Two Biosynthetic Pathways for Aromatic Amino Acids in the Archaeon Methanococcus maripaludis

Methanococcus maripaludis is a strictly anaerobic, methane-producingarchaeon. Aromatic amino acids (AroAAs) are biosynthesized inthis autotroph either by the de novo pathway, with chorismateas an intermediate, or by the incorporation of exogenous arylacids via indolepyruvate oxidoreductase (IOR). In order to evaluatethe roles of these pathways, the gene that encodes the thirdstep in the de novo pathway, 3-dehydroquinate dehydratase (DHQ),was deleted. This mutant required all three AroAAs for growth,and no DHQ activity was detectible in cell extracts, comparedto 6.0 ± 0.2 mU mg^–1 in the wild-type extract.The growth requirement for the AroAAs could be fulfilled bythe corresponding aryl acids phenylacetate, indoleacetate, andp-hydroxyphenylacetate. The specific incorporation of phenylacetateinto phenylalanine by the IOR pathway was demonstrated in vivoby labeling with [1-¹³C]phenylacetate. M. maripaludis has twoIOR homologs. A deletion mutant for one of these homologs contained76, 74, and 42% lower activity for phenylpyruvate, p-hydoxyphenylpyruvate,and indolepyruvate oxidation, respectively, than the wild type.Growth of this mutant in minimal medium was inhibited by thearyl acids, but the AroAAs partially restored growth. Geneticcomplementation of the IOR mutant also restored much of thewild-type phenotype. Thus, aryl acids appear to regulate theexpression or activity of the de novo pathway. The aryl acidsdid not significantly inhibit the activity of the biosyntheticenzymes chorismate mutase, prephenate dehydratase, and prephenatedehydrogenase in cell extracts, so the inhibition of growthwas probably not due to an effect on these enzymes.

INTRODUCTION

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Introduction

Methanococcus maripaludis is a strictly anaerobic, methane-producingarchaeon. It is a mesophile that utilizes CO₂ as the sole carbonsource during autotrophic growth in minimal medium but assimilatesacetate and some amino acids as carbon sources when they arepresent (28, 46, 47, 66). Regardless of the carbon source, thereduction of carbon dioxide to methane by H₂ or formate is arequired energy source for the growth of these obligate lithotrophs.

Several lines of evidence suggest that the aromatic amino acids(AroAAs) can be biosynthesized by the de novo pathway in methanogensand other archaea (for a review, see reference 67). The de novopathway starts from the common pathway leading to chorismateand then splits to biosynthesize tryptophan, tyrosine, or phenylalanine(Fig. 1). This pathway is sufficient to explain the patternof isotope incorporation in the AroAAs in many methanogens (11,12, 53). Bioinformatic analyses of genomic sequences furtherdemonstrate homologs for the genes for the de novo pathway inmany archaea (44, 52, 67). However, homologs have not been foundfor the first two steps in the methanogens, which may utilizedifferent precursors (60). A few enzymes in the pathway havealso been biochemically characterized. In the common pathway,only shikimate kinase from Methanocaldococcus jannaschii hasbeen characterized in archaea (9). From chorismate to tyrosineand phenylalanine, chorismate mutase (CM) from M. jannaschii,prephenate dehydratase (PDT) from Halobacterium vallismortis,and aromatic aminotransferases (AroAT) from Methanococcus aeolicusand Pyrococcus furiosus have been characterized (27, 34, 62,69). Most of the enzymes for the biosynthesis of tryptophanfrom chorismate have been characterized in archaea, includingsome Methanococcus species (14, 24, 29, 38, 48, 55, 61).

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FIG. 1. Pathways for the biosynthesis of AroAAs in M. maripaludis. The precursors for the de novo pathway in methanogens are not known, but homologs for genes at all the steps after 3-dehydroquinate are present in the genomic sequence (see the text). After chorismate, the pathway splits into three branches, one of which leads to tryptophan. At prephenate, the branches leading to phenylalanine and tyrosine form. The aryl acid pathway starts from phenylacetate, p-hydroxyphenylacetate, and indoleacetate, precursors for phenylalanine, tyrosine, and tryptophan, respectively. The enzymes shown are DHQ, CM, PDT, PDH, AroAT, and IOR. Possible transcriptional regulation of DHQ is indicated by double dashed lines. Inhibition (–) or activation (+) of the PDT and PDH enzyme activities are indicated by single dashed lines.

In addition to the de novo pathway, Methanothermobacter marburgensishas been proposed to form the AroAAs from the correspondingaryl acids (56). In this pathway, the aryl acids are activatedto the coenzyme A (CoA) thioesters indoleacetyl-CoA, phenylacetyl-CoA,and p-hydroxyphenylacetyl-CoA, which are then reductively carboxylatedby indolepyruvate oxidoreductase (IOR) to indolepyruvate, phenylpyruvateor p-hydroxyphenylpyruvate, respectively (Fig. 1). These compoundsare substrates for the AroAA aminotransferases (69). The presenceof this pathway in M. marburgensis is supported by characterizationof the key enzyme IOR and incorporation of radiolabeled phenylacetateinto phenylalanine (56). In contrast, a similar pathway in thehyperthermophilic peptide-fermenting archaeon P. furiosus isinvolved in AroAA degradation to aryl acids (36). Thus, thepresence of the enzymes of this pathway is not proof of itsphysiological function.

