YfcX Enables Medium-Chain-Length Poly(3-Hydroxyalkanoate) Formation from Fatty Acids in Recombinant Escherichia coli fadB Strains

Expression of Escherichia coli open reading frame yfcX is shownto be required for medium-chain-length polyhydroxyalkanoate(PHA_MCL) formation from fatty acids in an E. coli fadB mutant.The open reading frame encodes a protein, YfcX, with significantsimilarity to the large subunit of multifunctional ß-oxidationenzymes. E. coli fadB strains modified to contain an inactivatedcopy of yfcX and to express a medium-chain-length synthase areunable to form PHA_MCLs when grown in the presence of fatty acids.Plasmid-based expression of yfcX in the FadB^- YfcX^- PhaC⁺ strainrestores polymer formation. YfcX is shown to be a multifunctionalenzyme that minimally encodes hydratase and dehydrogenase activities.The gene encoding YfcX is located downstream from yfcY, a geneencoding thiolase activity. Results of insertional inactivationstudies and enzyme activity analyses suggest a role for yfcXin PHA monomer unit formation in recombinant E. coli fadB mutantstrains. Further studies are required to determine the naturalrole of YfcX in the metabolism of E. coli.

INTRODUCTION

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Introduction

Polyhydroxyalkanoates (PHAs) are a class of biopolyesters thatare receiving considerable attention for use as renewable plasticsin packaging and personal hygiene items (40). A broad spectrumof properties can be obtained from PHAs by varying the monomerunit composition (38, 40). PHAs containing short-chain-lengthmonomer units are thermoplastics, whereas PHAs containing medium-chain-lengthmonomer units are elastomeric. While considerable progress hasbeen made toward understanding and manipulating pathways forthe formation of short-chain-length PHAs (23, 34, 38), suchas poly-3-hydroxybutyrate and poly-3-hydroxybutyrate-co-3-hydroxyvalerate,our understanding of the biosynthesis of medium-chain-lengthPHAs (PHA_MCL) is not as extensive. Escherichia coli engineeredwith a PHA synthase possessing substrate specificity for medium-chain-lengthmonomer units will only produce significant levels of PHA_MCLwhen grown in the presence of fatty acids if the activity ofthe fatty acid ß-oxidation complex has been disruptedby mutation or chemical inhibition (37). Since ß-oxidationactivities are required to process longer-chain fatty acidsto PHA_MCL monomer units (Fig. 1), the requirement of a disruptedfatty acid ß-oxidation complex for PHA_MCL formationis counterintuitive.

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FIG. 1. Proposed pathways for PHA_MCL formation from fatty acyl-CoAs in recombinant E. coli fadB strains engineered with a PHA_MCL synthase. Reactions 1 through 4 indicate enzymes that may participate in the formation of (R)-3-hydroxyacyl-CoA from ß-oxidation pathway intermediates. Reactions: 1, (R)-ß-ketoacyl-CoA reductase (31); 2, 3-ketoacyl-acyl carrier protein reductase (FabG; 39); 3, 3-hydroxyacyl-CoA epimerase (activity of the FadB multienzyme; 28); 4, (R)-enoyl-CoA hydratase (31). Question marks refer to activities that have not been demonstrated in E. coli.

In the study described here, we examined the ability of fadBmutants of E. coli to produce PHA_MCL from longer-chain fattyacids. FadB encodes the ${alpha}$ subunit of a multienzyme complex thatis involved in the degradation of fatty acids in E. coli (4).It has been previously suggested (37) that FadB activities areinvolved in PHA_MCL formation in E. coli strain LS1298, a fadBmutant of E. coli, despite reports (9) that the strain is devoidof ß-oxidation activities. These unexplained resultsencouraged us to evaluate the ability of fadB strains to producePHA_MCL from longer-chain fatty acids and to search for alternativeactivities that may play a role in PHA_MCL formation.

Searches of the E. coli nucleotide sequence database identifiedenzymes that could contribute to PHA_MCL monomer unit formationin a fadB mutant on the basis of their homology to ß-oxidationenzymes. Candidate genes were identified and isolated, and theirenzyme activities were characterized. Enzymatic analyses andinsertional inactivation studies suggest a requirement for yfcX,a previously uncharacterized open reading frame in E. coli,for PHA_MCL formation from fatty acids in fadB mutants.

MATERIALS AND METHODS

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Materials and Methods

General methods. Protein concentrations were determined by the Bradford dye-bindingprocedure (5) with bovine serum albumin as the standard andprotein assay solution from Bio-Rad (Hercules, Calif.). Acetoacetylcoenzyme A (CoA) and saturated acyl-CoA substrates were purchasedfrom Sigma (St. Louis, Mo.). Standards of 3-hydroxyalkanoicacids for gas chromatography (GC) analysis were obtained fromMatreya, Inc. (Pleasant Gap, Pa.).

Bacterial strains and medium. The bacterial strains, plasmids, and primers used in this studyare listed in Table 1. Dehydrated LB (Luria-Bertani) broth (Miller),Bacto 2x YT, and Bacto M9 minimal salts (5x) were purchasedfrom Difco Laboratories (Detroit, Mich.). Palmitic and decanoicacid stock solutions contained 2.5% (wt/vol) fatty acid and10% (wt/vol) Brij-58, pH 7.0, and were sterilized by autoclavingbefore use. Room temperature stock solutions of palmitic acidwere briefly heated at 50°C before addition to the culturemedium to create a homogeneous solution. Antibiotics were addedto culture medium where indicated at the following concentrations:chloramphenicol, 25 mg/liter; ampicillin, 100 mg/liter; kanamycin,50 mg/liter; tetracycline, 15 mg/liter.

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TABLE 1. Bacterial strains, plasmids, and primers used in this study

Strain MBX763 was constructed via transduction of strain MG1655with a P1 lysate propagated from E. coli LS1298. Cells resistantto kanamycin were selected for further study. Strain MBX763was unable to grow after 72 h on E2 minimal plates (21) supplementedwith 5 mM oleate, 10 mM octanoate, or 20 mM butyrate.

