity of several glycolytic enzymes raises the question ofwhether one particular set of glycolytic enzymes in one of thetwo subcellular compartments is preferentially affected in thewri1 mutant.

Although no definitive answer can be provided at this time, we could demonstrate that the activity of pyrophosphate-dependentphosphofructokinase, an enzyme exclusively present in the cytosol(Plaxton, 1996), is strongly reduced in the wri1 mutant. Thiswould imply a reduction in carbon flow through cytosolic glycolysisif one assumes that pyruvate-dependent phosphofructokinase catalyzesa net glycolytic reaction in developing seeds of Arabidopsis,as has been postulated for developing potato tubers and tobaccosink leaves (Hajirezaei et al., 1994; Paul et al., 1995). Theobservation that pyruvate, the end product of glycolysis, canbe taken up and be incorporated at high rates into fatty acidsby isolated plastids of developing seeds of canola or castor (Smithet al., 1992; Kang and Rawsthorne, 1994) suggests that carbonflow from carbohydrates to triacylglycerols may involve extraplastidicglycolysis. Therefore, a deficiency in cytoplastic glycolysisin the wri1 mutant would be in agreement with reduced amountsof seed oil.

The Role of Seed Starch

Starch intermittently accumulates to higher amounts in developing wri1 mutant seeds compared with the wild type (Fig. 4C).Because the same low amounts of starch are present in mature mutantand wild-type seeds, one has to conclude that wri1 plastids arecapable of metabolizing starch. However, given the low amountof oil in mature wri1 embryos, the carbon flow through starchcan apparently only supply a fraction of the precursors requiredfor triacylglycerol biosynthesis in the wri1 mutant. Whether thisis due to a deficiency in glycolysis in the wri1 mutant or isan indication of a generally low rate of conversion of starchinto precursors of triacylglycerol biosynthesis in Arabidopsiscan currently not be distinguished. However, in canola the intermittentstarch amount is thought to be insufficient to support triacylglycerolbiosynthesis (King et al., 1997

Corroborating evidence has been provided by the expression of bacterial ADP-Glc pyrophosphorylase in developing seeds of canolathat led to an increased amount of starch and a decrease in oilcontent (Boddupalli et al., 1995), suggesting that the flow ofcarbon from photoassimilates to triacylglycerols does not go throughstarch, at least during the later stages of development. Apparently,the pathways for the biosynthesis of starch and triacylglycerolscompete and starch biosynthesis is normally repressed at the middlestage of development in canola seed. In the wri1 mutant seeds,the amount of starch is at least transiently increased, presumablybecause excess carbon is funneled into starch biosynthesis insteadof triacylglycerols.

The reduction in oil content in spite of the accumulation of starch in developing wri1 mutant seeds would be consistent witha reduction in glycolytic flux in the cytosol. Most likely, Sucimported into the embryo is converted to UDP-Glc and Fru by cytosolicSuc synthase, and UDP-Glc is further metabolized to Glc-1-P bythe action of cytosolic UDP-Glc pyrophosphorylase and is subsequentlyconverted to Glc-6-P by phosphoglucomutase. Instead of enteringglycolysis in the cytosol, Glc-6-P is imported into the plastidand preferentially incorporated into starch, as has been observedfor isolated plastids of canola (Kang and Rawsthorne, 1994), oris metabolized via the oxidative pentose phosphate pathway (Kangand Rawsthorne, 1996). Accordingly, the activity of UDP-Glc pyrophosphorylasewas not decreased, but slightly increased in wri1 mutant seeds(Table III). Furthermore, this pathway does not involve hexokinase,the enzyme most severely decreased in activity in the wri1 mutant.

The Primary Defect in the wri1 Mutant

The reduced activity of several glycolytic enzymes raises the question for the possible primary defect in the wri1mutant. Either a structural gene for one of the glycolytic enzymes,e.g. hexokinase, is mutated, leading to an altered glycolyticflux with secondary consequences for the activity of the otherglycolytic enzymes, or a developmental regulator of carbohydratemetabolism specific to seeds is affected.

Recently, it has been shown that hexokinase has dual functions in Arabidopsis (Jang et al., 1997): It catalyzes the phosphorylationof hexoses and also acts as a sugar sensor, repressing the expressionof different genes encoding photosynthetic proteins in the presenceof high sugar concentrations. Although sugar sensing and sugar-mediatedregulation of gene expression are intensely studied phenomenain plants (Koch, 1996; Smeekens and Rook, 1997), it is not knownwhether hexokinase of Arabidopsis as the possible sugar sensormay affect (stimulate) the expression of genes encoding glycolyticenzymes following the import of sugars into developing embryos.If this were the case, a defect in the structural gene for a seed-specifichexokinase in the wri1 mutant would explain the observed lossin hexokinase activity and the changes in overall glycolytic activityin developing wri1 seeds. However, if WRI1 indeed represents astructural gene for hexokinase, it must be different from ATHXK1and ATHXK2 described as sugar-sensor genes (Jang et al., 1997),because all three genes map to different chromosomes of Arabidopsisand, therefore, wri1 cannot be a mutant allele of one of the twoknown hexokinase genes.