The present work provides genetic and biochemical evidence forboth of these pathways for AroAA biosynthesis in M. maripaludis.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains, plasmids, media, and culture conditions. The bacterial strains and plasmids used in this work are listedin Table 1. Escherichia coli was grown in Luria-Bertani mediumwith ampicillin (100 µg/ml) when needed. M. maripaludiswas grown with 276 kPa of H₂-CO₂ gas (80:20 [vol/vol]) at 37°Cin the mineral medium McN, McNA (McN plus 10 mM sodium acetate),or McC (McNA plus 0.2% [wt/vol] Casamino Acids and 0.2% [wt/vol]yeast extract) as described previously (65). Puromycin (2.5µg/ml) or neomycin (500 µg/ml) was added when needed.Under these growth conditions, logarithmic growth is observedonly at low cell densities because the rate of transfer of H₂gas to the liquid medium limits the rate of growth at even moderatecell densities. For this reason, only linear growth curves arepresented. For preparation of the cell extracts, M. maripaludiswas grown in bottles with 100 ml of McNA medium and 138 kPaof H₂-CO₂ gas (80:20 [vol/vol]) at 37°C. The cells wereharvested, and the cell extract was prepared as previously described(33, 47).

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TABLE 1. Bacterial strains and plasmids

Construction of mutants. The ${Delta}$ aroD::pac and ${Delta}$ iorA2::pac mutants were made by transformationwith suicide vectors based upon pIJA03. Upon transformationand selection, these vectors exchange the internal portion ofthe aroD or iorA2 gene with the pac cassette, which encodespuromycin resistance in methanococci (15, 54). In pIJA03, thepac cassette is flanked by two multicloning regions that allowdirected cloning of genomic DNA. The upstream and downstreamregions of the aroD gene were PCR amplified from genomic DNAusing the primers U1-U2 and D1-D2, respectively. pIJA03-aroDwas constructed in E. coli DH5 ${alpha}$ (19) by cloning the U1-U2 PCRproducts into the BglII-XbaI sites and the D1-D2 products intothe KpnI and NheI sites of pIJA03. Similarly, the plasmid pIJA03-iorA2was constructed using the primers U3-U4 and D3-D4. Upon insertioninto the genome, this plasmid would be expected to delete the3' end of iorA2, as well as the first codon of iorB2. The pIJA03-aroDor pIJA03-iorA2 plasmid was transformed into M. maripaludisS2 by the polyethylene glycol method (59). After transformation,cultures were plated on McC medium plus puromycin, random puromycin-resistantcolonies were restreaked, and representative isolates were pickedinto tubes containing broth of the same composition. After growth,2.5 ml of the 5-ml culture was used for determination of thegenotype and phenotype. The remaining culture was used for preparationof frozen stocks. First, the culture tube was transferred toan anaerobic glove box, and the remaining culture was centrifugedand resuspended in 0.4 ml of 30% glycerol plus McC medium (58).The suspension was distributed into 0.2-ml fractions, sealedin airtight cryogenic vials (Corning), and stored at –70°C.

The plasmid pMEV2-iorAB2 for complementation of the IOR mutantwas constructed by cloning the iorAB2 genes into the NsiI andXbaI sites of the methanococcal expression vector pMEV2 (32).The iorAB2 genes were PCR amplified from genomic DNA using theprimers E1 and E2. The plasmid pMEV2-iorAB2 was constructedin E. coli DH5 ${alpha}$ (19) and transformed into M. maripaludis S122(59). Transformants were screened on McC plates containing neomycin.Isolated colonies were restreaked and stored as described above.All subcultures of this strain also contained neomycin.

The sequences of the primers used in this work will be providedupon request.

Southern hybridization. Southern hybridizations were performed using the DIG High PrimeDNA Labeling and Detection Starter Kit I (Roche, Mannheim, Germany).The probe for aroD was made by PCR amplification with primersU1 and U2. The probe for the iorA2 gene was made by PCR amplificationusing primers U3 and U4.

Enzymatic assays. The activity of 3-dehydroquinate dehydratase (DHQ) was assayedby monitoring the formation of 3-dehydroshikimate at 234 nm( ${varepsilon}$ = 12 x 10³ M^–1 cm^–1) at 37°C. The standardassay mixture (1 ml) contained potassium-PIPES [piperazine-N,N'-bis(2-ethanesulfonicacid)] buffer (50 mM; pH 7.0) and 10 mM 3-dehydroquinate (6).Dehydroquinate was prepared by the oxidation of quinic acid(Sigma, St. Louis, Mo.) with nitric acid and separation of theproducts by ion-exchange chromatography on Dowex 1 (Sigma) resin(17). The fractions that contained dehydroquinate were collected,and the dehydroquinate was precipitated as previously described(22).

Pyruvate oxidoreductase (POR) activity was assayed anaerobicallyas pyruvate- and CoA-dependent methyl viologen reduction, aspreviously reported (33). IOR activity was assayed similarly,except that pyruvate was replaced with phenylpyruvate (1 mM),indolepyruvate (0.5 mM), or p-hydroxyphenylpyruvate (1 mM) asthe substrate of the reaction. Stock solutions of the last twosubstrates were prepared in ethanol. An ethanol-only controlhad no activity.

CM activity was assayed by measuring the transformation of chorismateto prephenate after the chemical conversion of prephenate tophenylpyruvate in acid (1). Unless otherwise stated, the concentrationof chorismate was 1 mM. PDT was assayed by measuring the conversionof prephenate to phenylpyruvate as previously described (16),except that the enzymatic reaction was performed for 10 minwith 0.5 mM prephenate. For the kinetics experiments for PDT,the concentrations of KCl, phenylalanine, and tyrosine were725, 0.1, and 0.1 mM, respectively. Prephenate dehydrogenase(PDH) activity was assayed by following the formation of NADHupon the oxidative decarboxylation of prephenate (10). The concentrationof prephenate was 1 mM.

