Divergent Roles in Arabidopsis thaliana Development and Defense of Two Homologous Genes, ABERRANT GROWTH AND DEATH2 and AGD2-LIKE DEFENSE RESPONSE PROTEIN1, Encoding Novel Aminotransferases

doi:10.1105/tpc.019372

Divergent Roles in Arabidopsis thaliana Development and Defense of Two Homologous Genes, ABERRANT GROWTH AND DEATH2 and AGD2-LIKE DEFENSE RESPONSE PROTEIN1, Encoding Novel Aminotransferases

Jong Tae Song, Hua Lu and Jean T. Greenberg¹

Department of Molecular Genetics and Cell Biology, University of Chicago, Chicago, Illinois 60637

¹ To whom correspondence should be addressed. E-mail jgreenbe{at}midway.uchicago.edu; fax 773-702-9270.

ABSTRACT

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ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

The disease-resistant Arabidopsis thaliana aberrant growth anddeath2 (agd2-1) mutant has elevated levels of the defense signalsalicylic acid (SA), altered leaf morphology, and mild dwarfism.AGD2 and its close homolog ALD1 (for AGD2-LIKE DEFENSE RESPONSEPROTEIN1) encode aminotransferases that act on an overlappingset of amino acids in vitro. However, kinetic parameters indicatethat AGD2 and ALD1 may drive the aminotransferase reaction inopposite directions. ALD1-deficient mutants have the oppositephenotypes from agd2-1, showing reduced SA production and increaseddisease susceptibility. Furthermore, ALD1 transcript levelsare elevated in agd2-1 and are induced in the wild type by bacterialpathogen infection. ALD1 is responsible for some of the elevatedSA content and a majority of the disease resistance and dwarfismof agd2-1. A complete knockout of AGD2 renders embryos inviable.We suggest that AGD2 synthesizes an important amino acid–derivedmolecule that promotes development and suppresses defenses,whereas ALD1 generates a related amino acid–derived moleculeimportant for activating defense signaling.

INTRODUCTION

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ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

Extracellular bacterial pathogens such as Pseudomonas syringaeinfect a wide variety of plants (Gardan et al., 1999), causingwater soaking, cell death, and chlorophyll loss (chlorosis)(Agrios, 1997). Diseases caused by P. syringae require bacterialeffector proteins that are delivered via a type III secretionapparatus to plants and promote disease by a largely unknownmechanism (Greenberg and Vinatzer, 2003). In some plant genotypes,effectors encoded by avirulence genes can be specifically recognized,and a resistance response is mounted to limit the infectionin a so-called gene-for-gene interaction (Greenberg and Vinatzer,2003). However, it is now widely recognized that even withoutthe gene-for-gene interaction, plants mount an active defenseresponse that partially limits virulent P. syringae (Glazebrookand Ausubel, 1994; Glazebrook et al., 1996; Rogers and Ausubel,1997). This general resistance can vary in effectiveness dependingon the host-pathogen combination. It is not clear what triggersgeneral resistance, but it may be the perception of damage bythe plant, the recognition of pathogen-associated molecularpatterns, such as flagella (Asai et al., 2002), and/or the weakrecognition of effectors (Chang et al., 2002).

Many lines of evidence point to the small phenolic compoundsalicylic acid (SA) in playing a prominent role as a signalmolecule in general resistance. First, SA levels rise duringP. syringae infection (Rassmussen et al., 1991). Second, exogenousapplication of SA can induce resistance to P. syringae (Ryalset al., 1996). Third, numerous mutants compromised for SA accumulationor constitutively producing SA show enhanced susceptibilityor resistance, respectively, to P. syringae. In particular,Arabidopsis thaliana mutants, such as eds16/sid2 (for enhanceddisease susceptibility16/salicylic acid induction-deficient2)and eds5/sid1, that have very low levels of SA during pathogeninfection, probably because of a defect in SA biosynthesis,are disease susceptible (Nawrath and Métraux, 1999; Wildermuthet al., 2001; Nawrath et al., 2002). Plants engineered to producemore SA also are more resistant to viral and fungal infections,but resistance to bacterial pathogens has not been specificallytested (Verberne et al., 2000).

Not surprisingly, several mutants with heightened susceptibilityto P. syringae show altered but not abolished accumulation ofSA upon infection. These include pad4 (for phytoalexin deficient4;Zhou et al., 1998), eds1 (Feys et al., 2001), eds3 (Glazebrooket al., 1996, 2003), eds8 (Glazebrook et al., 1996, 2003), pad1(Glazebrook et al., 1997), pad2 (Glazebrook et al., 1997, 2003),eds4 (Gupta et al., 2000), and acd6-T (for accelerated celldeath6-T; Lu et al., 2003). These mutants affect SA accumulationto varying extents, with some only compromising the early productionof SA. ndr1 (for nonrace-specific disease resistance1) mutantsalso are compromised for SA production after infection withsome avirulent P. syringae isolates (Shapiro and Zhang, 2001).PAD4 encodes a possible lipase and may generate a lipid signal(Jirage et al., 1999). ACD6 is a probable transmembrane proteinwith an ankyrin repeat region that may act by making protein–proteincontacts (Lu et al., 2003). Finally, NDR1 is thought to mediateSA induction through the production of reactive oxygen (Shapiroand Zhang, 2001). However, the basis for the reduction in SAaccumulation in most mutants is not well understood. In somecases, genes that regulate SA production may regulate othersignals as well, as has been hypothesized for PAD4 (Glazebrooket al., 2003).

Constitutive disease-resistant mutants also have provided away to identify potential regulators of SA and other defensesignals. One such mutant we previously characterized, calledagd2-1 (for aberrant growth and death2), showed elevated SAand resistance to P. syringae (Rate and Greenberg, 2001). Thismutant also had some spontaneous cell death and enlarged cells,and the overall size of the plants was smaller than that ofthe wild type. The morphology of agd2-1 was greatly alteredby depleting SA with the nahG transgene, whose product convertsSA to catechol (Gaffney et al., 1993). agd2-1-nahG plants hadtumor-like growths and cells with highly endoreduplicated DNA,a phenotype that could be suppressed by application of an SAagonist (Rate and Greenberg, 2001; Vanacker et al., 2001). Thisled us to suggest that some genes that control defenses alsoplay a role in development (Vanacker et al., 2001). Indeed,we found that the nonexpressor of PR1-1 mutant blocked for SAsignaling also had a developmental defect, showing a decreasein cell number and an increase in the ploidy of mesophyll cellswhen compared with the wild type (Vanacker et al., 2001). Otherexamples of mutants with developmental and defense defects alsohave been reported recently (i.e., see Holt et al., 2002; Jinet al., 2002; Barth and Conklin, 2003).

In addition to defense components sometimes affecting cell growthand/or death, they also interact with other pathways. For example,many abiotic stresses, such as ozone, activate SA synthesisand SA-dependent defenses (Sharma et al., 1996). Amino acidstarvation or treatment with the abiotic elicitor ${alpha}$ -aminobutyricacid can induce SA-dependent and SA-independent defense markersand the phytoalexin camalexin, possibly through a common pathway(Zhao et al., 1998). However, no clear mechanism for how thesestimuli are sensed and transduced has yet emerged. Amino acidimbalances also can alter development. Transgenic plants thataccumulate 10-fold more Lys than the wild type have strikingdevelopmental defects (Frankard et al., 1992). These transgenicNicotiana sylvestris plants have decreased chlorophyll content,lack apical dominance, and show altered leaf size and morphology.Whether these Lys-overexpressing plants also alter the defenseresponse has not been investigated. In plants, amino acids areprecursors to hormones or secondary metabolites and serve totransport nitrogen from source to sink organs. As such, thecontrol of amino acid synthesis in plants affects many aspectsof growth and development.