Genetic manipulations. All PCR fragments were sequenced and found to contain wild-typesequences except where noted.

(i) pKPS1.2. A 1.68-kb BamHI/PstI fragment containing phaC1 of P. oleovoranswith its native ribosome binding site (RBS) was isolated frompPOB10 (O. P. Peoples and A. J. Sinskey, international patentapplication WO 91/00917, January 1991) and ligated into vectorpKK223-3 (Amersham Pharmacia Biotech, Piscataway, N.J.).

(ii) pTRCN-KPS1.2. The 1.68-kb phaC gene was excised from pKPS1.2 with BamHI andHindIII and cloned into pTRCN (11).

(iii) pTRCN-KPS1.2N. A 0.43-kb fragment was amplified by PCR from plasmid pTRCN-KPS1.2with primers Posyn1-N and Posyn1-nrSacII. The PCR fragment,containing an E. coli RBS upstream of the N-terminal fragmentof phaC1, was digested with EcoRI and cloned into the EcoRI/SmaIsites of vector pTRCN as an EcoRI/blunt fragment. The 1.72-kbintact synthase gene was reconstructed by subcloning a 1.33-kbSacII/HindIII C-terminal synthase fragment from pTRCN-KPS1.2behind the PCR fragment.

(iv) pSU18-KPS1.2N. The 1.72-kb EcoRI/HindIII phaC1 fragment of pTRCN-KPS1.2N wasexcised and cloned into pSU18 (1).

(v) pTRCN-f714. The yfcX gene was isolated by PCR from DH1 genomic DNA withprimers n-f714 and c-f714. The 2.1-kb PCR fragment was digestedwith EcoRI and BamHI and cloned into pTRCN.

(vi) pTRCABV. The yfcY gene was isolated by PCR from E. coli MBX245 genomicDNA with primers A6V.up and A6V.dw. The 1.34-kb PCR fragmentwas digested with BamHI and HindIII and cloned into pTRCN, formingpTrcAV. The yfcY gene was isolated from pTrcAV as a BamHI/HindIIIfragment and inserted into the BamHI/HindIII sites of pTRCN-f714,forming pTRCABV. Plasmid pTrcABV contains the trc promoter,followed by yfcX and yfcY.

(vii) pYfcYX. Plasmid pYfcYX contains the trc promoter, followed by yfcY andyfcX. The 3.44-kb yfcYyfcX insert of the plasmid was constructedin a two-step procedure. A 1.14-kb N-terminal portion of theyfcY fragment was isolated by PCR from E. coli DH1 genomic DNAwith primers A5-N and YfcY-nr-ClaI. The fragment was digestedwith EcoRI and subcloned into the EcoRI and SmaI sites of vectorpTRCN, forming 5.28-kb intermediary plasmid pN-A5. A 2.63-kbfragment containing the C terminus of yfcY, as well as yfcX,was isolated by PCR from E. coli DH1 genomic DNA with primersYfcX4 and c-f714. The fragment was digested with SmaI and BamHIand subcloned into the SmaI and BamHI sites of pN-A5.

(viii) pTRCNfadBA#6. A 9.4-kb BamHI fragment was isolated from plasmid pCEM (35)and cloned into the BamHI site of pTRCN, forming intermediaryplasmid pTRCN-CEMA. Plasmid pTRCN-CEMA was digested with NaeIand MfeI, and the protruding ends were filled in with Klenow.A 5.2-kb fragment was isolated from an agarose gel and clonedinto the SmaI site of pTRCN, forming plasmid pTRCNfadBA#6. Theorientation of the fadBA fragment in pTRCNfadBA#6 is suitablefor transcription from the trc promoter.

(ix) pTRCNfadBKanA#1. Genomic DNA isolated from strain LS1298 was digested with MfeIand NaeI, and protruding ends of the digested fragments werefilled in with Klenow. The resulting blunt-ended fragment wasligated into the SmaI site of vector pSU18, forming plasmidpSU18MF/NA#1. Plasmid pSU18MF/NA#1 was digested with MfeI andNaeI, and the resulting fragment was cloned into pTRCN thathad been digested with SmaI. Plasmid pTRCNfadBKanA#1 was isolatedfrom the kanamycin-resistant transformants. DNA sequencing confirmedthat the anticipated 6.5-kb NaeI/MfeI fragment, containing thegene encoding kanamycin resistance inserted into the BalI siteof fadB, had been isolated from the chromosome.

(x) pTRCNf714tet. Plasmid pACYC184 (6) was digested with AvaI and XbaI, and protrudingends of DNA were filled in with Klenow. A 1.50-kb blunt-endedfragment encoding tetracycline resistance was isolated and insertedinto the NruI site of yfcX in plasmid pTRCN-f714.

(xi) pMAKf714tet-A. Plasmid pTRCNf714tet was digested with EcoRI and XbaI, and protrudingends of DNA were filled in with Klenow. A 3.5-kb blunt-end yfcX-tetfragment was isolated. Plasmid pMAK705 (13) was digested withSphI, treated with T4 DNA polymerase, and ligated to the previouslyprepared yfcX-tet fragment.

(xii) pTRCNPOX1A. The gene encoding POX1 was isolated by PCR from genomic DNAof Saccharomyces cerevisiae strain FY-2 with primers N-pox1and C-pox1. The 2.27-kb PCR product was digested with KpnI andXbaI and cloned into pTRCN (11). Bases 1328 and 1329 of thePCR product were found to be inverted compared to the sequenceof the S. cerevisiae oxidase coding region reported by Dmochowskaet al. (10). This inversion, yielding a serine instead of thepredicted threonine, was observed in multiple clones.

