Glucose Conjugation of Anthranilate by the Arabidopsis UGT74F2 Glucosyltransferase Is Required for Tryptophan Mutant Blue Fluorescence*

Juan A. QuielDagger and Judith Bender§

From the Department of Biochemistry and Molecular Biology, the Bloomberg School of Public Health, The Johns Hopkins University, Baltimore, Maryland 21205

Received for publication, November 20, 2002, and in revised form, December 9, 2002

    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Plant mutants with defects in intermediate enzymes of the tryptophan biosynthetic pathway often display a blue fluorescent phenotype. This phenotype results from the accumulation of the fluorescent tryptophan precursor anthranilate, the bulk of which is found in a glucose-conjugated form. To elucidate factors that control fluorescent tryptophan metabolites, we conducted a genetic screen for suppressors of blue fluorescence in the Arabidopsis trp1-100 mutant, which has a defect in the second enzymatic step of the tryptophan pathway. This screen yielded loss-of-function mutations in the UDP-glucosyltransferase gene UGT74F2. The bacterially expressed UGT74F2 enzyme catalyzed a conjugation reaction, with free anthranilate and UDP-glucose as substrates, that yielded the same fluorescent glucose ester compound as extracted from the trp1-100 mutant. These results indicate that sugar conjugation of anthranilate by UGT74F2 allows its stable accumulation in plant tissues. A highly related Arabidopsis enzyme UGT74F1 could also catalyze this reaction in vitro and could complement the ugt74F2 mutation when overexpressed in vivo. However, the UGT74F1 gene is expressed at a lower level than the UGT74F2 gene. Therefore, even though UGT74F1 and UGT74F2 have redundant conjugating activities toward anthranilate, UGT74F2 is the major source of this activity in the plant.

    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The Arabidopsis genome encodes over 100 predicted UDP-glucosyltransferase (UGT)1 genes (1). These genes are identified by a conserved amino acid motif in the carboxyl-terminal region of the protein sequence that binds the common UDP-glucose substrate molecule. UGT enzymes can form either glucose esters or glucosides with a wide range of substrate molecules. These enzymes serve a variety of important biological functions, including converting metabolically active molecules into inactive storage/transport forms or in some cases generating intermediates for the subsequent conversion into other metabolites. To understand the substrate specificity of the Arabidopsis UGTs, ninety of these enzymes have been expressed in bacteria and are being systematically tested for activity against a battery of potential substrate compounds. This strategy has identified specific Arabidopsis UGTs that can use the plant growth regulator indole-3-acetic acid (IAA) (2), various phenylpropanoid compounds (3), and various hydroxybenzoic acid compounds (4) as substrates in vitro. However, understanding the roles of specific UGTs in the plant is only in its early stages.

The previous in vitro screening strategy identified the UGT74F1 and UGT74F2 enzymes as being able to use benzoic acid, 2-hydroxybenzoic acid (salicylic acid), and 3-hydroxybenzoic acid as substrates for glucose conjugation (4). Here we report that UGT74F1 and UGT74F2 can also use the tryptophan precursor compound 2-aminobenzoic acid (anthranilate) as a substrate for glucose ester conjugation both in vitro and in vivo. This finding has important implications for understanding the flux of metabolites in the tryptophan pathway.

The tryptophan pathway is of particular interest in plants, because it provides critical secondary metabolites, including the growth regulator IAA and indole glucosinolate defense compounds (5). Studies of this pathway have been greatly facilitated by the isolation of mutants with defects in tryptophan biosynthetic enzyme structural genes. A striking feature of some tryptophan mutants is a blue fluorescent phenotype under ultraviolet (UV) light, caused by accumulation of the first intermediate compound in the pathway, anthranilate (see Fig. 1). For example, the Arabidopsis mutant trp1-1, which has a defect in the second enzyme of the pathway, is strongly fluorescent throughout the plant (6). Biochemical analysis showed that the major fluorescent compound present in this mutant is an anthranilate-glucose conjugate.

Blue fluorescence due to tryptophan pathway mutations is a valuable reporter phenotype for probing tryptophan metabolism (7-9). This reporter phenotype has also been exploited to study factors that regulate cytosine methylation and gene silencing in plants (10-13). For example, a blue fluorescence Arabidopsis mutation, the weak trp1-100 allele in the gene encoding the second enzyme of the pathway (14, 15), was used to identify second site mutations that block the production of fluorescent compounds (7). In this work, the goal was to recover mutations that impair the synthesis of anthranilate. The suppressor mutations were therefore characterized for whether they conferred tryptophan auxotrophy. This screen yielded two trp4 loss-of-function alleles in the anthranilate synthase beta  subunit-encoding gene ASB1 (Fig. 1). Several other suppressor mutations were isolated in this screen, but because they were not tryptophan auxotrophs they were not studied further.


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Fig. 1.   The tryptophan pathway in Arabidopsis. The series of enzymatic conversions that lead to the synthesis of tryptophan are represented by arrows, with the chemical structures of the first compound in the pathway, anthranilate, and its sugar-conjugated form shown. The trp4 mutations affect an anthranilate synthase (AS) beta  subunit gene, and the trp1 mutations affect the gene encoding phosphoribosylanthranilate transferase (PAT).