In this report, we describe the cloning and characterizationof AGD2, which encodes a novel aminotransferase. A. thalianahas one homolog of AGD2, called ALD1 (for AGD2-LIKE DEFENSERESPONSE PROTEIN1), sharing 62% identity (77% similarity) withAGD2. The recombinant AGD2 and ALD1 proteins have overlappingsubstrate specificity on several amino acids but act in differentdirections in the aminotransferase reaction in vitro. AGD2 expressionis suppressed by dark treatment and during senescence, whereasALD1 is induced by bacterial pathogen infection and senescence.ald1 loss-of-function mutants had the opposite phenotypes fromagd2-1, showing increased P. syringae susceptibility and reducedSA accumulation. Additionally, most of the agd2-1 phenotypeswere at least partially attributed to ALD1 function. Finally,we show that complete loss of AGD2 function results in inviableembryos, suggesting a developmental role for AGD2.

RESULTS

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ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

Cloning of AGD2 and Identification of the Homologous ALD1 Gene
We fine-mapped AGD2 to a 65-kb interval encompassed on BAC cloneT16L1 between the C5-2 and C7-2N markers. AGD2 was encoded bythe At4g33680 gene according to a number of criteria. First,complementation test results using 15- to 20-kb overlappingT16L1 subclones uniquely identified the 7-kb At4g33680 regionto be capable of rescuing agd2-1. Second, defined genomic andcDNA clones corresponding only to At4g33680 complemented agd2-1(Figure 1A; data not shown). Third, the same single nucleotidechange was detected in both cDNA and genomic DNA from the At4g33680gene in agd2-1. The agd2-1 allele contained a C-to-A point mutationresulting in a Pro-to-Ser change at amino acid 398 (Figure 1B).

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Figure 1. Features of AGD2, ALD1, and agd2-T.

(A) Complementation of agd2-1. agd2-1 plants were transformed with the genomic clone of AGD2 (AGD2G, at right). The plants shown at the left and in the middle are untransformed wild-type and agd2-1 control plants. agd2-1 plants transformed with the genes adjacent to AGD2 were not complemented (data not shown).

(B) Molecular structures of AGD2, ALD1, OsAGD2, and OsALD1. T-DNA insertion sites are indicated by triangles. The asterisk indicates the Pro-to-Ser change caused by the agd2-1 allele. Closed and open boxes represent exons, and closed boxes represent possible chloroplast transit peptides. The closed circles indicate the pyridoxal-5'-phosphate attachment sites.

(C) Immature seeds inside a heterozygous agd2-T/AGD2 silique. Aborted dead seeds are indicated by red arrows.

(D) Microscopy analysis of aborted and normal seeds in agd2-T/AGD2 heterozygotes. Embryos are indicated by red arrows. Top panel (I to III), dying and dead seeds; bottom panel (IV to VI), normal seeds. IV, Globular stage; V, triangular stage; VI, heart stage. Bars = 80 µm.

AGD2 had 9 introns (Figure 1B) and encoded a 461–aminoacid protein. Using the simple modular architecture researchtool (http://smart.embl-heidelberg.de/), we found that residues148 to 460 had modest similarity (E = 1.5e-8) to the aminotransferaseclass I and class II protein families (Pfam 9.0) and containeda pyridoxal-5'-phosphate attachment site (Mehta et al., 1989

).The PSORT and TargetP algorithms (http://psort.ims.u-tokyo.ac.jp/and http://www.cbs.dtu.dk/services/TargetP/, respectively) bothpredicted AGD2 to be chloroplast localized (Figure 1B).

A. thaliana has one close homolog of AGD2 on chromosome 2 (At2g13810),which we named ALD1. ALD1 had 62% identity and 77% similaritywith AGD2 at the amino acid level. ALD1 had 10 exons (Figure 1B)and encoded a 456–amino acid protein. It was predictedto localize to the cytoplasm by the PSORT algorithm and to thechloroplasts by the TargetP algorithm. Because of this ambiguity,we have tentatively indicated that ALD1 lacks a chloroplasttransit signal (Figure 1B).

The Oryza sativa (rice) genome had two genes: one called OsJNBa00664E16.9and one that we annotated from genomic region AC105731 (tentativelynamed OsALD1), whose products had high similarities to bothAGD2 and ALD1 (Table 1). We isolated full-length O. sativa cDNAsfor OsJNBa00664E16.9 (cOsAGD2, GenBank accession number AY338235)and OsADL1 (cOsALD1, GenBank accession number AY338236) andfound that they had gene structures similar to AGD2 and ALD1,respectively (Figure 1B). Additionally, the product of cOsAGD2was predicted to have a subcellular location similar to AGD2,whereas the product of cOsALD1 was predicted to be cytoplasmic.Because of the high similarities of the predicted O. sativaproteins to both AGD2 and ALD1 (Table 1), localization assignmentsfor these proteins may change when more data is available.

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Table 1. Percentage Identities and Similarities (in Parentheses) among AGD2, ALD1, OsAGD2, and OsALD1 Proteins

Loss of AGD2 Causes Embryo Lethality
Analysis of the AGD2^P398S mutant recombinant enzyme activitycorresponding to the product encoded by agd2-1 (see below; Figure 6)suggested that the agd2-1 allele was not null. To ascertainthe phenotype of AGD2 null mutant plants, we isolated a heterozygousmutant (agd2-T/AGD2) with a kanamycin-resistant (kan^R) T-DNAinsertion in the first exon of AGD2 (Figure 1B). The progenyof heterozygous agd2-T/AGD2 plants yielded 20 wild-type, 44heterozygous, and no homozygous mutant plants, suggesting thatAGD2 is an essential gene. Furthermore, of 352 seeds from theheterozygous plant that were germinated on kanamycin plates,116 kanamycin-sensitive (kan^S) and 236 kan^R seeds were observed.This is a good fit to the 1:2:0 hypothesis that the homozygousembryos were not viable ( ${chi}$ ² = 0.012, P > 0.9). In accordancewith the lack of homozygous seeds, the seed yield per siliquein the wild type (54.5 ± 0.9 SD, n = 4) and heterozygousagd2-T (40.3 ± 2.2 SD, n = 4) was significantly different(P = 0.0009). The seeds in wild-type plants all looked normaland were of uniform size. By contrast, some seeds of the heterozygousplants were very tiny and dry and looked aborted (Figure 1C).This phenotype was detected in all of the >100 heterozygousplants assayed.

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Figure 6. Purification and Relative Activities of AGD2, AGD2^P398S, and ALD1.

(A) Electrophoretic patterns of purified recombinant proteins through column elution using Ni²⁺-NTA.

(B) Relative aminotransferase activities of AGD2, AGD2^P398S, and ALD1. Substrates were at a 50-mM concentration. Aminotransferase activity was determined by measuring concentration of the reaction product Glu (using 2-oxoglutarate as the cosubstrate) or Ala (using pyruvate as the cosubstrate). The activity of AGD2 with Lys and 2-oxoglutarate was arbitrarily set at 100%. Asterisks indicate no detectable activities. No detectable activity was seen with all of the other standard amino acids tested. Bars indicate standard deviations (n = 3).

