AtOPT3, a Member of the Oligopeptide Transporter Family, Is Essential for Embryo Development in Arabidopsis

doi:10.1105/tpc.005629

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AtOPT3, a Member of the Oligopeptide Transporter Family, Is Essential for Embryo Development in Arabidopsis

Minviluz G. Stacey¹^,a, Serry Koh¹^,b, Jeffrey Becker^c and Gary Stacey²^,a

^a Department of Plant Microbiology and Pathology, University of Missouri, Columbia, Missouri 65211
^b Department of Plant Biology, Carnegie Institution of Washington, Stanford, California 94305-1297
^c Department of Microbiology and Department of Biochemistry, Cellular, and Molecular Biology, University of Tennessee, Knoxville, Tennessee 37996

² To whom correspondence should be addressed. E-mail staceyg{at}missouri.edu; fax 573-882-0588

Abstract

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

A T-DNA–tagged population of Arabidopsis was screenedfor mutations in AtOPT3, which encodes a member of the oligopeptide(OPT) family of peptide transporters, and a recessive mutantallele, opt3, was identified. Phenotypic analysis of opt3 showedthat most homozygous embryos were arrested at or before theoctant stage of embryo development and that none showed theusual periclinal division leading to the formation of the protoderm.This defective phenotype could be reversed by complementationwith the full-length, wild-type AtOPT3 gene. A ${beta}$ -glucuronidase(GUS) fusion to DNA sequences upstream of the putative AtOPT3ATG start codon was constructed, and the expression patternwas assayed in transgenic plants. AtOPT3 was expressed in thevascular tissues of seedlings and mature plants as well as inpollen. Consistent with the function of AtOPT3 in embryogenesis,AtOPT3::GUS expression also was detected in developing embryosand in the maternal tissues of seeds. These data suggest a criticalrole for peptide transport in early embryo development.

INTRODUCTION

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

Peptide transport is a widely observed phenomenon in both prokaryotesand eukaryotes. The process is characterized by the abilityof cells to transport peptides across membranes in a carrier-mediated,energy-dependent manner. Transported peptides are hydrolyzed,and the resulting amino acids are used for protein synthesisor as alternative sources of nitrogen and carbon (Perry et al.,1994; Steiner et al., 1995). Peptide transport systems usuallyare restricted to small peptides of two to six amino acids,exhibit high stereoselectivity, have no strict side chain specificity,and prefer ${alpha}$ -peptide bonds and the L-stereoisomers of amino acids(Becker and Naider, 1980; Payne and Smith, 1994). In additionto a nutritional role, peptide transport systems also are involvedin other cellular processes, such as bacterial quorum sensing(Swift et al., 1996), yeast mating (Kuchler et al., 1989; McGrathand Varshavsky, 1989), and mammalian immune response (Neefjeset al., 1993; Shepherd et al., 1993; Uedel et al., 1995). Peptidetransport systems also can take up physiologically active peptidederivatives. For example, peptide transport systems in animalsare pharmacologically important for the uptake of peptide-derivedantibiotics (e.g., cephalosporins [Okano et al., 1986a, 1986b])and anticancer agents (e.g., bestatin [Inui et al., 1990]).

The ABC (ATP binding cassette) superfamily of transporters usesATP hydrolysis for the transmembrane translocation of a largevariety of substances (including peptides), and members havebeen identified in organisms ranging from Escherichia coli tohuman (Blackmore et al., 2001; reviewed by Detmers et al., 2001).In contrast to the ABC family, the PTR (peptide transport) familyuses the transmembrane proton gradient to energize transport.Members of the PTR family transport dipeptides and tripeptidesas well as amino acids and nitrate (reviewed by Williams andMiller, 2001; Stacey et al., 2002). PTR proteins have been identifiedin yeast (Perry et al., 1994; Basrai et al., 1995), human (Lianget al., 1995), rabbit (Fei et al., 1994, 2000), mouse (Ganapathyet al., 1995), barley (West et al., 1998), and Arabidopsis (Frommeret al., 1994; Steiner et al., 1994; Song et al., 1997). TheArabidopsis AtPTR2 transporter, when expressed in yeast, transporteddipeptides and tripeptides but not larger peptides (Steineret al., 1995; Song et al., 1996). AtPTR2 antisense plants exhibiteda delay in flowering time and arrest in seed development (Songet al., 1997). Database comparisons with the Arabidopsis genomesequence identified 51 additional PTR family members, most ofwhich were predicted to transport peptides (Stacey et al., 2002).