To better understand the homeostasis of fluorescent metabolites in tryptophan mutants, we extended the previous trp1-100 fluorescence suppressor analysis with a focus on non-auxotrophic isolates. This study yielded a single major complementation group of suppressor mutations with loss-of-function defects in UGT74F2, which catalyzes glucose conjugation to anthranilate through an ester linkage. Our findings provide new insights into specificity and function for the large and important plant UGT enzyme family.

    EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Mutant Isolation-- The Columbia (Col) trp1-100 gl1-1 strain was mutagenized by ethyl methane sulfonate as previously described (7). Seedlings were screened for fluorescence by plating on plant nutrient plus 0.5% sucrose (PNS) agar medium (16) and inspecting under short-wave UV light from a hand-held source at 2 weeks. This screen yielded the six alleles P155S, E206K, T341I, G344D, W364*, and W421*. The ugt74F2 alleles obtained from a previous screen were isolated by similar methods except that the agar medium contained supplements of tryptophan, phenylalanine, tyrosine, and para-aminobenzoic acid to aid the growth of aromatic amino acid auxotropic seedlings (7). This screen yielded the four alleles G64D, Q153*, i1a, and Q327*. All the trp1-100 ugt74F2 alleles were back-crossed at least one time to trp1-100 prior to subsequent analysis. The Wassilewskija (WS) pat1E151K mutant was isolated in a previously described screen for fluorescent mutants in the WS background (11). The mutation was found to be allelic with trp1-100 in complementation crosses. The PAT1 gene was PCR-amplified and sequenced from the mutant to determine the nature of the mutation. The wild type WS PAT1 gene was also sequenced to determine Col versus WS polymorphisms in the gene, and the sequence is available as GenBankTM AF498914.

Positional Cloning-- The splice junction allele ugt74F2i1a was used for positional cloning of the locus. The Col trp1-100 gl1-1 ugt74F2 strain was crossed to WS pat1E151K, and F2 progeny of the cross were scored for non-fluorescence, diagnostic of ugt74F2 homozygosity. A population of non-fluorescent F2 plants was used for mapping with standard cleaved amplified polymorphic sequence (17) and single sequence length polymorphism (18) markers that are polymorphic between the Col and WS strain backgrounds. This analysis showed linkage to the m429 cleaved amplified polymorphic sequence marker on the lower arm of chromosome 2. Additional Col versus WS polymorphic markers in the region were developed based on known polymorphisms between Col and the Landsberg erecta strain. Fine-structure mapping with these markers on a population of 710 plants from the mapping cross narrowed down the mutant locus to the region between the markers 56IN-F18O19 and 28IN-F4I1. The 56IN-F18O19 marker used primers 56IN-F18O19F 5'-GATCAATGATTGATTGAGTGG-3' and 56IN-F18O19R 5'-TCTTGCATTTCCTCCTTGGTG-3'; these primers amplify a 226-bp fragment in Col versus a 170-bp fragment in WS. The 28IN-F4I1 marker used primers 28IN-F4I1F 5'-TATGAATTCGAGTGTGTTTGCG-3' and 28IN-F4I1R 5'-GACATGATTGTCTTCCAAATG-3'; these primers amplify a 209-bp fragment in Col versus a 181-bp fragment in WS. No recombination breakpoints were detected at a central marker 29IN-F16E13. The 29IN-F16E13 marker used primers 29IN-F16E13F 5'-TCTAATTGTGGTTGGTAAATC-3' and 29IN-F16E13R 5'-GTAGTTAGACAACATGAGTTAC-3'; these primers amplify a 224-bp fragment in Col versus a 195-bp fragment in WS. Mutant alleles were amplified by PCR and cloned into the pGEM-T Easy vector (Promega) for sequencing. Two independent PCR products were sequenced for each allele to control for PCR-induced mutations.

PCR-based Genotyping of trp1-100 and ugt74F2 Mutations-- Neither the trp1-100 nor the ugt74F2 splice junction mutation changes a restriction enzyme recognition site. However, we were able to convert these base changes into restriction site changes by combining them with nearby mismatches in PCR primers, which result in PCR amplification of novel DNA species (19). For the trp1-100 mutation, we used primers TRP1100F 5'-GCTAAATGATCTTCGTCTGG-3', and TRP1100R 5'-CCACTCCTAGTGCCTCTAGTACATCAGAG-3', where the underlined base is mismatched with the genomic sequence. This primer set amplifies a 114-bp fragment. For TRP1 template DNA, the fragment cleaves with HaeII into 84- and 30-bp products, whereas for trp1-100 template DNA the fragment does not cleave with HaeII. For the ugt74F2 splice mutation, we used primers BKD4F 5'-CATGTACTAACTGCTCTTTTTTTGTTTACC-3', and BK-D4R 5'-GGTCTAAGTAAATTGATGG-3', where the underlined base is mismatched with the genomic sequence. The primer set amplifies a 104-bp fragment. For UGT74F2 template DNA, the fragment cleaves with MspI into 74- and 30-bp products, whereas for ugt74F2 splice mutant template DNA the fragment does not cleave with MspI.