To determine when in development AGD2 might act, we examinedat which stage the homozygous embryos died. Before the globularstage, all of the developing embryos in agd2-T/AGD2 heterozygoteswere normal. However, when most of the embryos reached the globularstage in agd2-T/AGD2 heterozygotes, some seeds already had diedor were severely malformed (Figure 1D). The aborted seed sizewas much smaller than that of normal seeds, and the embryo propercould no longer be seen. It seems likely that after fertilization,homozygous embryos had normal development at the beginning andthat later the embryos died. To investigate the ratio of lethal-to-healthyembryos at the heart stage, we examined the contents of individualsilique chambers. The heterozygous plant had 20.8 ± 0.66SD (n = 5) normal and 7.0 ± 0.32 SD (n = 5) dead seedsper silique chamber, whereas the control wild-type plants had27.8 ± 0.37 SD (n = 5) apparently living seeds. Theseratios of live-to-dead seeds were significantly different inthe heterozygous mutant and the wild type (P < 0.0001). Furthermore,the embryo lethality of the agd2-T mutant was complemented bythe AGD2 genomic clone. This was evidenced by the fact thatnumerous viable T2 plants (12) homozygous for agd2-T only wererecovered when the AGD2 transgene was present. In reciprocalcrosses, we found no indication that agd2-T haploid pollen orovules had any transmission defects (data not shown). Therefore,agd2-T affected the embryo and resulting diploid seeds but nothaploid pollen or ovules. These results also were consistentwith the 1:2 segregation of kan^S:kan^R of seeds from agd2-T/AGD2heterozygotes.

AGD2 Localizes to Chloroplasts
To investigate where in the cell AGD2 might function, we examinedthe subcellular location of the full-length protein fused tothe green fluorescent protein (GFP). We drove expression ofthe AGD2 cDNA fused to gfp from the 35S promoter of Cauliflowermosaic virus (CaMV). This construct complemented the agd2-1mutant (data not shown). The GFP fluorescence patterns in protoplastsisolated from A. thaliana expressing AGD2-GFP colocalized withthe red autofluorescence patterns of the chloroplasts (Figures 2A and 2B).When GFP lacking the AGD2 moiety was expressed,the GFP fluorescence was not specifically colocalized with chloroplastautofluorescence but was distributed throughout the cells (Figures 2C and 2D).The chloroplast localization of AGD2-GFP is consistentwith its possible role in amino acid synthesis because manyamino acids are known to be synthesized in chloroplasts (Bryan,1990).

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Figure 2. Subcellular Localization of AGD2.

The pGFP and pAGD2-GFP under control of the CaMV 35S promoter were transformed into A. thaliana. GFP fluorescence of the protoplasts was observed using a fluorescence microscope.

(A) and (B) pAGD2-GFP.

(C) and (D) pGFP.

AGD2 and ALD1 Have Divergent Expression Patterns
agd2-1 hypomorphic plants are resistant to P. syringae (Rateand Greenberg, 2001

) and showed elevated ALD1 expression (Figure 3A).This suggested that AGD2 and/or ALD1 mRNA levels mightbe modulated during pathogenesis. To test this, we used gene-specificprobes to examine their transcript levels after infection ofwild-type plants with P. syringae. In response to P. syringaepv maculicola strain DG3 infection, AGD2 mRNA levels were notsignificantly changed, whereas ALD1 was induced in a patternsimilar to that of the known defense-related gene PathogenesisRelated1 (PR1; Figure 3B). Mock inoculation did not alter ALD1or AGD2 expression (data not shown). Because some pathogen-inducedgenes also are senescence regulated (Morris et al., 2000

), wefollowed the expression levels of AGD2 and ALD1 in leaf 4 throughoutits life span. Visible senescence started on day 21. AGD2 expressionwas initially high and decreased with time, whereas ALD1 wasinduced after day 24 (Figure 3C). Thus, the expression of bothgenes was modulated during senescence.

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Figure 3. RNA Expression of AGD2 and ALD1.

Tissue from the wild type and/or aldT-1 was used for RNA extraction and RNA gel blot analysis.

(A) ALD1 and PR1 expression in the fourth and fifth leaves of 20-d-old wild-type (Col) and agd2-1 plants.

(B) ALD1 and PR1 expression in wild-type (Ws) and ald1-T1 plants. Leaves (fourth and fifth) from 18-d-old plants were infected with P. s. maculicola DG3 (OD₆₀₀ = 0.01).

(C) Expression of AGD2 and ALD1 during development of the fourth leaf. Leaf length and age of the plant when RNA was extracted are indicated.

(D) Expression of AGD2 and ALD1 in the indicated tissues.

(E) A time course of steady state AGD2 mRNA accumulation. Twenty-day-old plants were kept in a 16-h-light/8-h-dark (16L/8D) cycle or were shifted to continuous dark (D) for the indicated time after 4 h in the light of the normal light cycle (16-h-light/8-h-dark) and then switched back to light (L) for 1 or 4 h. Although the signal was low for the ALD1 transcript, the probe was verified to be high specific activity. It gave a strong signal on the blots probed in parallel (see [A] and [B]).

We also examined the expression levels of AGD2 and ALD1 in varioustissues (Figure 3D). AGD2 was strongly expressed in all of thetissues, including seedling, root, stem, flower, and leaves.However, AGD2 expression was relatively lower in siliques, whereasALD1 was very high in siliques but relatively low in other tissues.The expression of ALD1 is reminiscent of that seen for PR genesthat show expression in flowers, fruit, and ripening fruit (Lotanet al., 1989

; Salzman et al., 1998

). Such expression may conferresistance to pathogens during reproduction.

Amino acid–synthesizing enzymes as well as amino acids(the possible substrates and products of aminotransferases)can vary in abundance depending on whether light is present(Buchanan et al., 2000). Additionally, the expression of somedefense genes, such as ACD6, is light dependent (Lu et al.,2003). To test the effect of light on AGD2 and ALD1 expression,plants maintained in a 16-h-light/8-h-dark cycle were movedto constant dark after 4 h of the normal morning light. Theseare conditions under which ACD6 transcript levels are modulated(Lu et al., 2003). In 16-h-light/8-h-dark conditions, AGD2 expressionwas unchanged throughout the course of a day (Figure 3E). However,after dark treatment, AGD2 transcript levels were significantlyreduced at 24 and 48 h. When the dark-treated plants were re-exposedto light for 4 h, the AGD2 transcript level was restored backto the level seen in the control plants maintained in the normallight/dark cycle conditions (Figure 3E). ALD1 levels were notsignificantly altered under these conditions. Thus, the expressionpatterns of AGD2 and ALD1 are spatially, developmentally, andenvironmentally regulated, with different and sometimes complementarypatterns.

ALD1 Is Important for Resistance to the Bacterial Pathogen P. syringae
The pathogen-induced expression of ALD1 suggested it could beimportant for disease resistance. To test this, we isolateda mutant, ald1-T1, with a T-DNA insertion in the fourth intronof ALD1 (Figure 1B) in ecotype Wassilewskija (Ws). ald1-T1 plantsshowed two aberrantly large ALD1 transcripts, visualized with5' and 3' end ALD1 probes, because of the presence of the T-DNAinsertion (Figure 3B). Reverse transcriptase (RT)-PCR and sequenceanalysis established that ald1-T1 produced one transcript fromthe native promoter with the first four ALD1 exons and T-DNAborder sequence. The second transcript included a T-DNA sequenceat the 5' end and the six 3' exons of ALD1 at the 3' end (datanot shown). No full-length transcripts were found, suggestingthat little if any functional ALD1 protein was present in theald-T1 mutant.