All specific activities are given in milliunits per milligram(or nanomoles per minute per milligram of protein). Proteinconcentrations were determined using the bicinchoninic acidprotein assay kit (Pierce, Rockford, Ill.) after incubationat 90°C in 0.1 M NaOH for 30 min.

¹³C labeling and isolation of amino acids from M. maripaludis proteins. The AroAA auxotroph S87 was grown in 6.5 liters of modifiedMcNA medium in H₂-CO₂ gas as previously described (46). In additionto the usual components, the McNA medium contained 0.1 mM [1-¹³C]phenylacetateand p-hydroxyphenylacetate and 0.02 mM indoleacetate. The arylacids were flushed with N₂ gas and sterilized by filtration.The fermentor was inoculated with 400 ml of culture grown inthe same medium with unlabeled phenylacetate. The cells wereharvested by centrifugation as previously described (46). Theproteins from the cell pellets were extracted as described previously(64), except that the cell paste (8.2 g [wet weight]) was suspendedin 326 ml of ice-cold 5% (wt/vol) trichloroacetic acid and theprotein pellet was washed twice with acetone before being driedin a vacuum desiccator. For acid hydrolysis, the dried proteinswere suspended in 6 N HCl (40 µl/mg of dry protein) inan acid-cleaned, anaerobic glass culture tube (51). The tubewas sealed with a butyl rubber stopper and aluminum seal, andthe solution was frozen in an ethanol-dry ice bath. The tubewas flushed with N₂ gas for 15 min and incubated in a sand bathat 110°C for 20 h. Then, the acid was diluted with an equalvolume of water. Rotary evaporation was used for removing theacid, and the amino acid mixture was concentrated to 0.5 mlby lyophilization. The concentrated mixture of amino acids wasthen diluted to 1.5 ml in water, and multivalent cations wereremoved during passage through a 3-ml column of iminodiaceticacid chelating resin (Sigma). The column was treated with 500ml of 1 N HCl and 500 ml of water before the sample was loaded.After the sample was loaded, the column was eluted with distilledwater. The amino acids were detected by spotting drops fromthe column on filter paper. After the drops dried, a drop ofninhydrin reagent (100 ml of butanol, 3 ml of acetic acid, and0.3 g of ninhydrin) was added and dried. The formation of anorange color indicated the presence of amino acids. The aminoacids eluted within 13 ml and were taken to dryness by lyophilization.

NMR experiment. ¹H-decoupled ¹³C nuclear magnetic resonance (NMR) data wereacquired at 20°C on a 400-MHz spectrometer (399.8 MHz; ¹H),while ¹H detected spectra were recorded on a 500-MHz spectrometer(499.8 MHz; ¹H). ¹H chemical shifts at 20°C were referencedto 2,2-dimethyl-2-silapentane-5-sulfonic acid via the HDO resonancefrequency at 4.76 ppm, and ¹³C chemical shifts were referencedto tetramethylsilane at 0.0 ppm. All 2D phase-sensitive gradient-enhancedand 1D version ¹H-¹³C HMQC-clean-TOCSY (HMQC, heteronuclearmultiquantum coherence; TOCSY, total correlation spectroscopy)(31) experiments were acquired with GARP decoupling (45) duringacquisition. For all 2D experiments, quadrature detection inthe indirectly observed dimensions was obtained using the time-proportionalphase increment method (37). The 2D data were acquired withan acquisition time of 100 ms, with four scans for each of 256free induction decays. The 1D HMQC-clean-TOCSY data were recordedwith 64 scans.

Phylogenetic analysis. The genes encoding the ${alpha}$ subunits of the two IORs from M. maripaludiswere used for a BLASTP search of the National Center for BiotechnologyInformation (National Institutes of Health) database. The aminoacid sequences were aligned using Clustal X (57). This alignmentwas manually edited prior to construction of the phylogenetictrees with PHYLIP (13). Evolutionary distances were determinedwith PROTDIST, and the neighbor-joining and Fitch-Margoliashdendrograms were generated with NEIGHBOR and FITCH, respectively.Parsimony analysis was performed with PROTPARS. The SEQBOOTprogram was used to calculate bootstrap values based upon 100replicate trees.

RESULTS

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Results

Biosynthesis of AroAAs by the de novo pathway. The genome of M. maripaludis possesses homologs for five ofthe seven genes of the de novo pathway of AroAA biosynthesisup to chorismate (J. Leigh, personal communication). The ORFMMP1394 is the homolog to aroD, which encodes the third enzymein the pathway, DHQ. This is the first step for which a homologhas been identified. MMP1394 shows $~$ 30% amino acid identity tothe bacterial type I DHQs. Because there is no direct biochemicalevidence for the identity of aroD in the archaea, a deletionstrain of MMP1394 was constructed to confirm its role in AroAAbiosynthesis (Fig. 2A). The genotypes of the resulting mutants,S83 and S87, were confirmed by Southern blotting. The replacementof an internal portion of MMP1394 with the pac cassette resultedin an increase in size of the BglII fragment from 4.2 kb inthe wild type to 5.1 kb in the mutants (Fig. 2B). The mutantswere auxotrophic for all three AroAAs (Fig. 3A and data notshown). In cell extracts of the mutant S87, the DHQ activitywas below the limit of detection, or <0.5 mU mg^–1.In contrast, the specific activity in the wild-type strain was6.0 ± 0.2 mU mg^–1. These results confirmed theidentity of MMP1394 as aroD and its role in the pathway of AroAAbiosynthesis.