Plant Transformation-- An Agrobacterium tumefaciens-mediated in planta transformation method was used to introduce transgene constructs into Arabidopsis (20). The Col trp1-100 gl1-1 ugt74F2 splice junction mutation strain was used for transgene complementation experiments. This strain was transformed with four constructs: a UGT74F2 genomic clone, a UGT74F1 genomic clone, the UGT74F2 cDNA driven by the 35S promoter, and the UGT74F1 cDNA driven by the 35S promoter. Genomic sequences of both UGT74F2 and UGT74F1 were obtained by hybridization screening of a Col genomic plaque library (8). The UGT74F2 genomic clone consisted of an EcoRV fragment extending from 2.3 kb upstream of the translational start codon to 0.5 kb downstream of the translational stop codon inserted in the filled-in KpnI site of the pBIN19 plant transformation vector (21). The UGT74F1 genomic clone consisted of an XbaI fragment extending from 1.8 kb upstream of the translational start codon to 2.4 kb downstream of the translational stop codon inserted into the XbaI site of pBIN19. The full-length UGT74F2 cDNA was obtained as an EST isolate 127P19T7 from the Arabidopsis Biological Resource Center. This cDNA was cloned in the sense orientation as a blunt-ended fragment into the SmaI site of the 35S expression vector pBICaMV (22). The full-length UGT74F1 cDNA was obtained by RT-PCR, and cloned as an EcoRI fragment into the EcoRI site of pBICaMV. For the UGT74F2 genomic transgene, all of 44 transformants were fluorescent. For the UGT74F1 genomic clone, all of 40 transformants were non-fluorescent. For the 35S-UGT74F2 cDNA construct, 23 out of 31 transformants were fluorescent. For the 35S-UGT74F1 cDNA construct, 11 out of 38 transformants were fluorescent. We suspect that the non-fluorescent 35S-UGT74F2 and 35S-UGT74F1 isolates did not express the transgene sequences due to transgene silencing. Southern blot analysis of the 35S-UGT74F2 cDNA transgenic lines revealed that the non-complementing lines contained high copy numbers of the transgene, consistent with this hypothesis.

RNA Gel Blot Analysis-- Plant RNA extractions, formaldehyde gel electrophoresis, transfer to nylon membranes, and hybridization with radiolabeled probes were performed as previously described (23). Probes were cDNA fragments from the indicated genes. The UGT74F2 (At2g43820) probe was an internal NcoI fragment. The UGT74F1 (At2g43840) probe was an internal EcoRV fragment. Neither of these probes significantly cross-hybridized to the related gene, as determined by high stringency Southern blot analysis. The beta -tubulin-4 (TUB) full-length cDNA (At5g44340) probe was used as a control for loading differences. RNA blot results were reproduced in two or three independent experiments.

UGT74F2 and UGT74F1 Protein Expression and Enzyme Assays-- The UGT74F2 cDNA EST clone was modified by oligonucleotide-directed mutagenesis (24) to create an NdeI site at the start codon of the gene. The cDNA was then subcloned as an NdeI to BamHI fragment into the corresponding sites in the pGEX* vector (25) to make an amino-terminal GST fusion of the protein expressed from the lac promoter. An analogous GST fusion construct was made for the UGT74F1 cDNA by similar methods. All constructs were verified by DNA sequencing. The constructs were transformed into the BL21(DE3) bacterial strain harboring a helper plasmid, JY2, that encodes both the AGA-specific argU tRNA and T7 lysozyme (26) for protein expression. Expression was induced by the addition of 0.4 mM isopropyl-1-thio-beta -D-galactopyranoside to mid-logarithmic cultures of each strain grown in 2XYT broth (16 g of tryptone, 10 g of yeast extract, 5 g of sodium chloride per liter of water) at 17 °C. Cells were harvested after 16 h of induction. GST fusion proteins were purified from cell lysates using glutathione-coupled Sepharose gel according to the manufacturer's instructions (Amersham Biosciences) and assessed by Coomassie Blue gel analysis. Enzyme activity assays were performed with 1 µg of purified protein, 2 mM of anthranilate (Sigma A1506), 14 mM 2-mercaptoethanol (Sigma M6250), and 5 mM UDP-glucose (Sigma U4625) in 50 mM Tris-HCl, pH 7.0, buffer. Reactions were incubated for 30 min at 30 °C before stopping by addition of 20 µl 240 mg/ml trichloroacetic acid. Reaction products were analyzed by TLC analysis using Silica Gel 60 TLC plates (VWR EM5721-7) using a 55:25:20 ethyl acetate:chloroform:formic acid mixture as mobile phase. Plant extracts for TLC analysis of fluorescent compounds were prepared as previously described (6). For mass spectrometry, fluorescent spots were scraped off of TLC plates, extracted with ethyl acetate, passed over a ZipTip C4 desalting system (Millipore Corp.) according to manufacturer's instructions, and dried down. Electrospray ionization-mass spectrometry was performed at The Scripps Center for Mass Spectrometry facility. For analysis of conjugate linkages, conjugates were purified from TLC plates as described above. Conjugate treatments were as follows: TLC-purified fluorescent conjugate compounds were resuspended in water and incubated either in 10 mM Tris, pH 6.8, at 37 °C for 5 min (mock treatment), in 0.1 N sodium hydroxide for 1 h at 25 °C before neutralization with 3 M sodium acetate, pH 5.2 (NaOH treatment), with 2.5 units of beta -glucosidase in 50 mM sodium citrate, pH 5.0, at 37 °C for 5 min (beta -glucosidase treatment), or with 2.5 units of alpha -glucosidase in 10 mM Tris-HCl, pH 6.8, at 37 °C for 5 min (alpha -glucosidase treatment). Commercially available beta -glucosidase (Sigma G4511) and alpha -glucosidase (Sigma G3651) were used to test the nature of the linkage of the anthranilate glucose conjugate.