The ald1-T1 homozygous plants and seeds were morphologicallynormal (data not shown). Infection of wild-type and ald1-T1plants with P. s. maculicola DG3 resulted in chlorotic symptomsin the leaves of ald1-T1 but still green or slight symptom developmentin wild-type leaves (data not shown). P. s. maculicola DG3 bacteriagrew at least 10-fold more in ald1-T1 than in wild-type plantson days 2 and 3 after infection (Figure 4A). As P. s. maculicolaDG3 was not very virulent in Ws, we also assayed the growthof P. syringae pv tomato strain DC3000, a virulent isolate.ald1-T1 also was more susceptible than the wild type to P. s.tomato DC3000 (Figure 4A). Ecotype Columbia (Col) plants withRNA interference–mediated downregulation of ALD1 or containinga T-DNA insertion in exon one of ALD1 (ald1-T2; Figure 1B) behavedsimilarly to ald1-T1 (Figure 5; data not shown). ald1-T1 wasrecessive and was complemented by a genomic clone of ALD1 (Figure 4B).

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Figure 4. Increased Disease Susceptibility in the ald1-T1 Mutant.

(A) Disease susceptibility of ald1-T1 plants. Wild-type Ws (open circles) and ald1-T1 (open triangles) plants were infected with P. s. maculicola DG3 (PmaDG3, at left) or with P. s. tomato DC3000 (PtoDC3000, at right) at OD₆₀₀ = 0.0001. Growth of P. syringae in Ws and ald1-T1 was significantly different on days 2 and 3 (P < 0.01, t test, n = 8). Ws and ald1-T1 plants were pretreated with 100 µM BTH or water for 2 d and then subjected to infection with P. s. maculicola DG3. BTH-treated Ws (closed circles) and ald1-T1 (closed triangles) were not significantly different for bacterial growth (P > 0.5, t test, n = 8). cfu, colony-forming units. Bars indicate standard error. In some cases, the symbols obscure the error bars.

(B) Complementation of the ald1-T1 mutant phenotype. Ws (open circles), ald1-T1 (open triangles), and ald1-T1 transformed with the ALD1 genomic clone (closed circles) were infected with P. s. maculicola DG3 (PmaDG3, at left) or P. s. tomato DC3000 (PtoDC3000, at right) at OD₆₀₀ = 0.0001. Growth of P. syringae in Ws and ald1-T1 was significantly different on days 2 and 3 (P < 0.01, t test, n = 8), whereas growth in Ws and the transgenic plants was not different (P > 0.7, t test, n = 8).

(C) SA levels in Ws and ald1-T1 plants during pathogen infection. Leaves (fourth and fifth) from 18-d-old plants were infected with P. s. maculicola DG3 (OD₆₀₀ = 0.01) and were harvested, extracted, and analyzed by HPLC. The free and total SA values ±SD are averages of three sets of samples. The number of asterisks indicates samples that are significantly different from one another at a given confidence level (one asterisk, P < 0.004; two asterisks, P < 0.0008; three asterisks, P < 0.0002).

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Figure 5. Bacterial Growth in agd2-1 ald1-T2 Plants.

Wild-type Col (open circles), ald1-T2 (open triangles), agd2-1 (open squares), and agd2-1 ald1-T2 (closed circles) were infected with P. s. maculicola DG3 at OD₆₀₀ = 0.0001. Growth of P. syringae in Col and agd2-1 ald1-T2 was not significantly different on days 2 and 3 (P > 0.7, t test, n = 8). Bars indicate standard error. In some cases, the symbols obscure the error bars.

ald1-T1 Has Reduced SA Accumulation
Increased susceptibility of plants to P. syringae could resultfrom a defect in SA accumulation. Indeed, the free SA and totalSA (including glucoside-conjugated SA) levels in ald1-T1 plantsinfected with P. s. maculicola DG3 were lower than the levelsin infected wild-type plants at all time points tested (Figure 4C).PR1 defense-related gene expression in ald1-T1 plants alsowas delayed and lower than that seen in the wild type (Figure 3B).Similar results were observed when ald1-T1 and wild-typeplants were infected with P. s. tomato DC3000 (data not shown).Treatment of plants with the SA agonist benzo (1,2,3) thiadiazole-7-carbothioicacid (BTH) before infection resulted in ald1-T1 and wild-typeplants that were equally disease resistant (Figure 4A). Thus,the defect in SA accumulation was likely responsible, at leastin part, for the decreased resistance of ald1-T1.

ALD1 Is Largely Responsible for the Disease Resistance and Small Size of agd2-1
Because agd2-1 had increased resistance to P. syringae and ald1-T1and ald1-T2 had increased susceptibility to P. syringae, wetested whether ALD1 was required for the elevated disease resistanceof agd2-1. Mutant plants with the ald1-T2 allele had no detectableALD1 transcript (data not shown). ald1-T2 was in the same geneticbackground as agd2-1, making it suitable for double mutant construction.agd2-1 ald1-T2 plants had similar disease susceptibility tothat seen in the wild type but still less than that seen inald1-T2 alone (Figure 5). Thus, the majority of the diseaseresistance in agd2-1 was mediated by the ALD1 gene.

We tested whether the suppression of agd2-1 disease resistancein agd2-1 ald1-T2 was correlated with lowered SA levels. Indeed,the agd2-1 ald1-T2 double mutant had a lower basal level oftotal SA (11.2 ± 0.3 µg/g tissue, n = 3) comparedwith the agd2-1 single mutant (18.5 ± 0.4 µg/gtissue, n = 3, P = 0.0001). However, the double mutant stillhad significantly more SA than the wild type (1.3 ± 0.03µg/g tissue, n = 3, P < 0.0001), even though diseasesusceptibility was equivalent in wild-type and agd2-1 ald1-T2plants. This suggests that SA accumulation and ALD1 functioncan only partially explain the disease resistance of agd2-1.

Because depletion of SA in agd2-1 using a nahG transgene alteredthe morphology of agd2-1 (Rate and Greenberg, 2001; Vanackeret al., 2001), we also examined the morphology of agd2-1 ald1-T2plants. agd2-1 ald1-T2 showed tumor-like growths reminiscentof those seen in agd2-1-nahG plants (data not shown), supportinga role for SA in growth control (Vanacker et al., 2001). Strikingly,we also found that the overall size of the agd2-1 ald1-T2 rosetteswas nearly restored to that of the wild type (Table 2). Thesedata suggest that at least some agd2-1 phenotypes are mediatedby the action of ALD1.

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Table 2. Role of ALD1 in agd2-1 Rosette Size

Recombinant AGD2 and ALD1 Have Aminotransferase Activity in Vitro
Protein basic local alignment search tool (BLAST) searches indicatedthat AGD2 and ALD1 had the closest similarity to an aromaticaminotransferase from Pryococcus hirikoshii with highest activityon the amino acid substrates Tyr, Phe, Glu, Trp, and His (Matsuiet al., 2000

). However, the similarity was only modest (25%identity between the aromatic aminotransferase from P. hirikoshiiand both ALD1 and AGD2). Other much higher BLAST matches wereonly to putative amino transferases for which activity has notbeen experimentally validated. To test whether AGD2, AGD2^P398S,and ALD1 had amino transferring activity, we overexpressed recombinantAGD2, AGD2^P398S, and ALD1 proteins in Escherichia coli and performedaminotransferase activity assays. Optimization of the assaysis described in Methods. Six His-tagged truncated versions ofthe proteins lacking potential organelle targeting signals wereoverexpressed and then purified using nickel-nitrilotriaceticacid agarose (Ni²⁺-NTA) beads. The recombinant AGD2, AGD2^P398S,and ALD1 proteins were purified to near homogeneity and migratedon SDS-PAGE at the expected molecular masses (Figure 6A).

