A Novel Lipolytic Enzyme Located in the Outer Membrane of Pseudomonas aeruginosa

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Journal of Bacteriology, November 1999, p. 6977-6986, Vol. 181, No. 22
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

A Novel Lipolytic Enzyme Located in the Outer Membrane of Pseudomonas aeruginosa

Susanne Wilhelm,¹ Jan Tommassen,² and Karl-Erich Jaeger¹^,^*

Lehrstuhl Biologie der Mikroorganismen, Ruhr Universität, D-44780 Bochum, Germany,¹ and Department of Molecular Microbiology and Institute of Biomembranes, Utrecht University, NL-3584 CH Utrecht, The Netherlands²

Received 13 July 1999/Accepted 8 September 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results and Discussion References

A lipase-negative deletion mutant of Pseudomonas aeruginosa PAO1 still showed extracellular lipolytic activity toward short-chainp-nitrophenylesters. By screening a genomic DNA library of P.aeruginosa PAO1, an esterase gene, estA, was identified, cloned,and sequenced, revealing an open reading frame of 1,941 bp. Theproduct of estA is a 69.5-kDa protein, which is probably processedby removal of an N-terminal signal peptide to yield a 67-kDa matureprotein. A molecular mass of 66 kDa was determined for ³⁵S-labeled EstA by sodium dodecyl sulfate-polyacrylamide gel electrophoresisand autoradiography. The amino acid sequence of EstA indicatedthat the esterase is a member of a novel GDSL family of lipolyticenzymes. The estA gene showed high similarity to an open readingframe of unknown function located in the trpE-trpG region of P.putida and to a gene encoding an outer membrane esterase of Salmonellatyphimurium. Amino acid sequence alignments led us to predictthat this esterase is an autotransporter protein which possessesa carboxy-terminal $beta$ -barrel domain, allowing the secretion ofthe amino-terminal passenger domain harboring the catalytic activity.Expression of estA in P. aeruginosa and Escherichia coli and subsequentcell fractionation revealed that the enzyme was associated withthe cellular membranes. Trypsin treatment of whole cells releaseda significant amount of esterase, indicating that the enzyme waslocated in the outer membrane with the catalytic domain exposedto the surface. To our knowledge, this esterase is unique in thatit exemplifies in P. aeruginosa (i) the first enzyme identifiedin the outer membrane and (ii) the first example of a type IVsecretionmechanism.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results and Discussion References

Pseudomonas aeruginosa is a gram-negative soil bacterium that is also well known to be an important opportunistic human pathogen,which secretes a variety of proteins into the extracellular medium.Three of these are lipolytic enzymes: two extracellular phospholipasesC (PLC) and a lipase (20, 53). Apart from the phospholipases(EC 3.1.4.3), the term "lipolytic enzymes" comprises lipases(EC 3.1.1.3) and esterases (EC 3.1.1.1), which hydrolyze glycerolesters of both short- and long-chain fatty acids. Lipases are,by definition, carboxylesterases that have the ability to hydrolyzelong-chain acylglycerols ( $>=$ C₁₀), whereas esterases hydrolyze estersubstrates with short-chain fatty acids ( $<=$ C₁₀) (57). However,it should be emphasized that lipases are perfectly capable ofhydrolyzing esterase substrates. In P. aeruginosa, the phospholipasesPLC-H (heat-labile hemolysin) and PLC-N (nonhemolytic) have molecularmasses of 78,000 and 73,000, respectively (56), and hydrolyzea variety phosphoric monoester substrates. The lipase LipA hasa molecular mass of 29,000 and hydrolyzes water-insoluble carboxylicesters of long-chain fatty acids, e.g., trioleoyl glycerol andp-nitrophenylpalmitate (53). In addition to these secreted enzymes,an esterase tightly bound to the outer membrane of P. aeruginosawhich has a molecular mass of 55,000 and preferentially hydrolyzeslong-chain acyl thio- or oxyesters has been described (37).

There are two main reasons to study lipolytic enzymes of P. aeruginosa: (i) their important role as virulence factors and(ii) their biotechnologicalpotential.