The OPT (oligopeptide transport) family likely uses the protonmotive force to drive transmembrane transport. The OPT familywas first described in the pathogenic yeast Candida albicans(Lubkowitz et al., 1997) and subsequently in Schizosaccharomycespombe (Lubkowitz et al., 1998) and Saccharomyces cerevisiae(Hauser et al., 2000). OPT proteins are genetically and physiologicallydistinct from the ABC and PTR proteins and predominantly transporttetrapeptides and pentapeptides (Lubkowitz et al., 1997, 1998).OPT transporters are predicted to have 12 to 14 transmembranedomains, and sequence homology indicates several conserved motifs(Hauser et al., 2001; Koh et al., 2002). In addition to shortpeptides, the S. cerevisiae Opt1p was shown to transport glutathione(Bourbouloux et al., 2000) as well as enkephalins, which areendogenous opioid pentapeptides in the central nervous system(Hauser et al., 2000). Database searches for homology with theC. albicans CaOpt1p revealed nine putative Arabidopsis OPT orthologsthat form a distinct subfamily compared with the fungal OPTs(Koh et al., 2002; Stacey et al., 2002). Full-length cDNAs forseven Arabidopsis OPT transporters (AtOPT1 to AtOPT7) were clonedand tested for their ability to take up various peptides whenexpressed in yeast (Koh et al., 2002). Five (AtOPTs 1, 4, 5,6, and 7) of the seven AtOPTs were functional transporters inyeast, transporting at least one of the synthetic peptides KLLG,KLGL, and KLLLG. Peptide transport by AtOPT3 or AtOPT2 was notobserved, perhaps as a result of the limited number of substratesavailable for testing. Using gene-specific primers, the expressionof the cloned AtOPTs was detected by quantitative reverse transcriptase–mediatedPCR in Arabidopsis, and each was found to exhibit a distincttissue-specific expression pattern (Koh et al., 2002). The ArabidopsisOPT transporters were the first nonfungal orthologs to be identified.

Plants can assimilate nitrogen in a variety of forms, such asammonium, nitrate, amino acids, complex insoluble nitrogen-containingcompounds, and soluble peptides (reviewed by Williams and Miller,2001). In contrast to the information available on plant transportof ammonium, nitrate, and amino acids, very little is knownabout peptide transporters and their physiological substrates.The presence of multiple peptide transporters in the Arabidopsisgenome, as well as the known function of peptide transport systemsin bacteria, fungi, and animals, supports the idea that plantpeptide transporters play an important role in plant growthand development. Our previous reports on the cloning and characterizationof PTR and OPT transporters in Arabidopsis further support thisnotion. To address the functional role of peptide transportin plants, we used a reverse genetics approach to identify aloss-of-function mutation in one of the Arabidopsis oligopeptidetransporter homologs, AtOPT3. Phenotypic analysis of plantscarrying a T-DNA insertion in AtOPT3 showed that the opt3 alleleis recessive and that embryos homozygous for opt3 are arrestedvery early in embryogenesis. In addition, we also determinedthe tissue-specific expression pattern of an AtOPT3 promoter– ${beta}$ -glucuronidase(GUS) fusion in transgenic Arabidopsis. We found that AtOPT3is expressed preferentially in the vascular tissues of seedlingsand mature plants as well as in pollen and in developing embryos.

RESULTS

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

The opt3 Insertion Allele Is Lethal
Using a PCR-based approach, we identified an Arabidopsis lineharboring a T-DNA insertion in the predicted fourth exon ofthe AtOPT3 gene (Figure 1A) . The mutant line, designated N4,is heterozygous at the AtOPT3 locus (Figure 1B). DNA gel blotanalysis using the T-DNA–encoded NPTII (neomycin phosphotransferase)gene as a probe showed a single band (data not shown), consistentwith a single T-DNA copy inserted within AtOPT3. The N4 plantshowed wild-type phenotypes with regard to plant size and leafand flower development. However, a seed-defective phenotypewas observed. Before the greening stage, developing seeds appearedapproximately similar in color and size (data not shown). Afterthe greening stage (i.e., late heart to torpedo stages of embryodevelopment), abnormal seeds become readily distinguishableas white seeds compared with the wild-type, green seeds (Figure 1C).The mutant seeds then became brownish and eventually driedout. This seed-defective phenotype is consistent with that observedfor tagged embryo-lethal mutants (Meinke and Sussex, 1979; Errampalliet al., 1991).

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Figure 1. Isolation of a T-DNA Insertional Mutation in AtOPT3 and the Embryo-Lethal Phenotype Associated with the Mutation.

(A) T-DNA insertion site in the predicted fourth exon of AtOPT3. Black boxes represent exons, and black arrows indicate the relative locations and orientations of pertinent primers. The T-DNA insert and primers are not drawn to scale. LB, left border; RB, right border. Bar = 500 bp.

(B) The isolated N4 line is heterozygous for the opt3 allele. PCR amplification of the AtOPT3 wild-type allele with primers OPT3-A and OPT3-B (lane 2) and amplification of the mutant opt3 allele with primers JL202 and OPT3-B (lane 3) using genomic DNA isolated from the N4 (T2) plant. As a control, AtOPT3 was amplified (lane 1) from the wild type.