We first tested the ability of recombinant AGD2, AGD2^P398S,and ALD1 proteins to catalyze the transfer of amino groups ontothe amino acceptor molecule 2-oxoglutarate in vitro by monitoringthe production of glutamate. This amino acceptor was chosenbecause many characterized aminotransferases are active withthis cosubstrate (Mehta et al., 1993). Recombinant AGD2, AGD2^P398S,and ALD1 were incubated with each of the standard 20 amino acids(except Glu, which was used to monitor these aminotransferasereactions), ß-Ala, ${alpha}$ -aminobutyric acid (AABA), ß-aminobutyricacid, or ${gamma}$ -aminobutyric acid (GABA) as the amino donor. As anegative control, we used extract from E. coli containing vectoralone and purified in the same way as AGD2, AGD2^P398S, and ALD1.The highest enzymatic activity was obtained with Lys for bothAGD2 and ALD1 (Figure 6B). Both enzymes also exhibited someactivity with Ala, Arg, Gln, Met, Leu, and Asn as amino donors.However, they showed no significant activity (the limit of detectionwas 1% of the activity with Lys) with any other standard aminoacids under the conditions tested. It is common for aminotransferasesto have activity with several different substrates (Matsui etal., 2000; Nowicki et al., 2001). ALD1 had activity with AABAbut not with ß-aminobutyric acid or GABA, indicatingthat ALD1 needs an ${alpha}$ -amino group for its activities (Figure 6B;data not shown).

We also tested AGD2, AGD2^P398S, and ALD1 for activity with eachof the standard amino acids (except Ala, which was used to monitorthese aminotransferase reactions), ß-Ala, and AABAusing pyruvate as another amino acceptor and monitoring theproduction of Ala. Pyruvate is the second most common aminoacceptor for aminotransferases after 2-oxoglutarate (Mehta etal., 1993). AGD2 had lower activity with pyruvate than with2-oxoglutarate. However, ALD1 had more activity with pyruvatethan with 2-oxoglutarate (Figure 6B). As expected, AGD2^P398Shad reduced activity relative to the wild-type AGD2 proteinwith all the substrates tested.

Because agd2-1 (Rate and Greenberg, 2001) and ald1-T1 (Figure 4C)mutants have altered SA production, we wondered if ALD2or AGD2 might act in the SA biosynthetic pathway. One step inthis pathway was proposed to convert the oxo-acid prephenateto the amino acid arogenate (Wildermuth et al., 2001). However,we found no detectable activity of AGD2 or ALD1 using prephenateas a cosubstrate with Lys, Ala, or Glu.

In summary, although the BLAST searches with AGD2 and ALD1 revealedmodest similarity to an aminotransferase with highest activitywith Tyr, Phe, Glu, Trp, and His, the empirical data suggeststhat AGD2 and ALD1 do not act on these substrates. Rather, AGD2had its highest activities with Lys, Ala, and Arg, whereas ALD1had its highest activities with Lys, Ala, Arg, Met, and AABA.

AGD2 and ALD1 Act in Different Directions in the Aminotransferase Reaction in Vitro
To evaluate the kinetic properties of the AGD2 and ALD1 enzymesfor three of the best substrates (Lys, Ala, and Arg), the K_mvalues for the individual substrates were determined (Table 3).The K_m of AGD2 was 100-fold higher and the k_cat/K_m valuewas 100-fold lower for Lys when compared with those of ALD1.The K_m values of AGD2 and AGD2^P398S were not significantly different,but the k_cat value of AGD2^P398S was approximately half thatof AGD2, causing the mutant protein to have reduced enzyme efficiency(k_cat/K_m). The K_m values for the amino acids Ala and Arg weremuch lower than that of Lys. They are not good substrates forAGD2 and ALD1, as indicated by the high K_m and low k_cat/K_m values.The K_m values of most aminotransferases are within the 0.1 to5 mM range. For example, the Homo sapiens (human) GABA aminotransferasehas a K_m of 1.27 mM (Jeon et al., 2000), and a broad substratespecificity aminotransferase from Leishmania mexicana has 0.5to 2.5 mM K_m values with aromatic amino acids and aspartate(Vernal et al., 1998).

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Table 3. Kinetic Parameters of Recombinant AGD2- and ALD1-Catalyzed Reactions for Amino Acid Degradation Using Either Lys, Ala, or Arg with2-Oxoglutarate

The high K_m value of AGD2 with Lys suggests that Lys may notbe the in vivo substrate for AGD2. Rather, the function of AGD2may be to synthesize Lys or some other amino acid. To test this,we ran the aminotransferase reaction in reverse and measuredthe K_m values of AGD2 and ALD1 for the oxo-acid pyruvate asthe amino acceptor (6-amino-2-oxohexanoate, the predicted oxo-acidproduced by the forward reaction using Lys and2-oxoglutarate,was not commercially available). The K_m value of AGD2 was 3.08mM, 10-fold lower than that of ALD1 (Table 4). Although AGD2and AGD2^P398S showed similar K_m values, the k_cat/K_m value ofthe wild-type protein was fivefold higher than that of mutantprotein. These observations suggest that the reduction of k_cat/K_mis the cause of the agd2-1 phenotype. These data are consistentwith AGD2 being required for the synthesis of an amino acid(s)and ALD1 functioning to convert amino acid(s) to an oxo-acid(s)in vivo.

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Table 4. Kinetic Parameters of Recombinant AGD2- and ALD1-Catalyzed Reactions for Ala Synthesis Using Glutamate and Pyruvate as Cosubstrates

Amino Acid Profiles in agd2-1, AGD2-Overexpressing Plants, ald1-T2, and Wild-Type Plants Are Similar
The aminotransferase activity of AGD2 could indicate a rolefor AGD2 in the production of Lys and/or other amino acids.To test this, we measured amino acid levels in agd2-1, wild-type(Col), and AGD2-overexpressing transgenic plants. Free aminoacid levels were determined in leaves of young (10 d) and older(17 d) plants. There were no large differences in the relativeamino acid levels of the wild type versus agd2-1 in the youngor older plants, although there were small increases and decreasesin some amino acid levels (data not shown). Plants confirmedby RNA gel blot analysis to overexpress AGD2 driven by the CaMV35S promoter also had similar amino acid levels with wild-typeplants (data not shown). Attempts to rescue the agd2-T and agd2-1plants with major amino acids or mixtures of amino acids usinga previously successful approach for rescuing embryo-defectivebiotin auxotrophs (Patton et al., 1998

) were not successful.These data suggest that AGD2 may not be involved in the synthesisof any standard amino acids.