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FIG. 2. Construction of the ${Delta}$ aroD::pac mutation. (A) M. maripaludis aroD (MMP1394) gene region. The ORFs MMP1396, MMP1395 and MMP1391 were annotated as aminotransferase, DEAD/DEAH box helicase and aspartate-semialdehyde dehydrogenase, respectively. The ORFs MMP1393 and MMP1392 were annotated as hypothetical proteins (J. Leigh, personal communication). The locations of the primers U1, U2, D1, and D2 used to clone the upstream and downstream regions flanking MMP1394 are shown. (B) Confirmation of the genotypes of the wild-type S2 and mutants S83 and S87 by Southern hybridization. The genomic DNA (3.2 µg) was digested with BglII prior to hybridization with the probe indicated in panel A. Lanes 1, 2, and 3, genomic DNAs of S2, S83, and S87, respectively, digested with BglII. Lane 4, pJA03-aroD digested with PvuII and NheI as a positive control.

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FIG. 3. Growth requirement of the auxotroph S87 for AroAAs. The McNA medium contained 1 mM AroAAs or aryl acids, except when otherwise indicated. (A) Growth in the presence of AroAAs or aryl acids. The inoculum was 10⁵ cells. Shown are growth of the wild-type S2 with or without acids ( ${lozenge}$ ) and growth of S87 with all three aryl acids ( ${blacktriangleup}$ ), with all three AroAAs ( ${square}$ ), and without any addition (•). (B) Assimilation of phenylalanine and tyrosine limit the growth rate of the mutant S87. The inoculum was 10⁷ cells washed in McNA medium. Shown are growth of S87 without any addition (•); with all three aryl acids ( ${blacktriangleup}$ ); with phenylalanine, indoleacetate, and p-hydroxyphenylacetate ( ${blacksquare}$ ); with tyrosine, indoleacetate, and phenylacetate ( ${blacklozenge}$ ); with indoleacetate and p-hydroxyphenylacetate alone ( ${square}$ ); and with indoleacetate and phenylacetate alone ( ${lozenge}$ ). (C) Growth yield of the mutant S87 with limiting concentrations of indoleacetate ( ${blacksquare}$ ), p-hydroxyphenyacetate ( ${blacktriangleup}$ ), and phenylacetate (•). The inoculum was 10⁷ cells washed in McNA medium.

Biosynthesis of AroAAs from the aryl acids. The three aryl acids, phenylacetate, p-hydroxyphenylacetate,and indoleacetate, fulfilled the AroAA requirement for growthof the aroD mutant S87 (Fig. 3A). These results suggested thatM. maripaludis was also able to biosynthesize the AroAAs fromthe aryl acids using the IOR pathway.

Aryl acids are readily available in typical methanogenic environments,where they are formed from the AroAAs by anaerobic heterotrophs(3, 4). In contrast, strains of M. maripaludis poorly assimilatelow concentrations of the AroAAs themselves, as well many otheramino acids (66). The rapid growth of the auxotroph with arylacids suggested that these acids might be assimilated at environmentallyrelevant concentrations (Fig. 3A). In fact, replacement of phenylacetateand p-hydroxyphenylacetate with phenylalanine and tyrosine,respectively, actually inhibited growth, confirming that thearyl acids were assimilated more readily than the amino acids(Fig. 3B). The aryl acids were assimilated quantitatively. Forinstance, the concentrations of indoleacetate, phenylacetate,and p-hydroxyphenylacetate required for growth of S87 were closeto the values expected from the abundance of the AroAAs in proteins(Fig. 3C). The cellular yields for phenylacetate, p-hydroxyphenylacetate,and indoleacetate were 3.7, 4.2, and 23 g (dry weight) mmol^–1,respectively. From the compositions of AroAAs in E. coli, theexpected yields were very similar: 5.7, 7.6, and 19 g (dry weight)mmol^–1 (39). These results demonstrated that low concentrationsof aryl acids could fulfill the growth requirement for AroAAs.

In bacteria, chorismate is an intermediate in the biosynthesisof p-aminobenzoate, quinones, and the catechol siderophores(5). Although methanogens are not known to possess the lasttwo compounds, p-aminobenzoate is required for methanopterinbiosynthesis in Methanobrevibacter sp. (63). Although labelingof p-aminobenzoate was consistent with its formation from chorismate,this biosynthetic route was not demonstrated conclusively. Therefore,it was interesting that aryl acids alone were sufficient tosupport growth of the ${Delta}$ aroD::pac mutant. To confirm that no othercompounds were required for growth, this mutant was seriallytransferred five times in minimal medium with acetate and arylacids, for a total dilution of $~$ 10⁸-fold. After five transfers,the growth of the mutant closely resembled that of the wildtype in this medium (data not shown). From this result, methanococcimust have an alternative pathway of p-aminobenzoate biosynthesisduring growth on aryl acids. It is also possible that chorismateis an intermediate during growth without these AroAA precursors.

In vivo incorporation of phenylacetate into phenylalanine. To confirm the incorporation of aryl acids into the AroAAs,the mutant S87 was cultured with [1-¹³C]phenylacetate, unlabeledp-hydroxyphenylacetate, and indoleacetate. After extractionof the cellular proteins and acid hydrolysis to produce a mixtureof amino acids, only one amino acid carbon was specificallyenriched by the ¹³C label (Fig. 4A). This carbon was identifiedas the C of phenylalanine based in part upon its ¹³C chemicalshift in a ¹H-decoupled ¹³C experiment. However, this criterionalone was not sufficient, and the identification was confirmedby the ¹H and ¹H_ß resonances obtained in ¹H-¹³C HMQC-TOCSYexperiments of the mixture and those of amino acid standardsprepared at the same pH. The observed ¹H chemical shifts inthe mixture were 4.29 ppm for the ¹H proton and 3.34 and 3.20ppm for the ¹H_ß protons (Fig. 4B). These matched theresonances of the phenylalanine standard observed at 4.25 ppmfor the ¹H proton and 3.33 and 3.18 ppm for the ¹H_ßprotons. In contrast, the ¹H chemical shifts of other candidatestandards had significant deviations from that observed forthe mixture. For example, tryptophan had the closest chemicalshifts and resonances for the ¹H proton at 4.24 ppm and the¹H_ß protons at 3.49 and 3.37 ppm.