Evaluation of Enzyme Kinetics-- For the evaluation of Michaelis-Menten kinetic parameters, enzyme assays were performed as described above using a range of anthranilate concentrations from 0 to 3 mM. Consistent with previous reports (4) we found that both enzymes, UGT74F1 and UGT74F2, sustained linear activity at 20 °C for at least 60 min; therefore, we conducted our kinetics analysis at this temperature. Reactions were stopped as described above, quick-frozen, and stored until further analysis. The reverse-phase HPLC analysis of enzyme reactions was performed using a Varian ProStar HPLC system. Resolution of free and conjugated anthranilate was achieved over a LUNA 5-µm C18 column (150 × 4.6 mm, Phenomenex) using a linear gradient (10-65% over 20 min) of acetonitrile in water (0.1% trifluoroacetic acid) at a rate of 1 ml/min. Absorbance was monitored at 320 nm. The retention times under our HPLC conditions were 5.4 and 7.6 min for the conjugated and free anthranilate forms, respectively. The specific activity for each enzyme was expressed as nanomoles of anthranilate glucosylated per second (nanokatals) by 1 mg of recombinant protein at 30 min of reaction time at 20 °C with 1 mM anthranilate and 5 mM UDP-glucose. The Michaelis-Menten kinetics parameters, Km and kcat/Km were derived from Lineweaver-Burk plots. To estimate the upper limit of Km for the UGT74F2 enzyme, we assumed that the rate was 85% of Vmax at the lowest substrate concentration assayed (based on 15% error on individual measurements) and calculated Km accordingly.

    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Isolation of ugt74F2 Mutations-- The ugt74F2 mutations described here were isolated by screening ethyl methane sulfonate-mutagenized Col trp1-100 seedlings for loss of cotyledon fluorescence (see "Experimental Procedures"). The trp1-100 mutation is caused by a serine to asparagine mutation at codon 224 of the PAT1 gene, which encodes phosphoribosylanthranilate transferase (15). This defect confers strong fluorescence in cotyledons and weaker fluorescence in adult plant tissues without any additional morphological or fertility defects (14). The trp1-100 fluorescence phenotype is caused by accumulation of glucose-conjugated anthranilate (6).

The suppressor screen yielded six independent trp1-100 ugt74F2 mutant isolates that were non-fluorescent both in seedling tissues (Fig. 2) and in adult rosette leaves but displayed weak residual fluorescence in silique tissue (data not shown). The residual silique fluorescence is likely to be due to the activity of an UGT74F2-related gene product UGT74F1 (see Fig. 7 results below). The ugt74F2 suppressor mutations in the trp1-100 background were found to be recessive when back-crossed to the trp1-100 parental strain, yielding fluorescent F1 heterozygous plants and segregating ~25% non-fluorescent seedlings in the F2 generation. The suppressor mutations comprised a single complementation group: pairwise crosses between mutant candidates yielded non-fluorescent F1 heterozygous seedlings. The trp1-100 ugt74F2 double mutants had no obvious morphological phenotypes.


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Fig. 2.   ugt74F2 trp1-100 mutant phenotypes. Representative 2-week-old seedlings of the indicated strains are shown under visible light (upper panels) and UV light (lower panels). The F1 seedling has the genotype trp1-100/trp1-100 ugt74F2/UGT74F2. The ugt74F2 i1a splice site allele is shown. Similar suppression of fluorescence was observed for all the other ugt74F2 alleles isolated except the ugt74F2G64D allele, which was weakly fluorescent in this assay.

We also received a set of non-auxotrophic suppressors of trp1-100 fluorescence that were recovered in the previous screen that yielded the trp4 mutations (7). These previously isolated mutants included an additional four alleles of ugt74F2, as determined by complementation crosses. One of these alleles displayed only a partial suppression of fluorescence in seedling and leaf tissues.

Positional Cloning of ugt74F2 Mutations-- To understand the molecular nature of the trp1-100 suppressor mutants, we cloned the ugt74F2 suppressor locus by positional methods. For this analysis, we took advantage of a fluorescent trp1-100-like mutant that was isolated in the polymorphic strain background WS. The WS mutant carries a glutamic acid to lysine missense mutation of codon 151 of the PAT1 gene (WS pat1E151K). Similarly to trp1-100 mutation in the Col PAT1 gene, the WS pat1E151K allele conferred fluorescence without additional morphological defects. For mapping, a representative Col ugt74F2 trp1-100 (pat1S224N) double-mutant isolate was crossed to the WS pat1E151K mutant, and F2 progeny seedlings were examined for the suppressed non-fluorescent phenotype diagnostic of the homozygous ugt74F2 suppressor mutation. Approximately 25% of the F2 progeny of the mapping cross were non-fluorescent, showing that the ugt74F2 defect can suppress both pat1 mutations segregating in the cross.

Standard mapping analysis on a population of suppressed non-fluorescent F2 plants from the mapping cross revealed linkage to a locus on the lower arm of chromosome 2. Fine-structure mapping of this region on a population of 710 plants (1420 chromosomes) narrowed down the mutant locus to an interval containing ~70 predicted open reading frames (ORFs) (Fig. 3).