(C) Embryo-lethal phenotype associated with opt3. An immature silique from a wild-type plant showed only green seeds (silique 1), whereas heterozygous siliques from the N4 plant segregated green and white seeds, with the latter siliques turning purplish/brown in older siliques (siliques 2 to 4). Black arrows, wild-type seeds; white arrows, mutant seeds. Bar = 1.2 mm.

To determine the frequency and locations of mutant seeds, T3plants derived from N4 were allowed to self-pollinate, and siliquesfrom each plant were scored for the number and locations ofmutant and wild-type T4 seeds. The genotype of each T3 plantalso was determined to examine the cosegregation of the defectiveseed phenotype with the T-DNA insertion within AtOPT3. Genotypedetermination and segregation analyses for 10 selected T3 plantsare presented in Figure 2 . The five plants heterozygous foropt3 (plants 1 to 5) gave segregation ratios of wild-type tomutant seeds that were not significantly different from 3:1.By contrast, all nontagged plants (plants 6 to 10) producedwild-type seeds. In the heterozygous plants, 47 to 55% of mutantseeds were distributed in the upper half of each silique, indicatingthat the opt3 mutation has no apparent effect on the developmentof the male gametophyte (Meinke, 1982

). In addition, 25 moreT3 and T4 plants also were examined for cosegregation of thedefective seed phenotype with the opt3 allele. None of theseplants was homozygous for opt3, and plants heterozygous at theAtOPT3 locus produced wild-type and defective seeds (data notshown). Except for the defective seed phenotype, all viableT3 and T4 plants examined showed normal vegetative and reproductivedevelopment. Together, these results clearly indicate that theobserved embryo-lethal phenotype is linked to the T-DNA insertionwithin AtOPT3 and that opt3 is recessive and results in seedabortion of the homozygotes.

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Figure 2. Segregation Analysis of Embryo Lethality Associated with the opt3 Mutation.

(A) Segregation and distribution of defective seeds in 10 T3 plants.

(B) Genotype determination of the 10 T3 plants by PCR amplification of wild-type (WT) AtOPT3 and mutant opt3 alleles. Similar primers were used as in Figure 1B, except that a single PCR procedure containing OPT3-A, OPT3-B, and JL202 was performed for each of the T3 plants.

To confirm that the defective seed phenotype is the result ofthe insertion mutation within AtOPT3, genetic complementationwas performed by transforming plants heterozygous at the AtOPT3locus with a genomic DNA encoding the AtOPT3 gene and promoterregion (promoter::AtOPT3). As a control, transformation alsowas performed with a DNA encoding the GUS gene expressed fromthe native AtOPT3 promoter (promoter::GUS). Four independenttransgenic plants heterozygous for AtOPT3 and hemizygous forthe promoter::AtOPT3 transgene were selfed and scored for seedlethality. All four lines showed a reduction in the number ofdefective seeds, giving an average ratio of wild-type to mutantseeds that was not significantly different from 15:1 (Table 1).By contrast, control plants transformed with promoter::GUSshowed no genetic complementation (Table 1). Therefore, theseed-lethal phenotype genetically complemented by AtOPT3 confirmedthat the mutant phenotype is the result of the opt3 insertionallele.

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Table 1. Genetic Complementation of the opt3 Mutation

opt3 Embryo Development Arrests at the Preglobular Stage
To characterize the nature of the seed lethality associatedwith opt3, wild-type and mutant embryos from siliques of heterozygousT3 plants were analyzed at various stages of seed development.A comparison of wild-type and mutant embryos at the globular(Figures 3A and 3B) , heart (Figures 3C and 3D), and torpedo(Figures 3E to 3G) stages of embryo development showed thatmutant embryos remained small and arrested very early in embryogenesis.At the torpedo stage of normal development, mutant embryos becameslightly shriveled (Figures 3F and 3G), and most of them disintegratedby the curled cotyledon stage, although a few seeds retainedembryos that were clearly disintegrating (Figures 3H and 3I).Despite aberrant embryo development, endosperm development ofseeds harboring opt3 embryos appeared normal until the torpedostage of normal development (Figures 3A to 3F), after whichthe endosperm and integument layers also started to disintegrate(Figure 3H). In the mature silique, mutant seeds eventuallyturned brownish and dried out.

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Figure 3. Seed Development in Wild-Type and opt3 Homozygotes.

Siliques from heterozygous opt3 plants were examined at various stages of seed development, and the phenotypes of seeds harboring wild-type embryos ([A], [C], and [E]) were compared with those of the opt3 mutant ([B], [D], and [F] to [I]). For each developmental stage, wild-type and mutant seeds from the same silique were compared. Developmental stages are as follows: (A) and (B), globular; (C) and (D), heart; (E) and (F), torpedo; and (H), late curled cotyledon. (G) and (I) show higher magnifications of boxed mutant embryos in (F) and (H), respectively. In, integument layers; Em, opt3 embryo; En, endosperm; Ep, embryo proper; Su, suspensor. Bars in (A) to (F) and (H) = 80 µm; bars in (G) and (I) = 20 µm.