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FIG. 4. NMR spectra of the mixture of amino acids produced by acid hydrolysis of labeled proteins. The amino acids (10 mg) were isolated by Robert's method from S87 cells grown in the presence of 0.1 mM [1-¹³C]phenylacetate. (A) ¹³C spectrum of the mixture of amino acids produced by acid hydrolysis of the labeled proteins. (B) Proton spectrum of the ¹³C-labeled amino acids demonstrating coupling to ¹³C.

IOR from M. maripaludis. The IORs from M. marburgensis and Pyrococcus spp. have beenpurified and found to contain two subunits (35, 49, 50, 56).Two homologs of the IORs are present in the genomes of M. maripaludis(J. Leigh, personal communication), each one encoded by adjacentORFs: MMP0316 and MMP0315, and MMP0713 and MMP0714 for the ${alpha}$ and ß subunits, respectively. A phylogenetic treeof the ${alpha}$ subunits from the prokaryotes grouped the IOR homologsinto six clades (Fig. 5). While all six clades were observedby the Fitch-Margoliash, neighbor-joining, and parsimony algorithms,only some were strongly supported by bootstrap analyses. Moreover,it was not possible to confidently assign the genes from Chlorobiumtepidum, Bacteroides thetaiotaomicron, and homolog 1 of Geobactermetallireducens to a clade or to determine the deep branchingorder among the clades (Fig. 5). Four clades (A to D) containedonly archaeal genes, and two clades (E and F) contained bacterialand archaeal sequences. The biochemically characterized IORsfrom Pyrococcus spp. and M. marburgensis, which is closely relatedto Methanothermobacter thermoautotrophicus (56), were all inclade D, which included only archaeal genes but not the methanococcalhomologs. Instead the M. maripaludis homologs were found inclades A and F, along with the homologs from the closely relatedmesophile Methanococcus voltae (W. B. Whitman, R. A. Feldman,and R. Overbeek, unpublished observation). Clade A was composedentirely of archaeal genes. In addition to the methanococcalhomologs, it also included homolog 1 of Methanosarcina spp.In contrast, the methanococcal homologs were the only archaealgenes in clade F, which also contained genes from a varietyof facultative and strictly anaerobic bacteria. Because of thelow similarity of the methanococcal homologs to the biochemicallycharacterized enzymes and the broad distribution among differenttypes of prokaryotes, it was not possible to infer the physiologicalproperties of the IOR homologs from this phylogeny.

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FIG. 5. Phylogeny of the iorA genes that encode the ${alpha}$ subunit of IOR. The phylogenetic tree was constructed by using the PHYLIP package based upon an alignment of conserved positions using the Fitch-Margoliash algorithm. Similar phylogenetic trees were generated by neighbor-joining and parsimony algorithms (data not shown). The bootstrap values for all three algorithms were very close and are labeled in the tree by the symbols at the branch points: •, values of >90%; ${circ}$ , values of >60%; unlabeled, values of $≤$ 60%. The scale bar is 0.5 expected amino acid substitutions per site. The six clades found are labeled A to F. The accession numbers for protein sequences from the National Center for Biotechnology Information database (from top to bottom in the tree) are: AAM05134, AAM32330, CAF29872.1, AAR21228, AAL80969, NP_143041, NP_126757, C90374, BAB65740, BAB59718, CAC12141, Q9UZ57, O58495, AAL80657, BAA20528 [formerly named Pyrococcus sp KOD1(43)], NP_615972, NP_634117, O28783, AAB86318, ZP_00000830, ZP_00001160, ZP_00080126, NP_106112, BAC48676, CAD15531, ZP_00056522, ZP_00129724, AAM32484, AAM05385, NP_661020, AAO75537, ZP_00054515, ZP_00015617, ZP_00010808, ZP_00079304, NP_623747, NP_348620, ZP_00059944, AAR21230, and CAF30269.1.

In order to further understand the role of the IORs in M. maripaludis,the iorA2 (MMP0713) gene was deleted by replacement with thepac cassette (Fig. 6A). The genotype of the resulting mutant,S122, was confirmed by Southern blotting. The replacement ofthe internal portion of MMP0713 with the pac cassette resultedin an increase in size of the EcoRV fragment from 2.4 kb inthe wild type to 3.2 kb in the mutant S122 (Fig. 6B). The IORspecific activity in the mutant was greatly reduced, from 162mU mg^–1 in the wild type to 39 mU mg^–1 with phenylpyruvateas the substrate (Table 2). The genes iorAB2 were then clonednext to a strong promoter in the methanococcal expression vectorpMEV2 (32), and the vector was transformed into the mutant S122to produce strains S151, S153, and S155. The complemented strainsall possessed elevated levels of IOR activity, confirming thatthese genes encoded IOR (Table 2 and data not shown). Interestingly,the specific activity for POR in these complemented strainswas reduced, from 390 mU mg^–1 in the wild type and strainS122 to 180 to 220 mU mg^–1 in the complementation mutants.Presumably, biosynthesis of elevated levels of IOR depletedthe coenzymes needed for biosynthesis of normal levels of POR.Although the methanococcal IORs were not purified, the propertiesof the mutants suggested that the enzymes had different specificitiesfor the aryl acids. Compared to the wild type, extracts of the ${Delta}$ iorA2::pac mutant S122 possessed greatly reduced activity withphenylpyruvate and p-hydroxyphenylpyruvate (Table 2), suggestingthat IOR2 preferentially utilized these substrates. Similarly,complemented strains possessed very high activities for phenylpyruvateand p-hydroxyphenylpyruvate compared to the activity with indolepyruvate(Table 2). Presumably, the residual activity in the mutant S122,which was nearly the same for all three substrates, representedIOR1. Thus, the substrate specificities of IOR1 and IOR2 appearedto differ.