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Fig. 3.   Positional cloning of the ugt74F2 locus. A region spanned by three bacterial artificial chromosomes covers the minimal genetic interval containing the ugt74F2 locus based on fine-structure analysis of 1420 chromosomes of a mapping population. The markers 56IN-F18O19 (A), 29IN-F6E13 (B), and 28IN-F4I1 (C) detected the indicated number of recombinant chromosomes at each locus in this population. The UGT74F1 and UGT74F2 genes, represented by arrows, are closely located on bacterial artificial chromosome F18O19 (GenBankTM accession number AC002333). These genes are separated by a single predicted ORF encoding the putative protein kinase At2g43830. The brackets indicate the genomic DNA fragments used for transgenic complementation. X and E represent XbaI and EcoRV, respectively.

Within this interval, we focused on two ORFs encoding glucosyltransferases, UGT74F1 and UGT74F2 (1), as candidate genes where loss-of-function mutations could block the accumulation of fluorescent glucose-conjugated anthranilate (Fig. 1). Although the UGT74F1 and UGT74F2 genes encode similar predicted protein products (Fig. 4), we identified UGT74F2 as the more likely candidate, because this gene is represented by cDNAs in the Arabidopsis expressed sequence tag (EST) collection, whereas the UGT74F1 gene is not.


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Fig. 4.   UGT74F2 protein structure. The predicted amino acid sequence of UGT74F2 is shown aligned with the predicted amino acid sequence of its closest Arabidopsis homologue, UGT74F1. Residues highlighted in black are identical. The bracket under the sequence indicates the conserved UDP-glucose binding motif. The position of the single intron in both genes is indicated by an inverted triangle over the sequence. The ten ugt74F2 loss-of-function alleles are indicated above the sequence. An asterisk indicates a stop codon. The x at the acceptor site end of the intron indicates the position of the ugt74F2i1a allele.

We showed that the UGT74F2 gene is in fact the mutant locus with two approaches. First, we cloned and sequenced this gene from the ten mutant isolates, and found a coding sequence G:C to A:T transition mutation in each case. Four of the alleles created premature stop codons, one allele created a splice junction mutation at the acceptor site of the single intron in the gene, and five alleles created missense mutations (Fig. 4). Of the five missense mutations, two affected highly conserved residues in the sugar binding region of the protein sequence. The weak allele that only partially suppressed trp1-100 fluorescence was a missense mutation G64D. To understand the effects of the splice mutation, ugt74F2i1a (intron 1 acceptor), we used reverse transcriptase PCR (RT-PCR) to amplify the UGT74F2 transcript from this mutant. Sequencing of the product revealed that the intron missplices to a new acceptor site just 1 bp downstream of the normal site to yield a product with an incorrect downstream reading frame, causing premature translation termination at codon 220. We also sequenced the neighboring UGT74F1 gene from the ugt74F2i1a splice junction mutant and found that this related gene contained no mutations. Thus, the mutant phenotype was not caused by a combination of lesions in both predicted glucosyltransferase genes.

Second, we found that the cloned UGT74F2 gene introduced on a transgene could complement the ugt74F2 trp1-100 double mutant to restore seedling fluorescence (Fig. 5). Fluorescence was complemented by either a genomic clone carrying UGT74F2 but no other complete ORFs or a cDNA of UGT74F2 driven from the strong constitutive Cauliflower Mosaic Virus 35S promoter (35S-UGT74F2 cDNA). Fluorescence was not complemented by a genomic clone of the related UGT74F1, even in transgenic lines that carried multiple copies of the transgene insert. These results indicate that UGT74F2 is the fluorescence suppressor locus. However, fluorescence was complemented by a 35S-UGT74F1 cDNA construct. This result suggests that the UGT74F1 gene product is capable of catalyzing the same reaction as the UGT74F2 gene product when expressed at sufficiently high levels.


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Fig. 5.   The ugt74F2 mutation can be complemented by genomic UGT74F2, 35S-UGT74F2, and 35S-UGT74F1 but not by genomic UGT74F1. Representative 2-week-old seedlings of trp1-100 ugt74F2i1a transformed with the indicated transgene constructs are shown, under visible light (upper panels) and UV light (lower panels).

Using sequence information for the trp1-100 mutation and the ugt74F2 splice junction mutation, we designed PCR-based strategies to follow both of these lesions through genetic crosses (see "Experimental Procedures"). The markers allowed us to identify progeny plants of a cross between wild type Col and the trp1-100 ugt74F2i1a splice mutant strain that had segregated the homozygous ugt74F2i1a mutation into an otherwise wild type background. These ugt74F2 mutant plants had no obvious morphological abnormalities.

Regulation of the UGT74F2 Gene-- To understand the expression patterns of UGT74F2, we carried out RNA gel blot analysis on tissue-specific RNA samples with a UGT74F2 cDNA probe. The expression analysis revealed that, in wild type Col, UGT74F2 was most strongly expressed in seedling tissues with weaker expression in adult leaves (Fig. 6A). The gene was up-regulated by treatment of seedlings with exogenous salicylic acid (SA) or abscisic acid (ABA) and down-regulated by gibberellic acid (Fig. 6B). Treatment with methyl jasmonate, IAA, a cytokinin (6-benzylaminopurine), or the ethylene precursor 1-aminocyclopropane 1-carboxylic acid had little or no effect (Fig. 6B). Therefore, the UGT74F2 gene is transcriptionally responsive to a subset of plant signaling molecules.