Chromosomal disruption of yfcX. Chromosomal disruption of yfcX in E. coli LS1298 was performedby homologous recombination with plasmid pMAKf714tet-A as previouslydescribed (25). Integration candidates were tested for chloramphenicolsensitivity and tetracycline resistance by replicate plating.Two-thirds of the colonies examined were chloramphenicol sensitive,signifying excision of the vector DNA from the chromosome andsubsequent loss of the DNA from the cell. None of the examinedcolonies were found to be tetracycline resistant. Genomic DNAsamples of chloramphenicol-sensitive integrants were screenedfor the presence of a tetracycline-disrupted yfcX allele byPCR with primers f714seq7 and f714seq8. Integrant MBX2014, containinga PCR product of the expected size for the tetracycline-disruptedyfcX gene, was selected for further analysis by Southern blotting.Southern analysis was performed as described by Sambrook etal. (33) by using the 2.17-kb EcoRI/BamHI yfcX fragment fromplasmid pTRCN-f714 as a probe. Probes were labeled prior touse with the AlkPhos direct labeling kit (Amersham PharmaciaBiotech) in accordance with the directions supplied by the manufacturer.Southern prehybridizations, hybridizations, and washes wereperformed at 60°C. Signal detection was achieved with theCDP-Star chemiluminescent signal detection kit (Amersham PharmaciaBiotech) in accordance with the directions supplied by the manufacturer.Restriction maps of chromosomal fragments containing the wild-typeyfcX allele were prepared from the 11.40-kb chromosomal fragmentof E. coli listed in the GenBank database under accession no.AE000322.

Preparation of substrates. 3-Ketoacyl-CoA compounds were synthesized as follows. 3-Ketoacylthiophenyl esters were prepared from Meldrum's acid and theappropriate acid chloride by a procedure similar to that reportedearlier (27). The 3-ketoacyl thiophenyl ester derivatives werepurified via silica gel chromatography with mixtures of ethylacetate and hexane. 3-Ketoacyl-CoA thioester compounds wereprepared by trans-thiol esterification reaction of CoA withthe appropriate 3-ketoacyl thiophenyl esters. Typically, 0.3mmol of the thiophenyl ester was mixed with 0.12 mmol of CoAin 50 mM KH₂PO₄, pH 7.5, containing Triton X (0.1%) and acetonitrile(25 to 50%). The reaction was monitored by C₁₈ reversed-phaseanalytical high-performance liquid chromatography (HPLC). Thereactions were monitored for loss of CoA and formation of the3-ketoacyl-CoA derivative. Conversions ranged from 20 to 95%,depending upon the chain length of the 3-keto ester. After completionof the reaction, the mixture was acidified with phosphoric acidto pH 3, extracted with ether to remove thiophenol and its disulfide,and purified by solid-phase extraction or preparative C₁₈ HPLC.Products were analyzed by analytical HPLC.

${Delta}$ ²-Enoyl-CoA substrates were enzymatically synthesized from thecorresponding acyl-CoAs with acyl-CoA oxidase purified fromE. coli 1106/pTRCNPOX1A. Cells were cultured in 2x YT at 30°C,and recombinant protein expression was induced with 0.4 mM isopropyl-ß-D-thiogalactopyranoside(IPTG) when cells reached an optical density at 600 nm of 0.6.Cells isolated from 1 liter of culture were resuspended in 10mM KH₂PO₄, pH 7.0, and lysed by sonication. Soluble proteinswere loaded onto a Toyo Jozo DEAE fast protein liquid chromatography(FPLC) column (3 by 14 cm) equilibrated with 10 mM KH₂PO₄, pH7.0 (buffer A). The column was washed with buffer A (200 ml),and acyl-CoA oxidase activity was eluted with a linear gradientof NaCl (0.2 liter plus 0.2 liter, 0 to 500 mM) in buffer A.Fractions were analyzed for acyl-CoA oxidase activity by measuringthe increase in A₂₆₃ due to formation of the double bond inan assay mixture (1 ml) containing 0.2 M KH₂PO₄, pH 7.0, 34µM acyl-CoA, and enzyme. One unit of oxidase activitywas defined as the formation of 1 µmol of ${Delta}$ ²-enoyl-CoA( ${varepsilon}$ ₂₆₃ = 6,700 M^-1 cm^-1; 3) per min. Acyl-CoA oxidase-containingfractions were combined, dialyzed (50,000-molecular-weight cutoff)overnight (buffer A, 2 x 3 liters), and concentrated to 1 mlin a Centriprep YM-50 (Millipore, Bedford, Mass.), yieldinga precipitate. The precipitate was resuspended, transferredto an Eppendorf tube, and centrifuged (Eppendorf microcentrifuge,10 min, 4°C). The resulting pellet was washed three timeswith buffer A and dissolved in 10 mM KH₂PO₄, pH 7.0, containing20% glycerol. The above procedure typically yielded partiallypurified protein preparations with specific activities rangingfrom 4 to 18 U/mg.

${Delta}$ ²-Enoyl-CoAs were prepared in a reaction mixture (1 ml) containing0.2 M KH₂PO₄, pH 7; 34 µM saturated acyl-CoA; and 10 µlof acyl-CoA oxidase (total, 0.02 to 0.2 U). The concentrationsof saturated acyl-CoA substrates (in 50 mM KH₂PO₄, pH 4.7) weredetermined at 259 nm ( ${varepsilon}$ = 16.4 mM^-1 cm^-1) (36) prior to the reaction.The progress of the enzymatic synthesis was monitored at 263nm and the reaction mixture was incubated at room temperatureuntil all of substrate was consumed. The reaction mixture wastransferred to a Centricon YM-50 (Millipore), and acyl-CoA oxidasewas removed by centrifugation. The liquid flowthrough, containing0.2 M KH₂PO₄, pH 7, and 34 µM acyl-CoA, was used immediatelyas the substrate for hydratase assays.