We also tested if ald1-T1 had abnormal amino acid accumulationafter P. s. maculicola DG3 infection versus the wild type. Usinggas chromatography–mass spectrometry (GC-MS) analysisof methanol extracts, we could see no dramatic differences inthe relative levels of the 20 standard amino acids between ald1-T1and wild-type plants 9 and 24 h after infection. Most othermetabolites were not apparently different except free SA, whichwas 2.5-fold lower in ald1-T1 than the wild type (data not shown),consistent with our HPLC analysis (Figure 4C). These data suggestthat standard amino acids may not be the targets of ALD1 actionin vivo. We wondered if AABA could be an endogenous ALD1 substratebecause it was a good substrate in vitro (Figure 6B). Unfortunately,AABA levels were below the assay detection limit.

DISCUSSION

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RESULTS
DISCUSSION
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Gene duplications and gene families often encode or are assumedto encode proteins with similar and/or overlapping functions.However, the AGD2 and ALD1 genes of A. thaliana have quite divergentroles in development and defense, despite their high sequencesimilarity. AGD2 is indispensable for development and also mayrepress defenses, whereas ALD1 is important for activating defensesand limiting P. syringae growth. The activities of AGD2 andALD1 in vitro significantly differed from each other. Theirenzyme kinetic properties suggest that AGD2 is required forthe synthesis of an amino acid(s), whereas ALD1 may utilizethe same or a related amino acid(s) to make a defense-regulatingmolecule(s) (Figure 7A). The two enzymes may act in differentsubcellular compartments. Transcripts of ALD1 were upregulatedby pathogen infection and senescence, whereas those of AGD2did not accumulate under any of the conditions examined butwere downregulated by dark treatment and during senescence.

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Figure 7. Models for the Enzymatic Functions and Roles of AGD2 and ALD1 in Development and Disease Resistance.

(A) Enzymatic reactions that AGD2 and ALD1 may conduct based on the in vitro data. These reactions may be performed in different subcellular compartments.

(B) Integrated model for AGD2 and ALD1 functions in vivo. When plants are infected with P. s. maculicola DG3, ALD1 is needed for SA accumulation and activation of SA signaling responses, such as PR1 expression. ALD1 also is probably required for the generation of an SA-independent defense signal. AGD2 is required for normal development. Reduced activity of AGD2 results in developmental cell death and growth phenotypes and SA accumulation possibly because of the generation of an amino acid–derived signal or an amino acid imbalance. NPR1 also is shown as controlling development as an example of a protein that functions in defense and development (Vanacker et al., 2001).

Specific Physiological Function of AGD2
We established here that many of the agd2-1 phenotypes are partiallycaused by the presence of the ALD1 gene, possibly through itsupregulation. In particular, some of the elevated SA, P. syringaedisease resistance, and dwarfism can be suppressed when ALD1function is removed from agd2-1 plants. However, the fact thatin agd2-1 the effects of ALD1 are only partial suggests thatthere are ALD1-independent AGD2 functions important for thecontrol of SA synthesis, defense activation, and/or development.

agd2-1 hypomorphic plants have some dead cells and some cellswith altered size and elevated endoreduplication (Rate and Greenberg,2001; Vanacker et al., 2001). The loss-of-function agd2-T plantshad an early defect in embryogenesis, suggesting that AGD2 hasan essential function in plant development. What might thisfunction be? An obvious candidate is the synthesis of one ormore amino acid. In particular, our in vitro experiments suggestthat Lys would be the preferred product. Furthermore, AGD2 localizesto chloroplasts, the site of synthesis of amino acids (Bryan,1990). However, several observations lead to questions abouthow likely this function is for AGD2. First, we saw no significantdecrease in the level of Lys (or other amino acids) in agd2-1.Second, we were unable to rescue the agd2-1 or agd2-T mutantswith Lys or any of the other major amino acids or mixtures ofamino acids. Third, plants are known to make Lys from aspartatevia meso-diaminopimelate (Galili, 1995), which is decarboxylatedto form Lys using the chloroplast-localized diaminopimelatedecarboxylase (Azevedo et al., 1997). A. thaliana has two putativediaminopimelate decarboxylases encoded by the At3g14390 andAt5g11880 genes. These Lys biosynthetic enzymes all should beintact in the agd2 mutants. Possibly, Lys production in A. thalianais primarily formed by decarboxylation of meso-diaminopimelate,but there is a specific requirement for AGD2 during embryogenesisand some stage of leaf development. Our assays may have misseddifferences in Lys (or other amino acids) accumulation at thesespecific stages.

An alternative suggestion is that AGD2 is essential for an unknowndevelopmental regulator/signal molecule produced through Lyssynthesis or through a nonstandard amino acid. Plant hormonesconsist of free and conjugated forms. For example, most indole-3-aceticacid (IAA)–based conjugates accumulate as IAA-ester formsto inositol, sugar, or polysaccharides and IAA-amide forms toamino acids or peptides (Cooke et al., 2002; Ljung et al., 2002).The conjugates are generally thought to act as short-term intermediatesthat can be hydrolyzed to release free forms. Nevertheless,the role of conjugates is still incompletely defined. AGD2 mayprovide a precursor for a conjugated hormone, such as IAA-Lys,which is present in Agrobacterium tumefaciens and P. savastanoi(Glickmann et al., 1998) and may be present in plants. Sucha molecule or one derived from a nonstandard amino acid mightbe important for embryogenesis.

agd2-1 hypomorphic plants also have increased disease resistance(Rate and Greenberg, 2001), which implicates AGD2 directly orindirectly in repressing defenses. As stated above, this phenotypeis partially attributable to ALD1 function. The agd2-T knockoutmay have a lethal phenotype because of the derepression of defenseresponses, including programmed cell death. There is precedencefor a mutation in a defense component conferring a lethal phenotype.Plants lacking RPM1-interacting protein 4 show lethality (Mackeyet al., 2002) that is likely to be because of the direct activationof an R gene pathway that activates cell death (Axtell and Staskawicz,2003; Mackey et al., 2003). A link between developmental controland defense regulation also has been found for several defenseregulatory genes (Vanacker et al., 2001; Holt et al., 2002;Jin et al., 2002; Barth and Conklin, 2003).

Specific Physiological Function of ALD1
ALD1 activity is important for P. syringae disease resistance.What might account for the increased disease susceptibilityof ald1 mutants? An important clue comes from the observationthat SA levels are reduced in ald1 upon pathogen infection andthat agd2-1 ald1-T2 plants have less SA than agd2-1 alone. ALD1possibly synthesizes a signal important for inducing SA synthesis.That the SA agonist BTH can induce disease resistance in ald1supports this possibility. We have no evidence for ALD1 actingdirectly in the SA biosynthetic pathway because the enzyme wasnot active with any proposed SA biosynthetic intermediates.

The control of SA production may not be the sole function ofALD1. The wild-type level of disease susceptibility of agd2-1ald1-T2 plants that still have $~$ 8.6-fold elevated SA relativeto the wild type suggests that ALD1 also controls the synthesisof another defense signal. Several other genes in A. thaliana,such as PAD1, PAD2, PAD4, EDS1, EDS3, EDS4, EDS8, NDR1, andACD6, are similar to ALD1 in that mutations in these genes alsolead to reduced SA accumulation during infection by at leastone strain of P. syringae (Glazebrook et al., 1996, 1997, 2003;Zhou et al., 1998; Gupta et al., 2000; Feys et al., 2001; Shapiroand Zhang, 2001; Lu et al., 2003). However, no demonstratedbiochemical activity has been associated with the products ofthese genes. In the case of pad4, the mutation has been suggestedto affect both SA-dependent defenses and possibly additionaldefenses (Glazebrook et al., 2003). Whether ALD1 acts in thesame or separate pathways with PAD4 and/or other SA-regulatorygenes remains to be determined.