During normal embryo development, the initial division of thezygote is transverse, generating a small, spherical apical celland a large, elongated basal cell (Figure 4A) . The apicalcell undergoes two longitudinal divisions to produce a four-celledembryo (Figure 4B), followed by a transverse division to forman octant embryo proper (Figure 4C). A periclinal division ofeach of the 8 cells gives a 16-celled embryo. The resultingouter cell layer constitutes the protoderm, the first histologicallydetectable tissue, which gives rise to the epidermis (Figure 4D).The basal cell, on the other hand, undergoes a series oftransverse divisions to form the suspensor, which is composedof a single file of 6 to 11 cells, and the hypophysis, the uppermostderivative of the basal cell (Figures 4B to 4E). Asymmetricdivision of the hypophysis gives rise to the hypophyseal cell,the lens-shaped cell at the base of the embryo proper that isthe precursor of the root cap and the root quiescent center(Figure 4F) (Mansfield and Briarty, 1991

; West and Harada, 1993

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Figure 4. Terminal Phenotypes of opt3 Embryos.

Terminal phenotypes of opt3 embryos were determined in heterozygous siliques at the globular to early heart stages of normal embryo development. Early stages of embryogenesis in wild-type seeds are shown in (A) to (F), and representative terminal phenotypes of opt3 embryos are shown in (G) to (L). Developmental stages are as follows: (A), single cell; (B), (G), and (H), 2 or 4 cell; (C), (I), and (J), 8 cell; (D), 16 cell; (E) and (F), globular; and (K), 6 cell. (L) shows a mutant embryo in which cells from the octant stage divided longitudinally without previous periclinal division and the hypophysis was enlarged but did not divide to form the hypophyseal cell. Ac, apical cell; Ad, asynchronous division; Bc, basal cell; Ep, embryo proper; Hs, hypophyseal cell; Hy, hypophysis; Pd, periclinal division; Su, suspensor. Bars = 20 µm.

To determine the stage at which opt3 embryos are arrested duringembryogenesis, 86 mutant embryos contained in heterozygous siliquesat the globular to early heart stages of normal embryo developmentwere scored for their terminal phenotypes. These developmentalstages were selected because younger siliques (single to octantstages) contained mutant embryos that were difficult to distinguishfrom the wild type, whereas older siliques (torpedo to curledcotyledon stages) contained mutant embryos that already weredisintegrating or had fully disintegrated. Of the 86 mutantembryos scored, 12% were arrested at the single or two-celledstage (Figure 4G), 51% were arrested at the two- or four-celledstage (Figure 4H), and 23% were arrested at the octant stage(Figure 4I). A small percentage of mutant embryos (1%) showedan elongated embryo proper (Figure 4J). In addition, 8% of mutantembryos showed asynchronous cell division, in which only twoof the cells in the quadrant stage had undergone transversedivision, giving a six-celled embryo (Figure 4K). In wild-typeseeds, the 16-celled embryo underwent anticlinal and longitudinaldivisions of the outer and inner cells, respectively, resultingin a radially symmetrical globular embryo (Figures 4E and 4F).In the case of opt3 embryos, a small percentage of the seedsexamined (5%) showed embryos in which the cells that constitutethe octant embryo proper underwent further cell divisions withoutprevious periclinal division (Figure 4L), giving rise to embryoslacking the protoderm. Consistent with the early arrest in thedevelopment of the embryo proper, the hypophysis of opt3 embryosfailed to undergo asymmetric cell division and thus lacked adifferentiated hypophyseal cell (Figures 4G to 4L). The averagesuspensor length of 30 randomly selected opt3 embryos (arrestedat the single-celled to octant stages) was comparable to thatof wild-type embryos at the two-celled to octant stages of normaldevelopment (data not shown).

AtOPT3 Is Expressed in Vascular Tissues, Pollen, and Embryos
Five independent transgenic lines expressing an AtOPT3 promoter–GUSfusion were analyzed histochemically for GUS activity to assessthe temporal and spatial patterns of AtOPT3 expression duringplant growth and development. In light-grown seedlings, AtOPT3was highly expressed in the vascular tissues of cotyledons,hypocotyls, rosette leaves, roots, and stipules (Figure 5A) .Likewise, adult plants showed AtOPT3 expression in the vasculartissues of rosette leaves (Figure 5B), sepals (Figures 5C and 5D),and developing siliques and funiculi (Figures 5E and 5F).Weaker AtOPT3 expression also was detected in the vasculatureof stamens and petals (data not shown). Strong expression ofAtOPT3 was observed in pollen, but none was detected in unfertilizedovules (Figures 5C and 5G). The ubiquitous expression of AtOPT3in various organs of both seedling and adult plants is consistentwith a previous report on the expression pattern of AtOPT3 asdetermined by reverse transcriptase–mediated PCR (Kohet al., 2002).