The alternative suggestion, that WRI1 encodes not hexokinase but a gene product primarily involved in the developmental regulationof glycolytic activity in seeds during storage compound accumulation,would be consistent with the altered developmental activity profileof hexokinase and pyrophosphate-dependent phosphofructokinasein the wri1 mutant (Fig. 6). In this context it should be pointedout that the developmental activity profiles for hexokinase (Fig.6) and for the incorporation of Glc (Fig. 5) differ during thelater stages of development in the wild type. Although Glc incorporationdeclines sharply after d 10, hexokinase activity remains fairlyhigh. This observation suggests that, at least during later stagesof seed development, factors other than hexokinase may be limitingfor the conversion of carbohydrates into triacylglycerols. Becausethe morphogenesis of the embryo and the seedling of the wri1 mutantis not affected, it seems unlikely that WRI1 encodes a generalregulator of late embryo development such as LEC1 or FUS3 (Parcyet al., 1997). The clearly defined wri1 phenotype restricted tometabolism would suggest that it encodes a regulator specificallygoverning the carbon flow from carbohydrates to fatty acids duringseed filling.

Consequences for Fatty Acid Biosynthesis and Modification

Based only on the low oil content of the wri1 seeds and the change in fatty acid composition of the remaining oil (Table II),one could conclude that WRI1 is more directly involved in triacylglycerolbiosynthesis than has been suggested above. However, isolateddeveloping wri1 seeds are clearly capable of incorporating pyruvateand acetate at high rates into triacylglycerols, and the changein fatty acid composition of the remaining triacylglycerols maysimply be a consequence of reduced carbon flow into fatty acidbiosynthesis. Apparently, the relative amounts of the end productof fatty acid desaturation, 18:3, and of fatty acid elongation,22:1, are strongly increased, whereas the relative amount of theprecursor of both reaction sequences, 18:1, is most strongly decreased.This observation also implies that no feedback regulation occursin developing wri1 seeds to adjust the degree of unsaturationand elongation of the fatty acid substituents of triacylglycerolsto the decrease of carbon flow into this pathway, and that, presumably,different regulators control the activity of enzymes involvedin carbohydrate and lipid metabolism or the expression of therespective genes during seed development.

	CONCLUSIONS

In summary, a novel mutant of Arabidopsis has been isolated with a deficiency in seed carbohydrate metabolism that leads toa reduction in seed-oil accumulation. This mutant identifies agenetic locus designated wri1, which encodes either a regulatoryprotein governing carbohydrate metabolism during seed developmentor a novel hexokinase that may act as sugar sensor in developingseeds, controlling the activity or expression of other glycolyticenzymes. Given the high rate of photosynthate import during seedfilling, regulation of seed-specific carbohydrate metabolism bysugar sensing seems to be a reasonable mechanism with which tocontrol the flux of carbon into starch or oil in developing seeds.To gain further insight into the function of the WRI1 gene productand into the regulation of carbon flow in developing oilseeds,genes encoding seed-specific glycolytic enzymes have to be identifiedand their expression compared in the wild type and the wri1 mutant.Ultimately, the WRI1 locus has to be isolated and characterizedto understand the molecular basis for the complex phenotype ofthe wri1 mutant and to exploit the possibility of using the respectivegene for the modification of carbon partitioning in developingoilseeds by genetic engineering. The availability of the wri1mutant provides the basis for a positional cloning approach.

	FOOTNOTES

¹ This work was financially supported in part by the Deutsche Forschungsgemeinschaft (grant nos. Be 1591/2-1 and Be 1591/2-2)and by the Bundesminister für Bildung und Forschung (grant no.0311024).
^* Corresponding author; e-mail benning{at}pilot.msu.edu; fax 1-517-353-9334.

Received February 18, 1998; accepted May 27, 1998.

ACKNOWLEDGMENTS

We would like to thank Chris Somerville for his contributions during the early phase of this work, which was initiated inhis laboratory at the Michigan State University-Department ofEnergy Plant Research Laboratory.

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wrinkled1: A Novel, Low-Seed-Oil Mutant of Arabidopsis with a Deficiency in the Seed-Specific Regulation of Carbohydrate Metabolism1

Copyright Clearance Center: 0032-0889/98/118//11 © 1998 American Society of Plant Physiologists

wrinkled1: A Novel, Low-Seed-Oil Mutant of Arabidopsis with a Deficiency in the Seed-Specific Regulation of Carbohydrate Metabolism¹

Copyright Clearance Center: 0032-0889/98/118//11

© 1998 American Society of Plant Physiologists