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FIG. 6. Construction of ${Delta}$ iorA2::pac mutation. (A) M. maripaludis iorA2 (MMP0713) gene region. The ORFs MMP0712, MMP715, MMP0716, and MMP0717 were annotated as solute-binding protein/glutamate receptor, coenzyme F390 synthetase II, acetohydroxyacid synthase small-subunit related, and hypothetical protein, respectively (J. Leigh, personal communication). The primers U3, U4, D3 and D4 were used to clone the flanking regions for construction of pIJA03-iorA. The primers E1 and E2 were used for cloning iorA2 and iorB2 during the construction of pMEV2-iorAB2. (B) Confirmation of the genotype by Southern hybridization with the wild-type S2 and the iorA2 mutant S122. The genomic DNA (3.3 µg) was digested with EcoRV prior to hybridization to the probe indicated in panel A. Lanes 1 and 2, S122 and S2 genomic DNAs, respectively; lane 3, pJA03-iorA2 DNA digested with PvuII and NheI as a positive control.

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TABLE 2. Indolepyruvate oxidoreductase specific activities of the wild-type S2 and mutant S122 and S155 strains^a

Regulation of de novo AroAA biosynthesis by aryl acids. The growth of the ${Delta}$ iorA2::pac mutant S122 was indistinguishablefrom that of the wild type in medium with (McC) or without (McNAor McN) amino acids. However, the aryl acids phenylacetate andp-hydroxyphenylacetate, either alone or in combination, severelyinhibited growth of the mutant in minimal medium (Fig. 7A anddata not shown). In some experiments, growth of the ${Delta}$ iorA2::pacmutant resumed after a long lag in the presence of phenylacetateor p-hydroxyphenylacetate (Fig. 7B). Growth in these cases wasbest explained by selection for revertants. Growth was seldomseen when very small inocula were used, suggesting that growthoccurred due to selection for mutants arising spontaneously.Moreover, the aryl acids no longer inhibited the growth of thesecultures upon subsequent transfers in the same medium (datanot shown). The inhibition by the individual aryl acids suggestedthat phenylacetate and p-hydroxyphenylacetate inhibited thede novo pathway of AroAA biosynthesis. The inhibition by allthree aryl acids together further indicated that the level ofIOR activity remaining in the mutant was insufficient to provideAroAAs from the aryl acids.

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FIG. 7. Effects of aryl acids on growth of the ${Delta}$ iorA2::pac mutant S122. The McNA medium contained 1 mM aryl acids or AroAAs as indicated. The inoculum was $~$ 2 x 10⁵ cells. (A) Inhibition of growth of strain S122 by phenylacetate or p-hydroxyphenylacetate. ${lozenge}$ , wild-type S2 without any addition; •, S122 without any addition; ${triangleup}$ , S122 with phenylacetate alone, p-hydroxyphenylacetate alone, both phenylacetate and p-hydroxyphenylacetate, or all three aryl acids. (B) Restoration of growth by AroAAs. Shown are S122 without any addition (•), with phenylacetate ( ${triangleup}$ ), with phenylacetate and phenylalanine ( ${blacktriangleup}$ ), with p-hydroxyphenylacetate ( ${square}$ ), and with p-hydroxyphenylacetate and tyrosine ( ${blacksquare}$ ). (C) Complementation of the ${Delta}$ iorA2::pac mutant with pMEV2-iorAB2. Shown are growth of wild-type S2 without any addition ( ${lozenge}$ ), the complemented strain S155 without any addition (•), S155 with phenylacetate ( ${triangleup}$ ), S155 with p-hydroxyphenylacetate ( ${square}$ ), S155 with phenylacetate and p-hydroxyphenylacetate ( ${circ}$ ), and S155 with the three aryl acids ( ${blacktriangleup}$ ).

In support of these hypotheses, phenylalanine provided partialprotection against inhibition by phenylacetate, indicating thatlimitation for AroAAs caused at least some of the growth inhibition(Fig. 7B). However, tyrosine failed to protect against inhibitionby p-hydroxyphenylacetate. Tyrosine was assimilated poorly byM. maripaludis. For instance, tyrosine supported only poor growthof the ${Delta}$ aroD::pac mutant S87 after a lag of >2 days (Fig.3B). Therefore, the failure of tyrosine to protect against arylacid inhibition probably reflected its poor uptake. In addition,p-hydroxyphenylacetate appeared to be a stronger inhibitor thanphenylacetate (see below), so its effects would be more difficultto reverse upon the addition of the AroAAs. Because phenylacetatewas less inhibitory, phenylalanine could provide partial protection,presumably by sparing the chorismate requirement for biosynthesisof the other AroAAs. In contrast, indoleacetate did not inhibitthe growth of the ${Delta}$ iorA2::pac mutant (data not shown). Presumably,it was either not a strong inhibitor of AroAA biosynthesis orthe levels of IOR activity were sufficient for tryptophan biosynthesis.