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Figure 5. Representative AtOPT3 Promoter–GUS Expression Patterns in Seedlings and Tissues of Mature Plants.

5-Bromo-4-chloro-3-indolyl- ${beta}$ -D-glucuronide staining for AtOPT3 promoter–GUS expression in seedlings and mature plants is shown. Cot, cotyledon; Fun, funiculus; Hyp, hypocotyl; Ovu, ovule; Pol, pollen; Stp, stipules. Bar in (A) = 2 mm; bars in (B) to (E) = 0.5 mm; bars in (F) and (G) = 0.1 mm.

(A) A 10-day-old seedling showing strong GUS staining in the vascular tissues of cotyledons, rosette leaves, hypocotyls, roots, and stipules.

(B) A rosette leaf of a mature plant showing preferential GUS staining in vascular tissues.

(C) and (D) An unfertilized flower showing GUS staining in pollen (C) and in the vascular tissues of sepals (C) and (D).

(E) and (F) Vascular staining in siliques and funiculi.

(G) Anther and carpel of an unfertilized flower showing stained pollen and unstained ovules.

Immediately after fertilization (2 to 4 h after fertilization),AtOPT3 expression was detected in the embryo sac (Figure 6A) ;subsequently, AtOPT3 was expressed in developing maternal tissuesas well (Figure 6B). By the globular stage, prominent GUS stainingwas observed in the developing endosperm, integument layers,the embryo proper, and the suspensor of the developing embryo(Figure 6C). At the heart stage, prominent staining of the developingembryo, but not the suspensor, was observed (Figure 6D). Althoughprominent GUS staining was observed in the embryo from the heartstage onward, very weak or no detectable staining was observedin the endosperm and integument tissues at these later stages(Figures 6D to 6F). The transition from globular to heart stagerepresents a change from radial to bilateral symmetry and marksthe formation of the procambium, the precursor of vascular tissue,and the ground meristem (Mansfield and Briarty, 1991

; West andHarada, 1993

). Consistent with the expression of AtOPT3 in vasculartissues of seedlings and adult plants, strong GUS expressionwas observed in the developing vasculature of embryos as earlyas the heart stage (Figures 6G and 6H), with cotyledons showingstronger GUS staining in the developing veins at the curledcotyledon stage.

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Figure 6. AtOPT3 Promoter–GUS Expression in Developing Seeds.

5-Bromo-4-chloro-3-indolyl- ${beta}$ -D-glucuronide staining for AtOPT3 promoter–GUS expression in seeds is shown at different stages of embryo development. cot, developing cotyledon; En, endosperm; Ep, embryo proper; hyp, developing hypocotyl; In, integument layers; Pc, procambium; Sac, embryo sac; Su, suspensor. Bars = 60 µm.

(A) Two to 4 h after fertilization.

(B) Four to 8 h after fertilization.

(C) Globular stage.

(D) and (G) Heart stage.

(E) Torpedo stage.

(F) and (H) Curled cotyledon stage.

	DISCUSSION

TOP Abstract INTRODUCTION RESULTS DISCUSSION METHODS References

Characteristics of opt3 Embryos
During plant embryogenesis, the zygote undergoes a series ofhighly orchestrated developmental changes involving cell division,elongation, and differentiation (West and Harada, 1993

; Souterand Lindsey, 2000

; Jürgens, 2001

). None of the opt3 embryosexamined showed the characteristic periclinal division of cellsthat constitute the octant embryo proper, either because theywere blocked before this stage (86%) or because cells in theoctant stage divided further without previous periclinal division(5%). Moreover, the hypophysis did not undergo the asymmetriccell division necessary for the formation of the hypophysealcell. Thus, opt3 embryos are compromised in cell division veryearly in development and are not able to establish the earliestprecursor cells for embryonic organ systems: the protoderm cellsfor the epidermis and the hypophyseal cell for the embryonicroot cap and the root quiescent center. Arrested opt3 embryosthen undergo cellular degradation starting at the torpedo stageof normal development, coinciding with the time when the suspensorcells of wild-type embryos undergo programmed cell death (Marsdenand Meinke, 1985

; Mansfield and Briarty, 1991

). Although AtOPT3is clearly essential for embryo growth, it is not required fornormal endosperm development, as shown by the apparently normalendosperm in seeds harboring opt3 embryos.