ALD1 also may have a direct role in synthesizing antimicrobialcompounds. Precedent for an aminotransferase having such a functioncomes from Streptomyces virginae, which uses Lys2-aminotransferaseto synthesize a cyclohexadepsipeptide antibiotic (Namwat etal., 2002).

Relationship and Roles of AGD2 and ALD1 in Development and Defense
The opposing defense phenotypes of agd2-1 and ald1 are strikingbecause AGD2 and ALD1 likely drive the aminotransferase reactionon related substrates in opposite directions. A model for howthese enzymes function is shown in Figure 7B. AGD2 is shownpromoting development based on its requirement for embryogenesisin agd2-T and the abnormal leaf morphology in agd2-1 (Rate andGreenberg, 2001). AGD2 also is shown having a second functionrepressing defenses. Because agd2-1 showed constitutive defensesbefore morphological alterations were apparent (Rate, 2000;Rate and Greenberg, 2001), the effect of agd2-1 on defense activationis shown as independent from the effect on development (althoughformally the developmental phenotype could cause the defensephenotype or vice versa). We speculate that in agd2-1, an aminoacid–derived signal (possibly related to the ALD1 substrate),an amino acid imbalance, or the presence of a developmentalregulator results in cross talk to the defense pathway. Aminoacid starvation is known to activate plant defenses (Zhao etal., 1998). In support of a relationship between the substratesand products of the AGD2 and ALD1 enzymatic reactions, we foundthat ald1-T2 could in large part suppress the reduced rosettesize and other phenotypes of agd2-1.

We have no direct evidence for any large differences in theamino acid compositions of wild-type and agd2-1 plants. However,we most likely missed amino acids that are either conjugatedto other molecules (such as hormones), are present only transiently,or are low in abundance. Possibly, any amino acid imbalancecaused by agd2-1 is very transient because of the conversionof AGD2 substrates into alternative products. In our model,ALD1 functions to regulate SA synthesis and a second defensesignal through an amino acid–derived signal. This is basedon the results discussed above showing that agd2-1ald1-T2 plants,which still have residual elevated SA, show pathogen susceptibilityequal to that of wild-type plants. The second defense signalpostulated to be regulated by ALD1 could be directly producedby ALD1.

In summary, we have shown that two related aminotransferasesperform divergent yet critical functions to control plant developmentand defense. Our study implicates amino and/or oxo-acids ashaving central roles in these processes.

METHODS

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Plant Materials, Treatment, and Pathogen Infection
The agd2-1 A. thaliana mutant in the Col background was describedpreviously (Rate and Greenberg, 2001). T-DNAs in AGD2 and ALD1(agd2-T and ald1-T1, respectively) in the Ws background wereobtained by screening the T-DNA insertion library at the Universityof Wisconsin (http://www.biotech.wisc.edu/). Another ALD1 T-DNAallele (ald1-T2; SALK_007673) in Col was obtained from the Salkcollection (http://signal.salk.edu/cgibin/tdnaexpress/).

Plants were grown and infections done as described previously(Greenberg et al., 2000). P. s. maculicola DG3 derived fromP. s. maculicola strain ES4326 was described previously (Guttmanand Greenberg, 2001). P. s. tomato DC3000 was obtained fromF.M. Ausubel (Massachusetts General Hospital, Boston, MA).

BTH was a gift from Robert Dietrich (Syngenta, Research TrianglePark, NC). BTH treatments were done by spraying 16- to 18-d-oldplants until all the leaves were wet. During dark treatment,plants were covered with an aluminum foil–wrapped plasticdome.

Recombination Mapping and Complementation Tests
To map AGD2, agd2-1 (ecotype Col) was crossed to ecotype Landsberg.Homozygous agd2-1 F2 plants were used for recombinant analysisusing published cleaved amplified polymorphic sequences (CAPS)and simple sequence length polymorphism markers (Konieczny andAusubel, 1993; Bell and Ecker, 1994). To identify new CAPS markers,primers were designed using the published sequence (http://www.arabidopsis.org/cereron/).AGD2 was mapped to a 65-kb interval between the CAPS markersC5-2 and C7-2N. The primers used for C5-2 were 5'-GATCGGAGGCATGCATTACAG-3'and 5'-TCCGAACAATCCAGCATTACC-3'. The primers for C7-2N were5'-TTCTCCTTCAGCACCTTGAAC-3' and5'-CTACCCAGAGGTTTAACGACG-3'.Enzymes used for these CAPS markers were ApoI (C5-2) and DraI(C7-2N). The A. thaliana genomic BAC clone T16L1 (The ArabidopsisInformation Resource, http://www.arabidopsis.org) covering thisregion was subcloned into the binary vector pAOV-CaMV. Thisvector is a modified version of pAOV (Mylne and Botella, 1998)lacking the CaMV 35S promoter, which was removed by digestingpAOV with HindIII and XbaI and filling in the overhangs. Subcloneswere transformed into agd2-1 as described (Clough and Bent,1998). A defined AGD2 genomic clone (a 7280-bp SacI fragmentfrom BAC clone T16L1) in pAOV-CaMV and the AGD2 cDNA (AV524925)driven by the CaMV 35S promoter cloned into pAOV were used forcomplementation of agd2-1. For complementation of ald1-T1 andald1-T2, a genomic clone of ALD1 was subcloned as a 7970-bpXbaI-ScaI fragment from BAC clone F17L24 into pAOV-CaMV andtransformed into ald1-T1 and ald1-T2 plants.

RNA Gel Blot Analysis
Total RNA was isolated as described (Kroczek and Siebert, 1990).The RNA ( $~$ 8 µg) was separated by electrophoresis on a 1%agarose gel. Hybridization was performed as described (Sambrooket al., 1989). Gene-specific DNA probes for AGD2 or ALD1 weremade using PCR to amplify a portion (3' end) of each gene fromcDNA. The primers used for AGD2 were 5'-CTGCACTTGTTTCAATGGTGC-3'(sense primer) and 5'-CACTGGTGTCAAAAGTGTCTTC-3' (antisense primer).The primers for ALD1 were 5'-GAGATACGGTCGGTGAACAACT-3' (senseprimer) and 5'-CAAGACGATGCACATAACACG-3' (antisense primer).Single-stranded probes were synthesized using the antisenseprimers.