Clinical P. aeruginosa strains isolated from cystic fibrosis patients produce both lipase and PLC (21). A synergistic effectof PLC-H and LipA which led to the complete hydrolysis in vitroof the major lung surfactant lipid dipalmitoylphosphatidyl-cholinehas been demonstrated (20). Furthermore, these enzymes inducethe release of the inflammatory mediator 12-hydroxyeicosatetraenoicacid from human platelets (27). These findings suggest thatthe lipolytic enzymes of P. aeruginosa act as virulence factors.The outer membrane-bound esterase may enable P. aeruginosa toutilize a variety of acyl esters as carbon sources; however, itsrole in pathogenicity has not been studied (37).

Lipases also play an important role in a variety of biotechnological applications (23). This potential is based on theirability to catalyze not only the hydrolysis of triglycerides butalso their synthesis from glycerol and fatty acids, which mayproceed with high specificity and enantioselectivity (24). Inparticular, P. aeruginosa lipase catalyzes the stereoselectiveconversion of a variety of amines as well as primary and secondaryalcohols (25). Recently, this lipase was used to demonstratethe principle of creating a biocatalyst with high enantioselectivitytoward a given substrate by applying the technique of directedevolution (41).

In the culture supernatant of the lipase-negative deletion mutant P. aeruginosa PABS1, we detected residual lipolytic activity,which led us to identify a novel esterase. The corresponding genewas cloned and expressed, and the encoded protein was analyzedwith respect to its cellularlocation.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results and Discussion References

Strains and plasmids. The strains and plasmids used in this study are listed in Table 1. P. aeruginosa PAO1 and PABS1 were used throughout thisstudy. Escherichia coli JM109 was used as a host for cloning,E. coli S17-1 was used for conjugational transfer of mobilizableplasmids, and E. coli BL21(DE3)(pLysS) (Novagene) was used forselective expression of plasmid-encoded esterase.

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TABLE 1. Strains and plasmids used in this study

Media and growth conditions. Bacteria were grown in glass tubes overnight at 37°C, used to inoculate 5 ml of fresh medium to an optical density at 580nm (OD₅₈₀) of 0.05, and grown for 24 h under aeration. P. aeruginosawas grown in nutrient broth (Oxoid), supplemented when necessarywith 100 µg of tetracycline per ml, 300 µg of chloramphenicolper ml, or 500 µg of carbenicillin per ml. E. coli was grown inLuria broth (LB) medium or M9 minimal medium (42), supplementedwhen necessary with 25 µg of tetracycline per ml, 100 µg of ampicillinper ml, or 50 µg of chloramphenicol perml.

General DNA manipulations. Plasmid DNA was prepared as described by Birnboim and Doly (5) and purified by anion-exchange chromatography on Qia-tips(Qiagen). Chromosomal DNA was prepared as described by Gamperet al. (15). Recombinant DNA techniques were performed essentiallyas described by Sambrook et al. (42). Restriction endonucleasereactions and bacteriophage T4 DNA ligase treatments were doneas recommended by the manufacturers. DNA fragments were analyzedon 0.4 to 1% (wt/vol) agarosegels.

Construction of a genomic library. A genomic library of P. aeruginosa PAO1 chromosomal DNA in cosmid pLAFR3 was constructed as described by Visca et al. (58).Chromosomal DNA was partially digested with Sau3A to obtain fragmentsof >15 kb. Cosmid DNA was linearized with either EcoRI or HindIII,dephosphorylated, mixed, and digested with BamHI. ChromosomalDNA fragments were added and ligated. The $lambda$ -DNA in vitro packagingmodule (Amersham) was used for DNA packaging and infection ofE. coli S17-1. The genomic library consisted of 15,000 individualclones each carrying an insert of 21 to 28 kb (average size),statistically representing 99.9% of the P. aeruginosagenome.

Screening of the genomic library. The individual clones were screened in P. aeruginosa PABS1 on esterase indicator plates. The library clones were conjugatedfrom E. coli S17-1 into P. aeruginosa PABS1 and plated on esteraseindicator plates to detect the formation ofhalos.