A wide variety of Arabidopsis genes involved in embryo developmenthave been identified. These include genes in biotin biosynthesis(BIO1 [Schneider et al., 1989] and BIO2 [Patton et al., 1998]),cell division (KNOLLE [Lukowitz et al., 1996] and FACKEL [Janget al., 2000]), intron splicing (SUS2 [Meinke, 1995]), translation(TWN2 [Zhang and Sommerville, 1997] and EDD1 [Uwer et al., 1998]),and hormone signaling (AXR6 [Hobbie et al., 2000] and ABP1 [Chenet al., 2001]). A summary of information on genes known to beinvolved in seed development, including descriptions of defectiveembryo development in various mutants, can be found at www.seedgenes.org.In a majority of the known embryo-defective mutants, embryoswere arrested after the dermatogen stage, usually at the transitionfrom the globular to the heart stage (Errampalli et al., 1991;Castle et al., 1993; McElver et al., 2001). Examples of Arabidopsismutants arrested very early in embryogenesis (i.e., before thedermatogen stage) include twn2, a mutation in the valRS gene(Zhang and Sommerville, 1997), and titan (ttn) mutants (i.e.,ttn1, ttn2, ttn4, ttn5, ttn7, ttn8, and ttn9), which are disruptedin genes likely involved in modulating chromosome integrityor microtubule assembly during mitosis (Liu and Meinke, 1998;McElver et al., 2000; Liu et al., 2002; Tzafrir et al., 2002).In these mutants, developmental arrest is accompanied by grossabnormalities such as the formation of basal cell–derivedmultiple embryos, in the case of twn2 (Zhang and Sommerville,1997), and abnormal endosperm tissue with giant polyploid nuclei(Tzafrir et al., 2002), in the case of the ttn mutants.

By contrast, a notable phenotype of opt3 embryos, in additionto arrest very early in development, is aberrant cell division,which is observed in a small percentage of mutant seeds examined.These include embryos lacking the protoderm layer as a resultof the absence of the periclinal division that gives rise tothis tissue (5%), as well as embryos that undergo asynchronouscell division (8%). These abnormalities in cell division aresimilar to those found in certain pattern-formation mutants.For example, a mutation in the Arabidopsis KNOLLE (KN) gene,which encodes a protein related to syntaxins, resulted in embryosthat did not exhibit periclinal divisions (Lukowitz et al.,1996). Likewise, asynchronous cell division was observed inaxr6 embryos, which are defective in a gene involved in auxinresponse (Hobbie et al., 2000). Unlike opt3 embryos, kn andaxr6 embryos exhibited sustained cell division throughout embryogenesis,giving rise to mutant seedlings with no morphologically distinctepidermis layer (Mayer et al., 1991) and abnormal root, hypocotyl,and vascular tissues (Hobbie et al., 2000), respectively.

Function of AtOPT3 in Plant Growth and Development
In Arabidopsis, nine OPT orthologs were identified that exhibit61 to 85% sequence similarity (Koh et al., 2002). When testedfor the ability to transport peptides and peptide derivatives,AtOPTs were able to take up only selected tetrapeptides andpentapeptides but not dipeptides and tripeptides. Therefore,although the exact nature of the physiological substrate(s)for AtOPT3 remains unanswered, the data suggest that this substrate(s)is likely a small peptide, larger than a tripeptide, or a modifiedpeptide. The expression of AtOPT3 in the vascular tissues ofseedlings and mature plants suggests its possible role in thelong-distance translocation of nutritionally important peptidesnecessary for plant growth and development. Significant levelsof peptides were reported in phloem and xylem exudates, includingnon-protein-derived peptides such as alanylaminobutyric acidand glycylketoglutaric acid (Higgins and Payne, 1982). Thereare certain advantages in plant cells transporting peptidesas opposed to individual amino acids. Transported peptides canprovide a wide variety of amino acids to cells and may be amore efficient means of long-distance transport of protein degradationproducts during leaf senescence and seed germination (Higginsand Payne, 1982). Transport of peptides also can protect aminoacids from catabolism by enzymes known to be present in thephloem (Higgins and Payne, 1980).

AtOPT3 expression is induced in the embryo sac immediately afterfertilization. By the globular stage, AtOPT3 is expressed inall of the maternal and filial tissues of the developing seed.This expression pattern very early in embryogenesis is consistentwith the arrest of opt3 embryos at the preglobular stage. Nutrientand signal exchanges between the developing embryo, the endosperm,and the maternal tissues are an important part of seed development.The early developmental arrest of opt3 embryos, as well as thetemporal and spatial expression patterns of AtOPT3 in the filialand maternal tissues, suggests the crucial role of peptide transportduring the earliest stages of embryogenesis. The induction ofAtOPT3 expression after fertilization is coincident with theformation of extensive embryo sac wall ingrowths and the degenerationof the three antipodal cells (Mansfield and Briarty, 1991).These changes in the embryo sac are believed to be indicativeof an increased flux of biomolecules from the maternal tissuesinto the embryo sac. No specific function during reproductionhas been attributed to the antipodal cells, although they mayfunction in the transport of nutrients and growth substancesfor the embryo sac or they may serve as an additional nutrientsource upon their degeneration after fertilization (Mansfieldand Briarty, 1991; Mansfield et al., 1991). Therefore, peptidetransport by AtOPT3 appears to be among the earliest physiologicalevents occurring during embryogenesis, namely, the import ofpeptide(s) from the maternal tissues and/or the degeneratedantipodal cells immediately after fertilization.