In strain S155, where the chromosomal ${Delta}$ iorA2::pac mutation wascomplemented by iorAB2 expression from a plasmid, the relativegrowth inhibition by the aryl acids was greatly reduced. First,p-hydroxyphenylacetate or phenylacetate alone was still inhibitory,as expected if they inhibited the de novo pathway. However,phenylacetate and p-hydroxyphenylacetate together or all threearyl acids together were no longer inhibitory, as expected ifthe IOR activity was now sufficient to provide AroAAs (Fig.7C). This result confirmed the hypothesis that the failure ofS122 to grow in the presence of the aryl acids was due to lowlevels of IOR activity and not due to a polar effect on othergenes at this locus. Compared to the wild type, strain S155also grew slowly in McNA medium without the addition of thearyl acids (Fig. 7C). Presumably, this result reflected thereduced levels of POR activity.

If the aryl acids inhibited de novo AroAA biosynthesis, theymight also inhibit the growth of the wild type. While even lowconcentrations of p-hydroxyphenylacetate were inhibitory, higherconcentrations of phenylacetate or indoleacetate were required(Fig. 8). In contrast to the mutant S122, the aryl acids wereinhibitory only when present individually, and combinationsdid not inhibit. Presumably, when the three aryl acids werepresent together, the AroAAs were formed from the aryl pathwayand the requirement for the de novo pathway was spared. Theabsence of inhibition by all three aryl acids strongly suggestedthat inhibition by aryl acids was due to an effect on AroAAbiosynthesis. However, because tyrosine was assimilated poorly,it was not possible to demonstrate protection by the AroAAsthemselves.

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FIG. 8. Effects of aryl acids on growth of wild type S2. The McNA medium contained 1 mM aryl acids where indicated. The inoculum was $~$ 2 x 10⁵ cells. Shown is the S2 strain growing without any addition ( ${lozenge}$ ), with phenylacetate alone (•), with indoleacetate alone ( ${blacksquare}$ ), with p-hydroxyphenylacetate alone ( ${blacktriangleup}$ ), and with the three aryl acids ( ${triangleup}$ ). The inset shows the growth lag of strain S2 during growth with increasing concentrations of phenylacetate (•), indoleacetate ( ${blacksquare}$ ), and p-hydroxyphenylacetate ( ${blacktriangleup}$ ).

Effect of aryl acids on enzymes of the de novo pathway. To identify the site of action of the aryl acids, the activitiesfor some of the key steps were examined in cell extracts. Inmany prokaryotes and yeasts, the initial reaction, DAHP synthase,is a key regulatory step (18, 30, 40, 41). However, in methanococci,the initial step of the de novo pathway is not known (67), andit was not possible to examine that reaction. For the enzymesof the de novo pathway tested, growth in the presence of thearyl acids had only small effects on the specific activitiesin cell extracts. DHQ is the first enzyme in the pathway thatis known. Its specific activity in wild-type cells grown withthe aryl acids was one-third (2.3 ± 0.1 mU mg^–1)of the level in cells grown without additions (6.0 ±0.2 mU mg^–1). For PDH, the specific activity of cellsgrown with the aryl acids (23 ± 1.2 mU mg^–1) wasnearly the same as the level in cells grown without additions(18 ± 2.1 mU mg^–1). For CM and PDT, the specificactivities were the same (see below). Therefore, the presenceof aryl acids did not have a large affect on the expressionof these enzymes.

The effect of phenylacetate and p-hydroxyphenylacetate on theactivities of the phenylalanine or tyrosine biosynthetic enzymesfrom chorismate were also examined. CM is the first common enzymefor the biosynthesis of both phenylalanine and tyrosine (Fig.1). The CM from M. jannaschii has been categorized as a monofunctionalAroQ (7, 34). The aroQ gene of many organisms is often fusedwith either other AroAA biosynthetic genes or a regulatory domain(7). M. maripaludis possesses a homolog of the M. jannaschiiCM (encoded by aroQ), MMP0578. In cell extracts, the CM specificactivity was affected very little by the AroAAs, phenylacetate,or p-hydroxyphenylacetate, which was expected because a regulatorydomain was not present in the open reading frame (ORF) (Table3). Thus, CM was unlikely to be a major site of inhibition bythe aryl acids.

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TABLE 3. CM, PDT, and PDH specific activities of the wild-type strain S2

PDT is the first enzyme in the phenylalanine branch (Fig. 1).Like the PDT from H. vallismortis (27), the activity of PDTfrom wild-type M. maripaludis was inhibited $~$ 70% by phenylalanineand activated $~$ 2-fold by tyrosine (Table 3). In one set of experiments,the V_max and K_m for prephenate were 5.3 mU min^–1 and 1.2mM, respectively. The apparent V_max and K_m for prephenate inthe presence of the inhibitor phenylalanine at 0.1 mM were 2.8mU min^–1 and 0.96 mM, respectively, and the V_max and K_mfor prephenate in the presence of the activator tyrosine at0.1 mM were 6.0 mU min^–1 and 0.63 mM, respectively. Thus,phenylalanine affected mostly the V_max, while tyrosine affectedmostly the K_m for prephenate. Methanococci contain high intracellularconcentrations of potassium, which is an activator for somebiosynthetic enzymes (70). However, PDT activity from M. maripaludiswas inhibited by KCl, as was previously found for PDT activityfrom E. coli (16). In this series of experiments, the V_max andK_m for prephenate with physiological concentrations of KCl of0.725 M (25) were 7.8 mU min^–1 and 3.5 mM, respectively.In the absence of KCl, the V_max and K_m for prephenate were 6.8mU min^–1 and 1.1 mM, respectively, in this experiment.Thus, KCl largely affected the K_m for prephenate. Phenylacetateand p-hydroxyphenylacetate had no effect on the activity ofPDT from M. maripaludis, even when the assay contained wellbelow the K_m concentration of prephenate (Table 3). Therefore,it is unlikely that this enzyme was the site of inhibition bythe aryl acids.