Enzyme activity analysis. The substrate specificities of the enoyl-CoA hydratase, 3-hydroxyacyl-CoAdehydrogenase, and ß-keto thiolase enzymes in YfcXor YfcYX expression strains (Fig. 2) were determined in crudeextracts prepared from cells cultured at 37°C in 2x YT mediumcontaining ampicillin. Recombinant protein expression was inducedwith 1 mM IPTG when cells reached an optical density at 600nm of 0.6. Cells were harvested after a total culture time of24 h and lysed by sonication. Cell lysates were clarified bycentrifugation prior to use in enzyme assays. For thiolase anddehydrogenase assays, cell pellets were resuspended in 1 mlof lysis buffer containing 50 mM Tris, pH 8.2; 1 mM EDTA; 10mM ß-mercaptoethanol; 20% glycerol; and 0.2 mM phenylmethylsulfonylfluoride. For hydratase assays, isolated cell pellets were resuspendedin 2 ml of lysis buffer containing 10 mM KH₂PO₄, pH 7.0.

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FIG. 2. Enzymatic analysis of YfcX and YfcY.

Residual enoyl-CoA hydratase and 3-hydroxyacyl-CoA dehydrogenaseactivities in strains expressing insertion mutant forms of yfcXor fadB were measured in crude extracts prepared from cellscultured at 30°C in 2x YT medium containing ampicillin.Cultures were induced with 0.4 mM IPTG at an optical densityat 600 nm of 0.6 and harvested after a total culture time of24 h. Cell pellets were resuspended in 2 ml of lysis bufferprepared by dissolving one tablet of complete mini proteaseinhibitors (Roche Diagnostics, Indianapolis, Ind.) in 10 mlof 10 mM KH₂PO₄, pH 7.0.

Dehydrogenase activity was assayed in reverse by monitoringthe decrease in A₃₄₀ due to the conversion of NADH to NAD⁺ (3).A typical assay mixture (1 ml) contained 100 mM KH₂PO₄, pH 7.0;0.2 mg/ml bovine serum albumin; 0.1 mM NADH; and 30 µM3-ketoacyl-CoA and was initiated by the addition of enzyme tothe assay mixture. One unit of dehydrogenase activity was definedas the loss of 1 µmol of NADH ( ${varepsilon}$ ₃₄₀= 6,220 M^-1 cm^-1)/min.

Hydratase activity was assayed by measuring the decrease inA₂₆₃ due to the hydration of the double bond as described byBinstock and Schulz (3). The final assay mixture (1 ml) contained17 µM ${Delta}$ ²-enoyl-CoA substrate; 0.2 M KH₂PO₄, pH 7.0; and0.2 mg of bovine serum albumin per ml. One unit of hydrataseactivity is defined as the loss of 1 µmol of ${Delta}$ ²-enoyl-CoA( ${varepsilon}$ ₂₆₃ = 6,700 M^-1 cm^-1)/min.

Thiolase activity was assayed by monitoring the thiolysis ofß-ketoacyl-CoA substrates at 304 nm ( ${varepsilon}$ = 16.9 x 10³cm^-1 M^-1, acetoacetyl-CoA; ${varepsilon}$ = 15.6 x 10³ cm^-1 M^-1, 3-ketohexanoyl-CoA; ${varepsilon}$ = 14.5 x 10³ cm^-1 M^-1, 3-ketooctanoyl-CoA; ${varepsilon}$ = 13.5 x 10³ cm^-1M^-1, 3-ketodecanoyl-CoA and 3-ketododecanoyl-CoA [2]) as previouslydescribed, with some modifications (8). The assay mixture (1ml) contained 65 mM Tris, pH 8.2; 50 mM MgCl₂; 62.5 µMCoA; 62.5 µM 3-ketoacyl-CoA; and soluble crude cell extract.One unit of thiolase activity was defined as the loss of 1 µmolof ß-ketoacyl-CoA/min.

PHA_MCL accumulation. Cell cultures for PHA_MCL production were performed with hoststrain LS1298 (9). A starter culture of freshly transformedcells was cultured at 37°C overnight in a 500-ml Erlenmeyerflask containing 50 ml of LB medium and the appropriate antibiotics.Cells were diluted 1:100 into a 500-ml Erlenmeyer flask containing50 ml of fresh medium, and the samples were cultured at 37°Cuntil the A₆₀₀ reached 0.6. The cells were induced with 2 mMIPTG, and either palmitic acid or decanoic acid was added tothe culture medium at a final concentration of 0.25% (wt/vol).Samples were cultured for an additional 72 h prior to harvest.Isolated cell pellets were washed with 20 ml of 1x minimal M9salts, isolated by centrifugation, and washed with an additional10 ml of 1x minimal M9 salts. The cell pellet was dried overnightin a lyophilizer.

The total polymer content of cell samples, as well as the monomerunit composition of the polymer, was determined with a simultaneousextraction-and-butanolysis procedure. Cell samples and 3-hydroxyalkanoicacid standards were heated at 110°C for 2 h in 2 ml of amixture containing (by volume) 90% 1-butanol and 10% concentratedhydrochloric acid with 2 mg of benzoic acid per ml as an internalstandard. The water-soluble components of the resulting mixturewere removed by extraction with water (2 ml). The organic phase(1 µl; split ratio, 1:50; overall flow rate, 2 ml/min)was analyzed on an SPB-1 fused silica capillary GC column (30m; 0.32-mm inside diameter; 0.25-µm film; Supelco; Bellefonte,Pa.) connected to a Hewlett-Packard gas chromatograph with thefollowing temperature profile: 80°C, 2 min; linear temperaturegradient of 10°C/min from 80 to 250°C; 250°C, 2min.