Although not much is known about the role of peptides in Arabidopsisduring seed development, the importance of peptides in otherplants has been reported. For example, in kidney bean seeds,34% of nonprotein amino nitrogen is present as a ${gamma}$ -glutamyl peptide( ${gamma}$ -glutamyl-S-methyl-L-Cys), which is degraded upon seed germinationand thus likely functions as a storage form for nitrogen and/orsulfur (Goore and Thompson, 1967). In barley, a peptide transportsystem that can transfer dipeptides and tripeptides across thescutellum layer, a specialized absorptive tissue abutting theendosperm, was reported (Higgins and Payne, 1978; West et al.,1998; Waterworth et al., 2000). It was proposed that storageproteins present in barley endosperm are hydrolyzed and transferredas peptides to the growing embryo. Therefore, the embryo-lethalphenotype of opt3 embryos, as well as the expression of AtOPT3in the endosperm and the embryo, is consistent with the possibilitythat peptides or modified peptides serve as an important nitrogensource for the developing embryo. Specifically, peptides couldbe an important form of storage nitrogen in the endosperm andcotyledons as well as a form of imported nitrogen from the plantinto the developing seed. The expression of amino acid permeases(AAP1 and AAP2) was demonstrated in Arabidopsis seeds, and thesetransporters were suggested to provide the developing seedswith amino acids for storage protein synthesis (Hirner et al.,1998). However, the physiological function of various nitrogenouscompounds and their transporters in seed development remainspoorly characterized.

Although it is possible that AtOPT3 plays a solely nutritionalrole during embryogenesis, one can argue that the opt3 embryosmay be blocked in the transport of an important developmentalregulator. Indeed, there is a growing body of information onbiologically active peptides or peptide derivatives and theirimportance in plant growth and development (Bisseling, 1999;Matsubayashi et al., 2001; Lindsey et al., 2002). For example,plant growth factors such as auxin and gibberellin are boundfrequently to small peptides, and these peptide-hormone conjugatesare present in many tissues, including the vascular system andthe endosperm of plant seeds (Salisbury and Ross, 1992). Phytosulfokinesare disulfated pentapeptides or tetrapeptides that stimulateplant cell division in tissue culture (Matsubayashi and Sakagami,1996). Regardless of whether AtOPT3 plays a nutritional or asignaling role, the data presented here provide evidence forthe critical importance of the OPT family of transporters inseed development. Isolation of less severe opt3 alleles wouldbe useful in further defining the function of AtOPT3. The observedphenotype of the opt3 lesion clearly suggests a specific functionof AtOPT3 in embryogenesis. The observed differences in thetissue-specific and subcellular expression patterns of the variousAtOPTs, as well as differences in their substrate specificity,suggest that each of the AtOPT transporters plays a unique rolein plant metabolism (Koh et al., 2002). Further elucidationof the timing of expression and localization of AtOPTs and theidentification of their cognate substrates will add significantlyto our understanding of plant growth and development.

METHODS

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

Isolation of the opt3 Allele and Genetic Analysis
A total of 60,480 T-DNA–tagged Arabidopsis thaliana seedsgenerated at the University of Wisconsin Knockout Arabidopsisfacility (Madison, WI) were screened for opt3 insertion allelesby PCR (see www.biotech.wisc.edu/Arabidopsis for methods). Insertionswithin AtOPT3 were identified using a primer specific for theT-DNA left border (JL202, 5'-CATTTTATAATAACGCTGCGGACATCTAC-3')in tandem with OPT3-specific primers (OPT3-A, 5'-AAGACTAATGTCCATCTCTCCTCGGACCA-3';OPT3-B, 5'-TCGAGCGCTGCAGAGAGT-ACGTAATTGTA-3'). The locationsand orientations of the primers are shown in Figure 1A. AppropriatePCR bands were identified by DNA gel blot analysis using theAtOPT3 cDNA (Koh et al., 2002) as a probe. One line carryingan opt3 allele, designated N4, was identified and sequencedwith a T-DNA–specific primer (JL270, 5'-TTTCTCCATATTGACCATTCATACTCATTTG-3').T-DNA copy number was determined by DNA gel blot analysis usinga 546-bp NPTII cDNA fragment as a probe. For seed amplification,the N4 plant was allowed to self.

The genotype of the N4 line with regard to the opt3 allele,as well as subsequent T3 and T4 plants, was determined usinga PCR-based approach. Briefly, genomic DNA was isolated fromeach plant analyzed and used as a template for PCR amplificationof DNA fragments corresponding to the wild-type AtOPT3 alleleand the opt3 insertion allele. The wild-type allele was amplifiedwith the AtOPT3 gene-specific primers OPT3-A and OPT3-B to givea 2.4-kb PCR product. The opt3 mutant allele was amplified withOPT3-B and the T-DNA–specific primer JL202 to give a 1.2-kbPCR product. PCR products were detected by agarose gel electrophoresis.Partial sequencing using JL202 or OPT3-A confirmed that theobserved PCR products corresponded to wild-type AtOPT3 or mutantopt3 sequences.