Purification and Assays of Recombinant AGD2 and ALD1 Proteins
The AGD2 and ALD1 genes were amplified using PCR with the followingprimers using the cDNA clones of AGD2 (GenBank accession numberAV524925), AGD2^P398S (obtained using RT-PCR), and ALD1 (GenBankaccession number AY057526) as templates. For AGD2 and AGD2^P398S,the sequences of primers were 5'-GCAAACCCGGGCAATACTTGCAAATGTGTTGC-3'(underlined sequence indicates the SmaI site) and 5'-AAACAACCCGGGTCATTTGTAAAGCTGCTTGA-3'(underlined and boldface sequences indicate the SmaI site andthe stop codon, respectively). For ALD1, the sequences of primerswere 5'-TGGCTCGAGATTCCCAAGGCTAGTTTGGAC-3' (underlined sequenceindicates the XhoI site) and 5'-TGGCTCGAGATCCTAATTGGTATTAGAAGT-3'(underlined and boldface sequences indicate the XhoI site andthe stop codon, respectively). These recombinant AGD2 (or AGD2^P398S)and ALD1 genes used for producing recombinant proteins lackedsequences encoding the first 40 and 20 amino acids, respectively.These N-terminal sequences corresponded to possible plastid-targetingsignals. PCR products containing the AGD2, AGD2^P398S, and ALD1genes were digested with SmaI and XhoI and then ligated intothe expression vector pET14b (Novagen, Madison, WI) cut withthe appropriate restriction enzyme. The recombinant plasmidswere transformed into E. coli BL21 (DE3) pLysS. To induce productionof the 6x-His-tagged recombinant enzymes, bacterial culturesgrown to an A₆₀₀ of 0.7 to 0.9 in LB medium containing 100 µg/mLampicillin at 37°C were treated with isopropyl-ß-D-thiogalactopyranosideat a final concentration of 1 mM. Incubation was allowed tocontinue at 20°C for an additional 12 h, and the cells wereharvested. Cell pellets were resuspended in one-tenth the culturevolume in a solution containing 50 mM Tris-HCl buffer, pH 8.0,and then subjected to two cycles of freezing and thawing. Thecrude extracts were treated with DNase and MgCl₂ to final concentrationsof 10 µg/mL and 20 mM, respectively, at room temperaturefor 30 min. After centrifugation, imidazole and NaCl were addedto the supernatant to final concentrations of 5 and 500 mM,respectively. The 6x-His-tagged fusion proteins were purifiedunder native conditions using Ni²⁺-NTA agarose beads (Qiagen,Valencia, CA). The lysates were incubated for at least 30 minwith binding buffer (5 mM imidazole, 50 mM NaCl, and 50 mM Tris-HCl,pH 8.0) containing Ni²⁺-NTA agarose beads. Elution was performedby a linear gradient of 5 to 200 mM. The recombinant proteinseluted at nearly 80 mM imidazole. Purified enzymes were storedat 4°C for 2 weeks without significant loss of the activity.Protein concentrations were determined as described (Bradford,1976) using BSA as a standard.

The recombinant AGD2, AGD2^P398S, and ALD1 activities were determinedby measuring the concentration of the reaction product glutamateor Ala. The assay buffer contained 50 mM Tris-HCl (pH 8.0),100 mM MgCl₂, and 1 µM pyridoxal-5-phosphate. Activitiesof the recombinant enzymes were found to be highest at 37°Cin Tris-HCl, pH 8.0, and 100 mM MgCl₂. The optimum temperaturefor the recombinant enzymes was determined using assay buffercontaining 50 mM Tris-HCl (pH 8.0), 100 mM MgCl₂, and 1 µMpyridoxal-5-phosphate with 50 mM Lys as the amino donor and50 mM 2-oxoglutarate as the amino acceptor at 4, 15, 25, 30,37, 45, 50, and 65°C for 4 h. The pH dependence of the enzymeswas determined at 37°C using three different buffer systems.Reactions were performed in 50 mM sodium acetate buffer at pHvalues ranging from 4.0 to 6.0, in 50 mM sodium phosphate bufferat pH values ranging from 6.0 to 7.0, and in 50 mM Tris-HClbuffer at pH values ranging from 7.0 to 10.0. Effects of variouscations on activities also were examined. Cations such as Cu²⁺,Mn²⁺, and NH₄⁺ did not significantly activate the activitiesat 100 mM each, whereas Ca²⁺, Na⁺, and K⁺ showed better activationeffects. The highest activities were in 100 mM MgCl₂. Afterthe reaction, samples were applied to a thin-layer chromatographicplate (Si250; J.T. Baker, Phillipsburg, NJ) and developed withn-butyl alcohol:acetic acid:water (3:1:1, v/v). The chromatogram,dried at 60°C and cooled to room temperature, was soakedin freshly prepared ninhydrin solution (0.2% in acetone) for1 min (Bhushan and Martens, 2001). To quantify the signals,the National Institutes of Health Image J program was used (http://rsb.info.nih.gov/ij/).

SA Measurements
Free and total SA (the sum of free and glucosyl SA) was extractedand quantified as described previously (Seskar et al., 1998).

Subcellular Localization of AGD2
The gfp gene was translationally fused at the 3' end of thecDNA of AGD2 gene in plasmid pAOV (Mylne and Botella, 1998)behind the CaMV 35S promoter to give pAGD2-GFP. The plasmidpAGD2-GFP or pGFP (GFP alone driven by the CaMV 35S promoter)was introduced into A. tumefaciens (GV3101) and then transformedinto A. thaliana plants. Protoplasts from leaves of transgenicplants were isolated as described (Asai et al., 2000). GFP localizationand chlorophyll autofluorescence were observed using a fluorescencemicroscope (Axioskop; Carl Zeiss, Jena, Germany) with fluoresceinisothiocyanate and UV filters, respectively.

Amino Acid Analysis
Approximately 200 mg of fresh leaves were ground in liquid N₂in the presence of water:methanol:chloroform (2:3.5:8) (Palaniveluet al., 2003). The homogenate was extracted and centrifuged.The supernatant was dried by passing nitrogen gas over it. Theresidue was resuspended in water and submitted to the MolecularStructure Facility at University of California (Davis, CA) foramino acid analysis by HPLC (Palanivelu et al., 2003).

GC-MS Analysis
Leaves of Ws and ald1-T1 plants were infected with P. s. maculicolaDG3 (OD₆₀₀ = 0.01). The infected leaves (50 mg) at 9 and 24h after infection were ground in liquid N₂ in 1.4 mL of 100%methanol with 50 µL internal standard (2 mg of ribitol/1mL of water) (Roessner et al., 2000). The mixture was extractedwith 1 volume of water and subsequently centrifuged. The supernatantwas dried and analyzed by the Michigan State University MassSpectrometry Facility (East Lansing, MI) using GC-MS. GC-MSconditions and the system for the analysis of metabolites wereperformed as described (Roessner et al., 2000).

Characterization of O. sativa cDNAs for OsAGD2 and OsALD1
The stop codons of the cDNAs were determined by RT-PCR usingprimers located at the stop codons of the annotated genomicsequences and/or by homology between the O. sativa and A. thalianagenes. The 5' ends of the O. sativa cDNAs were determined by5' rapid amplification of cDNA ends PCR according to the Invitrogenmanual (Carlsbad, CA). GenBank accession numbers of cOsAGD2and cOsALD1 are AY338235 and AY338236, respectively.

Sequence data from this article have been deposited with theEMBL/GenBank data libraries under accession numbers AY338235,AY338236, AV524925, and AY057526.

Acknowledgments

We thank Ravishankar Palanivelu for advice and critical readingof the manuscript. We thank Brian Traw and Joy Bergelson fortheir assistance with SA quantitation. We are grateful to theABRC at the Ohio State University and Kazusa DNA Research Institutefor clones. This work was supported by National Institutes ofHealth Grant 5R01 GM54292 to J.T.G. and the postdoctoral fellowshipprogram of the Korea Science and Engineering Foundation to J.T.S.

Footnotes

The author responsible for distribution of materials integralto the findings presented in this article in accordance withthe policy described in the Instructions for Authors (www.plantcell.org)is: Jean T. Greenberg (jgreenbe{at}midway.uchicago.edu).

Article, publication date, and citation information can be foundat www.plantcell.org/cgi/doi/10.1105/tpc.019372.

Received November 17, 2003; accepted November 26, 2003.

REFERENCES

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INTRODUCTION
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METHODS
REFERENCES

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