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Fig. 6.   Expression analysis of UGT74F2. A, RNA samples prepared from leaves (leaf), flowers and buds (flower), green siliques (silique), or roots (root) of adult wild type Col plants grown in soil, plus 10-day post-germination and aseptically grown whole Col seedlings (seedling), were used for gel blot analysis with a UGT74F2 probe. The ethidium bromide (EtBr)-stained gel is shown as a loading control. B, wild type Col seedlings were grown aseptically on PNS medium under glass plates for 10 days post-germination and then transferred to inducer-supplemented liquid PNS medium for a 6-h induction with aeration before RNA extraction. For each treatment, ~150 seedlings were transferred to 40 ml of liquid medium with the indicated concentration of inducer added: 20 µM methyl jasmonate (MeJa), 20 µM abscisic acid (ABA), 500 µM salicylic acid (SA), 20 µM IAA, 20 µM 6-benzylaminopurine (BAP), 20 µM gibberellic acid A3 (GA), or 20 µM 1-aminocyclopropane 1-carboxylic acid (ACC). The RNA samples were analyzed by gel blot with the UGT74F2 probe, or with a TUB probe as a gel loading control. C, the indicated strains were grown aseptically on agar medium and whole-seedling RNA was prepared at 10 days post-germination. Replicate blots were probed with UGT74F2 or TUB as a gel loading control.

In a panel of seedling RNA samples prepared from ugt74F2 mutant alleles, the splice mutation and two early stop mutations resulted in decreased steady-state message levels and lower molecular weight degradation products for the UGT74F2 transcript (Fig. 6C). This loss of message stability is presumably due to nonsense-mediated decay (27). The remaining stop mutations, which occur nearer the end of the transcript, did not noticeably destabilize the message. There was also no effect on UGT74F2 message levels in either the weak missense allele ugt74F2G64D or a representative strong missense allele ugt74F2T341I. These results suggest that UGT74F2 transcription is not responsive to the product of the UGT74F2-catalyzed reaction.

To determine whether high ectopic expression of UGT74F2 might confer a fluorescent phenotype in wild type plants by channeling anthranilate into the conjugated form, we transformed Col with the 35S-UGT74F2 cDNA construct. None of 17 transformed plants displayed detectable fluorescence, regardless of transgene copy number (data not shown). This result suggests that there is not enough free anthranilate available in a wild type plant for even the overexpressed UGT74F2 enzyme to make a significant amount of conjugated product.

We also tested the expression patterns of the related gene UGT74F1 using RNA gel blot analysis. The UGT74F1 probe gave no signal in seedling RNA prepared from wild type Col, trp1-100, or trp1-100 ugt74F2 mutants, or from adult tissue RNAs prepared from wild type Col (data not shown). Moreover, the UGT74F1 probe gave no signal in RNA samples prepared from seedlings treated with the same battery of plant signaling molecules shown in Fig. 6B (data not shown). However, we were able to amplify a UGT74F1 cDNA using RT-PCR on template RNA prepared from silique tissue of the trp1-100 ugt74F2 mutant that displayed residual fluorescence. These results suggest that UGT74F1 is expressed but at a lower level than UGT74F2.

Functions of the UGT74F2 and UGT74F1 Proteins-- The simplest explanation for our recovery of ugt74F2 mutations as suppressors of trp1-100 fluorescence is that the UGT74F2 protein is required to catalyze the conjugation of anthranilate into the form that stably accumulates in the trp1-100 mutant (Fig. 1). To test this hypothesis, we showed that the bacterially expressed UGT74F2 protein can indeed catalyze the glucose-conjugation of anthranilate in vitro.

UGT74F2 was expressed and purified as a GST fusion protein in Escherichia coli (Fig. 7A and see "Experimental Procedures"). The purified protein was capable of utilizing anthranilate and UDP-glucose as in vitro substrates to yield a product that co-migrated in thin layer chromatography (TLC) analysis with the fluorescent compound that accumulates in trp1-100 (Fig. 7B). In contrast, GST alone did not generate any detectable product in this assay. Both the in vitro reaction fluorescent product and the fluorescent compound from trp1-100 extracts were isolated from TLC plates and subjected to electrospray ionization-mass spectrometry analysis. This analysis revealed that the two compounds are identical and have a mass of 299, consistent with the structure of anthranilate conjugated to glucose (Fig. 1).


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Fig. 7.   UGT74F2 and UGT74F1 can catalyze a conjugation reaction utilizing UDP-glucose and anthranilate as substrates to form a glucose ester compound. A, a Coomassie Blue-stained gel of preparations of the indicated GST fusion proteins used in enzyme assays is shown. Approximately 0.5 µg of each recombinant protein was loaded in each lane. B, a TLC assay for resolution of free anthranilate from conjugated anthranilate is shown. The TLC plate was photographed under long wave UV light to visualize the fluorescent compounds. Plant extracts were prepared from seedlings at 10 days post-germination as previously described (6). Enzyme assays were performed as described under "Experimental Procedures." O indicates the origin, and F indicates the solvent front. C, the fluorescent conjugate compounds from the in vitro UGT74F2-catalyzed reaction, or from the in vitro UGT74F1-catalyzed reaction, were purified by isolation from TLC plates and subjected to the indicated treatments, and the reaction products were resolved by TLC to determine whether the conjugate was cleaved or uncleaved. See "Experimental Procedures" for conjugate treatment details.