Plant Growth Conditions and Transformation
Seedlings were germinated aseptically on agar medium containinghalf-strength Murashige and Skoog (1962) salts (Sigma, St. Louis,MO) and 1% Suc (w/v) supplemented as required with 50 µg/mLkanamycin or 20 µg/mL hygromycin. For seed amplificationand analysis of mature plants, 10-day-old seedlings were transferredto Pro-Mix soil (Premier Horticulture, Red Hill, PA) and grownat 22°C under constant fluorescent white light. Stable transformationof Arabidopsis was performed after the vacuum infiltration procedurefor Agrobacterium tumefaciens–mediated T-DNA gene transfer(Bechtold and Pelletier, 1998).

Phenotypic Analysis
The growth phenotypes of plants harboring the opt3 allele wereobserved carefully, making note of plant size, shape, and growthrate during vegetative and reproductive growth phases. Leafand flower phenotypes were observed for any gross defect usinga stereoscope (SZX12; Olympus, Tokyo, Japan). Defective seeddevelopment was noted by dissecting siliques of self-pollinatedplants and enumerating the number of wild-type and aborted seedspresent in each silique. At least eight siliques were scoredper plant.

To determine the terminal phenotypes of opt3 embryos, seedsfrom heterozygous siliques were cleared in Hoyer's solution(7.5 g of gum arabic, 100 g of chloral hydrate, and 5 mL ofglycerol in 30 mL of water) and observed for defects in embryogenesis,taking note of the terminal phenotypes of arrested embryos.Abnormalities in endosperm and integument development also wereobserved. Observation and documentation of morphology were performedusing an Eclipse E600 microscope (Nikon Tokyo, Japan) equippedwith Nomarski optics or a Leica SP2 laser scanning confocalmicroscope (Wetzlar, Germany) attached to a photo multiplier.

Construction of the AtOPT3 Promoter– ${beta}$ -Glucuronidase Fusion and Analysis of Transgenic Plants
A 3.5-kb fragment containing sequences upstream of the predictedATG start codon of AtOPT3 was amplified by PCR using OPT3pFor(5'-ACTGGATCCGGTCCAGTAGGCCATTTCACAT-3') and OPT3pRev (5'-AGCGAATTCCTGGCAGAAAGTGAATGCTGTT-3')primers. The amplified AtOPT3 promoter was cloned as an EcoRI-BamHIfragment into the binary vector pCAMBIA 1391Z (Hajdukiewiczet al., 1994) upstream of a promoterless ${beta}$ -glucuronidase (GUS)gene. Transformed Arabidopsis plants carrying the promoter–GUSfusion were selected based on hygromycin resistance encodedin the T-DNA and were stained for GUS using 5-bromo-4-chloro-3-indolyl- ${beta}$ -D-glucuronideas a substrate according to published protocols (Jefferson etal., 1987). Stained seedlings and tissues were fixed in 50%ethanol, 5% acetic acid, and 3.7% formaldehyde and destainedin 70% ethanol overnight. Additional overnight clearing withlactophenol (water:glycerol:lactate:phenol, 1:1:1:2 [v/v]) wasperformed for seeds after the ethanol treatment to visualizethe embryos. Staining patterns were observed and documentedusing a stereomicroscope (Olympus SZX12) or an Eclipse E600microscope (Nikon) equipped with Nomarski optics.

Genetic Complementation
A 6.2-kb fragment encompassing the AtOPT3 genomic DNA and upstreamsequences was cloned into the BamHI and BstEII sites of pCAMBIA1391Z (Hajdukiewicz et al., 1994). Transformed Arabidopsis plantscarrying the opt3 allele were selected for hygromycin and kanamycinresistance. Selected plants were allowed to self and analyzedfor the segregation of the embryo-lethal phenotype. PCR wasused to distinguish transformed plants heterozygous at the opt3locus. As a control, plants heterozygous at the opt3 locus thatwere transformed with the AtOPT3 promoter–GUS fusion describedabove also were analyzed for genetic complementation.

Upon request, all novel materials described in this articlewill be made available in a timely manner for noncommercialresearch purposes. No restrictions or conditions will be placedon the use of any materials described in this article that wouldlimit their use for noncommercial research purposes.

Acknowledgments

The authors gratefully acknowledge the helpful suggestions andcomments of Albrecht von Arnim during the course of this studyand the helpful review of the manuscript by Walter Gassmann.This research was supported by National Research InitiativeGrant 99-35304-8194 from the U.S. Department of Agriculture.

Footnotes

Article, publication date, and citation information can be foundat www.plantcell.org/cgi/doi/10.1105/tpc.005629.

^¹ These authors contributed equally to this article.

Received June 23, 2002; accepted September 2, 2002.

References

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

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