Purification of YfcYX. E. coli MBX763/pYfcYX was cultured at 30°C in LB mediumsupplemented with ampicillin and kanamycin. Recombinant proteinexpression was induced for 24 h with 0.4 mM IPTG when the culturereached an optical density at 600 nm of 0.6. Cell pellets from2 liters of culture were resuspended in 50 ml of 10 mM KP_i,pH 7, containing complete mini protease inhibitor cocktail (RocheDiagnostics). Cells were lysed by sonication, and the cell lysatewas clarified by centrifugation, yielding a soluble proteinextract typically containing 11.2 U of hydratase activity permg with the substrate ${Delta}$ ²-decenoyl-CoA. Soluble proteins wereloaded (3 ml/min) onto a Toyo Jozo DEAE FPLC column (3 by 14cm) that had been previously equilibrated with buffer A (10mM KH₂PO₄ [pH 7.0], 50 mM NaCl). The column was washed with200 ml of buffer A, and proteins bound to the column were elutedwith a linear gradient of NaCl (0.2 liter plus 0.2 liter, 0to 500 mM) in buffer A. Fractions (10 ml) containing hydrataseactivity with the substrate ${Delta}$ ²-decenoyl-CoA were pooled, dialyzed(2 x 3 liters, 10 mM KP_i [pH 7], 4°C, 24 h), and concentratedwith a Centricon 30 (Millipore). Glycerol (20%) was added, andthe samples were stored at -80°C.

Gel filtration of the purified YfcYX preparation was performedon a Superdex 200 HR 10/30 FPLC column (Amersham Pharmacia Biotech)preequilibrated in buffer C (10 mM KP_i [pH 7], 150 mM NaCl).A standard calibration curve was generated with blue dextran2000, thyroglobulin (669 kDa), catalase (232 kDa), albumin (67kDa), chymotrypsinogen A (25 kDa), ferritin (440 kDa), aldolase(158 kDa), ovalbumin (43 kDa), and RNase (13.7 kDa). For molecularweight determinations and enzyme activity analysis, an aliquotof YfcYX was loaded onto the gel filtration column and proteinswere eluted (0.25 ml/min) in buffer C. A portion of each fractionwas analyzed for hydratase, dehydrogenase, and thiolase with ${Delta}$ ²-decenoyl-CoA, 3-hydroxydecanoyl-CoA, and 3-ketodecanoyl-CoAas substrates.

RESULTS

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Results

Polymer formation in LS1298/pSU18-KPS1.2N/pTRCN. Previous researchers have observed the presence of PHA monomerunits with a chain length shorter than that of the initial fattyacid carbon feed in polymer samples isolated from E. coli fadBmutant strains engineered for PHA production (22, 29, 30, 31).The presence of the shorter monomer units suggests that thehost strains retain some fatty acid degradation activities despitethe disruption of the FadBA fatty acid ß-oxidationcomplex. In this study, E. coli strain LS1298 (9) was chosenas the host to examine both the fatty acid degradation and PHAmonomer unit-producing abilities of fadB mutant strains. Thepolymer formed in strain LS1298/pSU18-KPS1.2N/pTRCN was usedas a benchmark with which to compare additional strains, aswell as to confirm the ability of LS1298 to degrade fatty acidsduring PHA_MCL production (22, 30). Plasmid pSU18-KPS1.2N containsthe gene encoding P. oleovorans synthase 1 (17) behind a strongE. coli RBS, and plasmid pTRCN is a vector control. For PHAproduction, cultures of LS1298/pSU18-KPS1.2N/pTRCN cells weregrown at 37°C in LB medium with either 0.25% palmitic ordecanoic acid as the carbon source. Synthesis of plasmid-encodedproteins was induced with IPTG, and all strains were allowedto accumulate PHA for 72 h. When palmitic acid was utilizedas the carbon source, LS1298/pSU18-KPS1.2N/pTRCN produced 9.2%± 0.6% PHA per unit of dry cell weight (Table 2). Theaccumulated PHA contained 55.1 ± 1.0 mol% 3-hydroxyoctanoateand 44.9 ± 1.0 mol% 3-hydroxydecanoate (Table 2). Whendecanoic acid was utilized as the carbon source, LS1298/pSU18-KPS1.2N/pTRCNproduced 8.5% ± 0.6% PHA per unit of dry cell weight(Table 2). The accumulated PHA contained 37.7 ±3.1 mol%3-hydroxyoctanoate and 62.3 ± 3.1 mol% 3-hydroxydecanoate(Table 2). Strain LS1298/pSU18/pTRCN, containing both vectorcontrols, did not produce detectable levels of PHA of any monomerunit composition, suggesting that PHA was formed only in thepresence of active synthase. The ability to produce PHA_MCL containingmonomer units with differing chain lengths in LS1298/pSU18-KPS1.2N/pTRCNwith either palmitic or decanoic acid as the carbon source confirmedthe presence of fatty acid degradation activities within LS1298.

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TABLE 2. PHA_MCL accumulation in LS1298 and MBX2014 strains^a

Analysis of enzymatic activities in the disrupted fadB gene from LS1298. Residual activities remaining in a disrupted ß-oxidationcomplex might contribute to the fatty acid degradation observedduring polymer formation in strain LS1298/pSU18-KPS1.2N/pTRCN.While it has been proposed that the disrupted fadB allele inLS1298 contains a defective yet active dehydrogenase, as wellas functional hydratase and epimerase activities (37), no experimentaldata has been provided to support these claims. In fact, LS1298has been reported to be deficient in ß-oxidation activitieswhen assayed with four-carbon-unit substrates (9). To determineif residual fadB activities are encoded by the disrupted fadBkangene of LS1298, a genomic DNA fragment encoding the fadBkangene was isolated and cloned into E. coli expression vectorpTRCN. The resulting plasmid was named pTRCNFadBKanA#1. A controlplasmid, pTRCNFadBA#6, was also constructed by cloning an equivalentfragment encoding the intact FadBA ß-oxidation complexinto pTRCN.