The fluorescent conjugated compound that accumulates in the trp1-1 mutant and a maize tryptophan mutant Bf-1 was previously characterized as an "anthranilate beta -glucoside," because it is cleaved by treatment with beta -glucosidase (6, 28). However, this compound is more properly described as an anthranilate glucose ester (Fig. 1). To confirm the nature of the chemical linkage between anthranilate and glucose, we treated the fluorescent compound isolated from trp1-100 plants or from the in vitro reaction catalyzed by UGT74F2 with beta -glucosidase, alpha -glucosidase, or base (NaOH) (Fig. 7C and data not shown). As previously reported (6), the compound was labile to beta -glucosidase treatment but stable to alpha -glucosidase treatment. These enzymatic assays indicate that anthranilate is conjugated to glucose through a beta  linkage. The compound was also labile to base treatment, diagnostic of the glucose ester linkage (3).

To understand the nature of the fluorescent compound that accumulates in the siliques of the otherwise non-fluorescent trp1-100 ugt74F2 plants, we subjected plant extracts made from these siliques to TLC analysis and found that the predominant fluorescent compound corresponded to the glucose ester form of anthranilate (data not shown). This result indicated that there is a residual conjugating activity present in trp1-100 ugt74F2 mutants. Because UGT74F1 is highly related to UGT74F2 (Fig. 4) and was capable of complementing the ugt74F2 mutant when overexpressed (Fig. 5), this enzyme was a likely candidate for the source of a secondary activity. We expressed UGT74F1 as a GST fusion in E. coli and assayed the enzyme in vitro under the same conditions used for UGT74F2 (Fig. 7). As for UGT74F2, UGT74F1 could use anthranilate and UDP-glucose as substrates to form the glucose ester conjugate. Given the similar in vitro activities of UGT74F1 and UGT74F2, we presume that only ugt74F2 mutations were isolated in the trp1-100 suppressor screen, because UGT74F2 is expressed at a higher level than UGT74F1 and is therefore predominantly responsible for anthranilate conjugation in the plant.

Both UGT74F1 and UGT74F2 displayed similar specific activities toward anthranilate (Table I). These values were within 2-fold of specific activities previously determined for both enzymes toward benzoic acid and for UGT74F1 toward salicylic acid (4). However, the specific activity of UGT74F2 toward anthranilate was ~10-fold higher than that previously determined toward salicylic acid (4).

                              
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Table I
UGT74F1 and UGT74F2 kinetic parameters
The Michaelis-Menten kinetic parameters for UGT74F1 and UGT74F2 were evaluated over a range of 0-3 mM anthranilate concentration, and the specific activity was evaluated at 1 mM anthranilate. Enzyme assays were performed with 1 µg of purified protein, 0-3 mM of anthranilate, 14 mM 2-mercaptoethanol, and 5 mM UDP-glucose in 50 mM Tris-HCl, pH 7.0, buffer. Reactions were incubated at 20 °C before stopping by addition of 20 µl of 240 mg/ml trichloroacetic acid, and quick-frozen before reverse-phase HPLC analysis. Reaction products were analyzed as described under "Experimental Procedures." Km and kcat/Km values were derived from Lineweaver-Burk plots.

Michaelis-Menten kinetic analysis of both enzymes revealed that UGT74F2 has at least 10-fold higher affinity toward anthranilate than UGT74F1 (Table I). In fact, for measurements of UGT74F2 enzyme kinetics we approached the lower detection limit of our HPLC system, so we were able to place only an upper limit on the value of Km (see "Experimental Procedures"). The estimate of kcat/Km lower limit value shows UGT74F2 to be a better enzyme than UGT74F1 for glucose conjugation of anthranilate. The Km of UGT74F2 for anthranilate is similar to that previously determined for benzoic acid, but kcat/Km is almost 5-fold higher (4), suggesting that anthranilate is a preferred substrate.

    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The blue fluorescent phenotype of plants with defects in tryptophan pathway enzymes is a useful reporter for the flux of tryptophan metabolites and the regulation of tryptophan pathway genes. The phenotype occurs due to the accumulation of the first compound in the tryptophan pathway, anthranilate, predominantly in a sugar-conjugated form. Here we describe the isolation of ugt74F2 loss-of-function mutants that block the accumulation of sugar-conjugated anthranilate (Fig. 7B) and block the blue fluorescence of the trp1-100 tryptophan mutant (Fig. 2). Consistent with the mutant phenotypes, the purified UGT74F2 enzyme is able to catalyze a conjugation reaction using UDP-glucose and anthranilate as substrates to form a glucose ester compound (Fig. 7B).

Both conjugated and free anthranilate are blue fluorescent (Fig. 7B). However, loss of UGT74F2 function blocks the fluorescence of the trp1-100 mutant (Fig. 2), and there is no detectable free anthranilate in trp1-100 ugt74F2 double-mutant seedling extracts (Fig. 7B). These findings imply that free anthranilate does not accumulate to the same steady-state levels as the conjugated form, presumably because it is metabolized into non-fluorescent compounds. Thus, the UGT74F2 gene product might serve a specialized role of stabilizing free anthranilate when it accumulates in excess of the amounts found during normal flux of tryptophan biosynthesis. This stabilization could occur by rendering anthranilate non-reactive and/or by efficient localization of the conjugated form to a particular sub-cellular compartment. Although we do not know the metabolic fate of excess free anthranilate, this metabolism could potentially have deleterious consequences for the plant unless controlled by UGT74F2-mediated glucose conjugation.