Finally, PDH, the first committed enzyme of tyrosine biosynthesis,was tested. PDH activity from wild-type M. maripaludis was inhibitedby $~$ 70% by either tyrosine or p-hydroxyphenylpyruvate and 55%by p-hydroxyphenylacetate (Table 3). Phenylalanine had a smalleffect, and phenylacetate had no effect on the PDH activity.This inhibition pattern was consistent with its role in tyrosinebiosynthesis, and it would not explain the growth inhibitionby aryl acids.

DISCUSSION

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Discussion

Evidence has been presented for two pathways of AroAA biosynthesisin M. maripaludis. The presence of the de novo pathway fromdehydroquinate is supported by construction of an AroAA auxotrophvia deletion of the aroD homolog in the genome. Moreover, activitiesof four enzymes in this pathway were demonstrated directly incell extracts. Evidence for the IOR pathway from aryl acidsincludes growth experiments where the aryl acids fulfilled therequirement for AroAAs by the auxotroph and the specific incorporationof the isotopically labeled aryl acid phenylacetate into phenylalanine.The role of IOR2 in this pathway is further supported by theapparent inability of the deletion mutant S122 to incorporatearyl acids.

Anaerobic heterotrophs ferment AroAAs to the aryl acids to provideenergy under starvation conditions (4, 20, 21). Thus, the arylacids may be more abundant in anaerobic environments than theamino acids themselves. Consistent with this idea is the observationthat methanococci utilized the aryl acids more readily thanthe amino acids themselves. Moreover, the aryl acids down regulatedthe de novo biosynthetic pathway sufficiently to inhibit growthin the ${Delta}$ iorA2::pac mutant. Because the AroAAs were taken up poorly,it was not possible to reverse this inhibition completely bythe addition of the amino acids. Thus, it might be that chorismatewas a precursor for additional cellular components in additionto the AroAAs. The inability to demonstrate an additional nutritionalrequirement following extensive subculture of the aroD::pacmutant with only the aryl acids does not support this hypothesis.In addition, the individual aryl acids phenylacetate and p-hydroxyphenylacetateinhibited the growth of the wild-type S2, the ${Delta}$ iorA2::pac mutantS122, and the iorAB2 complementation strain S155. However, whenthe aryl acids were provided together, only the ${Delta}$ iorA2::pac mutantwas inhibited. These results suggested that AroAA biosynthesis,which is the product of the IOR pathway, was the major siteof aryl acid inhibition. These results further imply that thearyl acids are physiologically relevant precursors for the AroAAs.

Although it was not possible to identify the major site of regulationby aryl acids, some regulatory features of the de novo pathwaywere elucidated. These features are summarized in the workingmodel proposed in Fig. 1. Growth in the presence of the arylacids lowered the expression of DHQ but not the levels of CM,PDH, and PDT activity. Thus, regulation of levels of expressionappeared to be a relatively minor factor in the regulation ofthis pathway in methanococci. Similarly, the presence of branched-chainamino acids had only small effects on the specific activitiesof their biosynthetic enzymes (W. L. Gardner and W. B. Whitman,unpublished data).

In contrast, feedback inhibition in the methanococcal enzymesclosely resembles that found in other prokaryotes. Like theenzyme from the halophilic archaeon H. vallismortis, the M.maripaludis PDT activity is inhibited by phenylalanine and activatedby tyrosine (27). Additionally the H. vallismortis PDT is inhibitedby tryptophan and activated by methionine, leucine, and isoleucine.This type of interpathway regulation was discovered in Bacillussubtilis and named metabolic interlock (26). Feedback inhibitionof PDT by phenylalanine is highly conserved in gram-negativeand gram-positive bacteria and yeast (16, 26, 30). In E. coli,the bifunctional P protein has been mapped, and the PDT, CM,and regulatory domains have been clearly identified (72). Twohighly conserved motifs in the regulatory domain that are involvedin the binding of phenylalanine are also present in the M. maripaludisPDT sequence (reference 42 and data not shown). These observationsagree with the proposal for an ancient origin of PDT regulation(27).

The feedback inhibition of PDH by tyrosine is also highly conservedamong gram-positive and gram-negative bacteria (2, 8, 23). TheB. subtilis PDH is also inhibited by phenylalanine, tryptophan,and p-hydroxyphenylpyruvate (8). The M. maripaludis PDH is inhibitedby tyrosine, p-hydroxyphenylpyruvate, and p-hydroxyphenylacetate,connecting it to the aryl acid pathway. However, the magnitudeof the inhibition by p-hydroxyphenylacetate is not sufficientto explain the growth inhibition by this aryl acid. Presumably,the aryl acids have other sites of inhibition in the de novopathway. In any case, feedback inhibition was also observedin the methanococcal acetohydroxyacid synthase, the first enzymein branched-chain amino acid biosynthesis (68, 71), suggestingthat this regulatory mechanism is widely conserved among theprokaryotes.

ACKNOWLEDGMENTS

This work was supported by grant DE-FG02-01ER15262 from theDepartment of Energy.

We thank Andrew Leech for his recommendations on the preparationof dehydroquinate and Robert S. Phillips and John A. Leigh forhelpful discussions.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology, University of Georgia, Athens, GA 30602-2605. Phone: (706) 542-4219. Fax: (706) 542-2674. E-mail: whitman{at}uga.edu.

Present address: 127 Roland Rd., Thomaston, GA 30286.

REFERENCES

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