Plasmids were transformed into host strain DH5 ${alpha}$ , and dehydrogenaseand hydratase activities were measured in crude cell extractswith trans-2-hexenoyl-CoA and 3-ketodecanoyl-CoA, respectively,substrates identified as having the preferred chain length foreach activity in purified preparations of FadBA (3). Equivalentdehydrogenase activities were observed in strain DH5 ${alpha}$ /pTRCNFadBKanA#1,expressing the disrupted ß-oxidation complex, andDH5 ${alpha}$ /pTRCN, containing the vector alone, yielding 0.36 and 0.37U/mg, respectively. The dehydrogenase activity of strain DH5 ${alpha}$ /pTRCNFadBA#6,expressing the native ß-oxidation complex, was substantiallyhigher, yielding 12.5 U/mg. Hydratase activity in strain DH5 ${alpha}$ /pTRCNFadBKanA#1(0.8 U/mg) was slightly higher than the activity observed instrain DH5 ${alpha}$ /pTRCN (0.3 U/mg) but significantly lower than thehydratase activity measured in the undisrupted complex in strainDH5 ${alpha}$ /pTRCNFadBA#6 (16.5 U/mg).

Identification of genes with homology to ß-oxidation enzymes. The absence of dehydrogenase activity and the minimal levelsof hydratase activity observed in strain DH5 ${alpha}$ /pTRCNFadBKanA#1suggest that additional enzymes may participate in fatty aciddegradation during polymer formation in LS1298/pSU18-KPS1.2N/pTRCN.To determine if E. coli contains other enzymes capable of catalyzingthe degradation of fatty acids, the amino acid sequence of therat long-chain enoyl-CoA hydratase/3-hydroxyacyl-CoA dehydrogenase ${alpha}$ subunit of the mitochondrial trifunctional protein (20; GenBankaccession no. D16478) was used to screen the E. coli nucleotidesequence database with the TBLASTN program from The NationalCenter for Biotechnology Information. The rat trifunctionalprotein was chosen because it encodes a dehydrogenase activityas well as a long-chain hydratase activity, an enzyme whosegene has yet to be identified in E. coli (4, 7). Open readingframe f714, corresponding to yfcX on the physical map of E.coli K-12 (32), was found to be 39.5% identical to the geneencoding the rat trifunctional protein. YfcX is an uncharacterizedprotein that has been recently classified as a member of thecrotonase superfamily of enzymes on the basis of its amino acidsequence homology to the rat mitochondrial crotonase (12). Alignmentsof the amino acid sequence of YfcX with that of FadB, the previouslyidentified ${alpha}$ subunit of the E. coli FadBA ß-oxidationcomplex (2, 3, 9), were prepared to determine if active-siteamino acid residues in FadB are conserved in YfcX. YfcX (714amino acids) is 34% identical to FadB (729 amino acids), andits alignment spans the entire FadB amino acid sequence. Inaddition, amino acid residues important for hydratase and dehydrogenaseactivities in FadB are conserved in YfcX. G116 and E139, active-siteresidues for enoyl-CoA hydratase and 3-hydroxyacyl-CoA epimeraseactivity in FadB (41, 42), are conserved as G115 and E140, respectively,in YfcX. E119, a residue that is important for enoyl-CoA hydrataseactivity in FadB (14), is conserved as E118 in YfcX. H450 andE462, active-site amino acids for 3-hydroxyacyl-CoA dehydrogenaseactivity in FadB (15, 16), are conserved as H446 and E458, respectively,in YfcX.

Analysis of enzyme activities of proteins with homology to ß-oxidation enzymes. YfcX was identified as a possible candidate for the fatty acid-degradingactivities observed during polymer production in LS1298 strainson the basis of its homology to enzymes associated with ß-oxidation.To test the activities of the candidate enzymes, the gene encodingYfcX was isolated by PCR from genomic DNA and cloned into E.coli expression vector pTRCN (11). The overexpression plasmidwas transformed into host strain DH5 ${alpha}$ and cultured in 2x YT mediumat 37°C as described in Materials and Methods. Selectedintermediates from the ß-oxidation of saturated fattyacids were employed as substrates for the enzyme assays. Withthis approach, plasmid-based expression of YfcX from strainDH5 ${alpha}$ /pTRCN-f714 yielded significant dehydrogenase activity withß-ketoacyl-CoAs of 6, 8, and 10 carbon units, comparedto that of control strain DH5 ${alpha}$ /pTRCN (Fig. 2). The dehydrogenaseactivity of DH5 ${alpha}$ /pTRCN-f714 with acetoacetyl-CoA as a substratewas less than that of control strain DH5 ${alpha}$ /pTRCN. Significanthydratase activity was observed in DH5 ${alpha}$ /pTRCN-f714, comparedto that of control strain DH5 ${alpha}$ /pTRCN. Activity with ${Delta}$ ²-enoyl-CoAsubstrates of 6, 8, 10, and 12 carbon units was observed. Minimalactivity was observed with crotonyl-CoA.

Chromosomal inactivation of yfcX. Hydratase and dehydrogenase enzyme assays of YfcX suggest thatthe multifunctional-enzyme gene may encode activities that accountfor the fatty acid degradation observed during polymer productionin FadB mutant strains engineered with a medium-chain-lengthsynthase. To determine if the activities of YfcX are essentialfor polymer production in E. coli fadB strains, the yfcX genewas inactivated by insertion of a fragment encoding tetracyclineresistance into its coding sequence. The resulting plasmid,pTRCN-f714tet, was assayed for dehydrogenase and hydratase activitiesin host strain DH5 ${alpha}$ with 3-ketodecanoyl-CoA as the substrate.Dehydrogenase activities of 0.20 and 0.23 U/mg were observedfor strains DH5 ${alpha}$ /pTRCN and DH5 ${alpha}$ /pTRCN-f714tet, respectively, suggestingthat an inactivated dehydrogenase was created upon disruptionof yfcX. Hydratase activities of 0.44 and 0.1 U/mg were observedfor strains DH5 ${alpha}$ /pTRCN and DH5 ${alpha}$ /pTRCN-f714tet, respectively, suggestingan inactivated hydratase activity. The disrupted yfcX gene wastransferred to the chromosome of LS1298 by homologous recombinationof plasmid pMAKf714tet-A. The disruption of yfcX in the chromosomeof LS1298 was confirmed by Southern blotting in integrant candidateMBX2014 (Fig. 3).