Arabidopsis tryptophan biosynthetic enzymes carry predicted amino-terminal chloroplast-targeting sequences and have been shown to be imported and processed by isolated chloroplasts (29). The bulk of tryptophan biosynthesis is therefore thought to occur in the chloroplast, with subsequent transport of metabolites to other cellular compartments. The subcellular localization of UGT74F2 remains to be determined, but the protein lacks an amino-terminal extension with sequences diagnostic of chloroplast targeting. Thus, the UGT74F2 enzyme might be spatially separated from the site of anthranilate and tryptophan biosynthesis in the cell. In this scenario, only when anthranilate escapes from the chloroplast would it become available as a substrate for UGT74F2. Consistent with this model, overexpression of UGT74F2 is not sufficient to confer a fluorescent phenotype in wild type plants.

The UGT74F1-predicted protein is very similar to UGT74F2 (76% amino acid identity, Fig. 4), and both bacterially expressed enzymes can catalyze the glucose ester conjugation of anthranilate in vitro (Fig. 7). Furthermore, when UGT74F1 is overexpressed from a strong viral promoter rather than its own expression sequences, it can complement the ugt74F2 defect (Fig. 5). We presumably recovered mutations only in the UGT74F2 gene as suppressors of trp1-100 seedling fluorescence, because this gene is more abundantly expressed than UGT74F1 in seedling tissues (Fig. 6A and data not shown). However, it is likely that UGT74F1 is the source of residual anthranilate-conjugating activity in the siliques of trp1-100 ugt74F2 mutant plants where a low level of fluorescent-conjugated product still accumulates. It should therefore be possible to isolate ugt74F1 mutations as suppressors of the residual silique fluorescence. Such a suppressor screen would be the most facile means of generating a ugt74F1 ugt74F2 double mutant, because these genes lie only 4 kb apart (Fig. 3) and would be difficult to recombine from single-mutant parents.

UGT74F1 and UGT74F2 were previously tested as part of a battery of ninety Arabidopsis glucosyltransferases for activity against benzoic acid and hydroxybenzoic acid compounds in vitro (4). Both enzymes, along with UGT75B1, displayed glucose ester conjugation activity against benzoic acid and 3-hydroxybenzoic acid. In addition, UGT74F1 and UGT74F2 uniquely displayed conjugating activity against SA, which is an important signaling molecule during plant pathogen defense responses (30). The levels of SA, both in the free and conjugated forms, rise in response to pathogen attack. The physiological consequences of sugar conjugation on the SA moiety are not known, but it has been proposed that this conjugation may serve as a detoxifying mechanism for the rapidly rising SA levels (31). Interestingly, UGT74F1 specifically formed the O-glucoside conjugate to the 2-hydroxy group of SA (4). UGT74F2 had lower activity toward SA and preferentially formed the glucose ester conjugate. This difference for in vitro activities advocates that UGT74F1 may be the predominant SA conjugating activity in vivo.

Given that UGT74F1 and UGT74F2 have both been implicated in conjugation of SA and benzoic acid, it is possible that these enzymes only utilize anthranilate as a substrate under exceptional conditions, such as the metabolic blocks found in some tryptophan pathway mutants, where anthranilate accumulates to high enough levels to become an effective substrate for sugar conjugation. However, in the case of UGT74F2, the high activity of the enzyme toward anthranilate (Table I) suggests that it might have evolved to specifically discriminate this compound as a preferred substrate. Our work, together with previous results (4), indicates that UGT74F1 and UGT74F2 have partially overlapping profiles of benzoate compound substrates and therefore are likely to be partially redundant in the plant, with the specific contributions of each enzyme determined by its intrinsic activity and its expression profile in response to a particular substrate.

    ACKNOWLEDGEMENTS

We thank Gromoslaw Smolen, Julie Blum, and Diane Grove for technical assistance; Dr. Paul Miller for use of HPLC equipment; Dr. Cecile Pickart for helpful discussions; and the Arabidopsis Biological Resource Center for providing EST clones of UGT74F2. We also thank Dr. Brian Keith for the gift of four ugt74F2 mutants isolated previously.

    FOOTNOTES

* This work was supported by National Science Foundation Grant IBN 9723172 (to J. B.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EBI Data Bank with accession number(s) AF498914.

Dagger Current address: Laboratory of Immunology, NIAID, National Institutes of Health, Bldg. 10, Rm. 11N311, 10 Center Dr., MSC 1892, Bethesda MD 20892-1892.

§ To whom correspondence should be addressed: Dept. of Biochemistry and Molecular Biology, the Bloomberg School of Public Health, The Johns Hopkins University, 615 N. Wolfe St., Baltimore, MD 21205. Tel.: 410-614-1595; Fax: 410-955-2926; E-mail: jbender@mail.jhmi.edu.

Published, JBC Papers in Press, December 9, 2002, DOI 10.1074/jbc.M211822200

    ABBREVIATIONS

The abbreviations used are: UGT, UDP-glucosyltransferase; IAA, indole-3-acetic acid; Col, Columbia; WS, Wassilewskija; EST, expressed sequence tag; RT, reverse transcriptase; TUB, beta -tubulin-4; GST, glutathione S-transferase; HPLC, high-performance liquid chromatography; ORF, open reading frame; SA, salicylic acid; ABA, abscisic acid.

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

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