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FIG. 3. Maps comparing restriction enzyme sites in the 12.92-kb predicted chromosomal fragment of MBX2014 (a) and the 11.40-kb predicted chromosomal fragment of LS1298 (b). (c) Southern blot of digested genomic DNA preparations from strains MBX2014 and LS1298. Each lane contains 2 µg of genomic DNA digested with the indicated enzymes. Lanes: 1, MBX2014 genomic DNA digested with SapI, HindIII, and SacII; 2, MBX2014 genomic DNA digested with SapI and SacII; 3, LS1298 genomic DNA digested with SapI, HindIII, and SacII; 4, LS1298 DNA digested with SapI and SacII.

Analysis of PHA production in a fadB yfcX mutant strain. An inactivated yfcX gene in strain LS1298 provides a usefultool with which to study the role of YfcX during polymer formationin fadB mutant strains. Strain MBX2014/pSU18-KPS1.2N/pTRCN,the fadB yfcX double-mutant host strain with plasmid-based expressionof PHA_MCL synthase and a pTRCN vector control, failed to accumulateany polymer when either palmitic or decanoic acid was utilizedas the carbon source. This observation suggests a requirementfor activities associated with yfcX for polymer production inE. coli fadB mutant strains. Plasmid-based expression of yfcXfrom pTRCN-f714 in strain MBX2014/pSU18-KPS1.2N/pTRCN-f714 wasfound to restore polymer formation, yielding 27.7% ±3.6% (dry cell weight) PHA when palmitic acid was the carbonsource and 10.1% ± 0.5% (dry cell weight) PHA when decanoicacid was utilized as the carbon source (Table 2).

Identification of a gene encoding thiolase activity upstream of yfcX. Enzymatic assays of strains overexpressing YfcX revealed elevatedlevels of hydratase and dehydrogenase activities compared tothose of wild-type strains. These enzymes are often associatedwith fatty acid ß-oxidation complexes. Interestingly,YfcY, encoded by a gene located upstream of yfcX, was previouslyassigned as a putative thiolase in homology searches of theE. coli nucleotide sequence database in our laboratory (L. Madison,unpublished data). To determine if YfcY indeed possesses thiolaseactivity, crude extracts prepared from strain DH5 ${alpha}$ /pTrcABV, encodingYfcX and YfcY, were assayed. DH5 ${alpha}$ /pTrcABV contained significantthiolase activity, compared to that of control strain DH5 ${alpha}$ /pTRCN(Fig. 2). Thiolase activity in DH5 ${alpha}$ /pTrcABV was observed withß-ketoacyl-CoAs of 6, 8, 10, and 12 carbon units.Little to no thiolase activity was observed when acetoacetyl-CoAwas used as the substrate.

Comigration of YfcY and YfcX as a high-molecular-weight complex during gel filtration. The hydratase, dehydrogenase, and thiolase enzyme activitiesassociated with bacterial fatty acid degradation, such as FadBand FadA of E. coli (2) or FaoA and FaoB of Pseudomonas fragi(19), have been shown to copurify in multienzyme complexes composedof multimers of subunits. Since YfcY and YfcX contain activitiesrelated to fatty acid degradation, purification of the enzymescoexpressed in strain DH5 ${alpha}$ /pYfcYX was performed. Throughout thepurification process, hydratase activity was monitored withthe substrate ${Delta}$ ²-decenoyl-CoA. Greater-than-ninefold purificationof the enzyme, with respect to hydratase activity, was achievedupon passage of the crude MBX763/pYfcYX lysate over a DEAE FPLCcolumn (Table 3). Sodium dodecyl sulfate-polyacrylamide gelelectrophoresis (SDS-PAGE) indicated that the purified proteinfraction contained proteins with sizes equivalent to those ofboth YfcX and YfcY. The native molecular weights of proteinsin the purified preparation were estimated by passing the sampleover a Superdex 200 HR 10/30 gel filtration column. Peaks possessingnative molecular masses of 435,510 Da (peak P2), 11,950 Da (peakP3), 3,700 Da (peak P4), and 1,460 Da (peak P5) were observedin the gel filtration chromatogram (Fig. 4a). Peak P1 migratedwith the void volume of the column. Fractions in peak P2 (435,510Da) were the only fractions that contained any protein detectableby SDS-PAGE (Fig. 4b). These fractions were found to be enrichedin bands close to the predicted sizes of YfcX (77.1 kDa) andYfcY (46.5 kDa). The multiple bands observed may be due to degradationof the protein during purification, since protease inhibitorswere not used. Enzyme activity analysis of fractions 7 through14 demonstrated that thiolase, hydratase, and dehydrogenaseactivities coeluted in fractions 9 through 13 (Fig. 4c).

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TABLE 3. Partial purification of YfcYX^a

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FIG. 4. Analysis of protein content and enzyme activity in fractions obtained upon gel filtration of partially purified YfcYX preparations. (a) FPLC gel filtration chromatogram obtained upon loading of 1.08 mg of partially purified YfcYX onto a Superdex 200 HR 10/30 gel filtration column. Calculated molecular masses of eluted peaks: P1, void volume; P2, 435,510 Da; P3, 11,950 Da; P4, 3,700 Da; P5, 1,460 Da. (b) SDS-PAGE analysis of fractions collected by gel filtration chromatography. Samples were subjected to SDS-10% PAGE. Lanes MW contained molecular size markers. (c) Thiolase, hydratase, and dehydrogenase activities in fractions collected by gel filtration chromatography.

DISCUSSION

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Discussion

While previous researchers have demonstrated that significantPHA_MCL formation in genetically engineered E. coli proceedsonly when the fatty acid ß-oxidation system of thehost strain is impaired (37), the ability of E. coli to degradefatty acyl-CoAs without the activities of the FadB componentof its ß-oxidation system has not been addressed.Conversion of fatty acyl-CoAs to 3-hydroxyacyl-CoAs with a shorterchain length requires the ß-oxidation system to possessacyl-CoA dehydrogenase, enoyl-CoA hydratase, 3-hydroxyacyl-CoAdehydrogenase, and ß-ketothiolase activities for fattyacid degradation, as well as enoyl-CoA hydratase activity for3-hydroxyacyl-CoA formation (Fig. 1). Strain LS1298, one ofthe fatty acid degradation-impaired strains capable of producingPHAs from fatty acids when engineered with a PHA_MCL synthase(22, 30), contains an insertionally inactivated fadB gene thathas been reported to encode inactive enoyl-CoA hydratase, 3-hydroxyacyl-CoAdehydrogenase, and ß-ketothiolase when assayed withenzyme substrates with a four-carbon-unit chain length (9).PHA_MCL formation in recombinant LS1298 strains from fatty acidcarbon feeds is therefore unexplained.

In this study, the ability of LS1298 to form PHA monomer unitswith chain lengths shorter than that of the initial fatty acidfeed was examined. First, residual enzyme activities remainingin the disrupted FadB component of ß-oxidation weremeasured. Plasmid-based overexpression of a genomic DNA fragmentcontaining the insertionally inactivated fadB gene from LS1298yielded no 3-hydroxyacyl-CoA dehydrogenase activity and basallevels of enoyl-CoA hydratase activity when the enzymes wereassayed with substrates with the preferred chain length forFadB activities. The absence of 3-hydroxyacyl-CoA dehydrogenaseactivity suggests that an enzyme other than the disrupted FadBenzyme contributes to the degradation of fatty acyl-CoAs observedduring polymer formation. Searches of the translated E. coligenome for candidate enzymes capable of degrading fatty acyl-CoAsidentified YfcX and YfcY, amino acid sequences containing homologyto known multifunctional ß-oxidation enzymes. Enzymeassays of extracts prepared from recombinant E. coli overexpressingYfcX confirmed that the polypeptide possesses enoyl-CoA hydrataseactivity, as well as 3-hydroxyacyl-CoA dehydrogenase activity.While the substrate specificity of the dehydrogenase componentof YfcX is similar to the dehydrogenase activity observed inFadB (2), the hydratase activities of the two enzymes vary significantly.YfcX contains a hydratase activity with a preference for medium-chain-lengthsubstrates, whereas FadB contains an activity with a preferencefor short-chain substrates. The substrate specificity of YfcYis similar to that of the thiolase activity observed in FadAof the E. coli FadBA ß-oxidation complex (2). Inactivationof yfcX in LS1298 via insertional mutagenesis yielded a strainthat, when engineered with a PHA_MCL synthase, was unable toform PHA_MCL from palmitic or decanoic acid feeds. The abilityto form PHA_MCL was restored to the mutant strain upon plasmid-basedexpression of yfcX. These observations suggest that yfcX encodesa gene product that contributes to the formation of PHA_MCL monomerunits from fatty acids with longer chain lengths in strain LS1298.

The formation of PHA_MCL has previously been used as a tool withwhich to monitor the flow of carbon through the fatty acid ß-oxidationpathways of plants (24). Here, we have used the formation ofPHA_MCL to detect the presence of enzyme activities that arestill capable of degrading fatty acids in E. coli strains inwhich the FadB component of the FadBA ß-oxidationcomplex has been disrupted. This tool has allowed us to identifythe genes responsible for the degradation and to characterizethe activities of the encoded enzymes. The enzyme activitiesof YfcX and YfcY and the comigration of the proteins as a high-molecular-weightcomplex in gel filtration experiments suggest that YfcX andYfcY possess some similarity to enzymes associated with bacterialfatty acid ß-oxidation complexes. The estimated nativemolecular mass of the YfcYX complex (435 kDa) does not, however,conform to the formation of a heterotetramer model as predictedwith the E. coli FadBA (3) and P. fragi FaoAB (18) complexes.While this work was in progress, Olivera et al. (26) reportedthe presence of two separate ß-oxidation pathwaysin Pseudomonas putida U and suggested that other microbes, includingE. coli, may also have more than one set of ß-oxidationactivities. The need for a second enoyl-CoA hydratase activityfor PHA production in E. coli fadB mutants was mentioned bythe authors as support for a second set of ß-oxidationactivities in E. coli. Additional experiments are required tofully characterize the YfcYX complex and to determine if E.coli does indeed possess more than one ß-oxidationpathway.

ACKNOWLEDGMENTS

We acknowledge Concetta DiRusso for supplying E. coli LS1298and plasmid pCEM, S. Kushner for supplying plasmid pMAK705,the laboratory of Fred Winston for supplying S. cerevisiae strainFy-2, Karen Frost for supplying plasmid pSU18, Roberto Kolterfor supplying E. coli MG1655, A. Eisenstark for supplying E.coli 1106, Xun Tu for technical assistance, and Oliver Peoplesfor critically reviewing the manuscript.

FOOTNOTES

* Corresponding author. Mailing address: Metabolix, Inc., 303 Third St., Cambridge, MA 02142. Phone: (617) 492-0505. Fax: (617) 492-1996. E-mail: snell{at}metabolix.com.

Present address: Cell Signaling Technology, Beverly, MA 01915.

Present address: TEPHA, Cambridge, MA 02142.

Present address: Dyax Corp., Cambridge, MA 02139.

REFERENCES

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