Cell fractionation. Cultures (volume, 100 ml) of P. aeruginosa and E. coli grown in LB medium for 24 h were separated by centrifugation (8,000× g for 5 min) into cells and culture supernatant, which was usedto determine the extracellular enzyme activity. The cells wereresuspended in 20 ml of 100 mM Tris-HCl (pH 8.0) and disruptedby two passages through a French press. Cell debris was removedby centrifugation (5,000 × g for 15 min), and the supernatantwas subjected to ultracentrifugation at 100,000 × g for 2 h tocollect the crude membrane fraction, which was resuspended in5 ml of 100 mM potassium phosphate buffer (pH 7.2) (membrane fraction).The resulting supernatant was used as the cytoplasmic/periplasmic(cp/pp)fraction.

Enzyme assays. (i) Plate assay. Esterase indicator plates (28) were prepared by addition of 15 ml of an emulsion of 50% (vol/vol) tributyrin and 5% (wt/vol)gum arabic to 500 ml of molten nutrient broth agar medium. Tributyrinwas emulsified by sonication for 3 min at 75 W (duty cycle 100%)in a Branson 250 sonifier. Esterase and lipase activity is indicatedby the formation of clear halos around thecolonies.

(ii) Liquid assays. For esterase assay 1, 23.7 mg of p-nitrophenyl caproate (pNPC; Sigma) was dissolved in 10 ml of 2-propanol and added to 90ml of Sørensen phosphate buffer (pH 8.0) supplemented with sodiumdeoxycholate (207 mg) and gum arabic (100 mg), yielding a finalpNPC concentration of 1 mM. Culture supernatant (5 to 50 µl) wasadded to the substrate solution to give a final volume of 2.5ml, the solution was incubated for 15 min at 30°C, and the OD₄₁₀was recorded with a Zeiss PMQ II spectrophotometer. The OD₄₁₀/OD₅₈₀ratio was used to estimate clone-specific extracellular enzymeactivities during library screening. For esterase assay 2, 23.7mg of pNPC was dissolved in ethanol (5 ml) and added to 95 mlof 100 mM potassium phosphate buffer (pH 7.0) containing 10 mMMgSO₄ to yield a final concentration of 1 mM pNPC. Samples (5to 50 µl) were added to the substrate solution to give a finalvolume of 1 ml, and the $Delta$ OD₄₁₀/min was recorded for 5 to 10 minat room temperature. The molar absorption coefficient of pNP atpH 7.0 was determined as 10,400 M¹. One unit of enzyme activity is defined as the amount of enzymeforming 1 µmol of pNP per min. For the lipase assay 30 mg of p-nitrophenylpalmitate (pNPP; Sigma) was dissolved in 10 ml of 2-propanol at60°C. The test was done as described above for esterase assay1, except that the reaction was carried out at 37°C (63).

(iii) Glucose-6-phosphate dehydrogenase assay. Glucose-6-phosphate dehydrogenase was used as a cytoplasmic marker enzyme (10). A stock solution of NADP (45 mM) and a stocksolution of glucose-6-phosphate (110 mM) were diluted 1:100 ina buffer containing 55 mM Tris-HCl (pH 7.5) and 11 mM MgCl₂. A950-µl volume of this test solution was mixed with 50 µl of samples,and the decrease in optical density ( $Delta$ OD₃₄₀/min) was monitoredspectrophotometrically at 30°C for 5min.

Trypsin treatment of whole cells. P. aeruginosa and E. coli were grown overnight in LB medium. The cells were collected by centrifugation and resuspended toan OD₅₈₀ of 5 in 100 mM Tris-HCl (pH 8.0). Trypsin (10 µl of astock solution containing 2 mg of trypsin per ml in 100 mM Tris-HCl[pH 8.0]) was added to 100 µl of the cell suspension. After 1h of incubation at 37°C, the protease was inhibited by the additionof 1 mM phenylmethylsulfonyl fluoride. Cells were collected bycentrifugation and resuspended in 100 µl of 100 mM Tris-HCl (pH8.0). Esterase activity was determined in supernatants and wholecells obtained after trypsin treatment. As a control, cells weretreated in the same way except that no trypsin wasadded.

Selective labeling of plasmid-encoded proteins. The selective labeling of esterase encoded by pSKX^/+ was performed as described previously (54). Bacteria precultured in LB/M9medium were used to inoculated 5 ml of fresh medium to an OD₅₈₀of 0.1. At an OD₅₈₀ of 0.6, the cells were harvested and addedto 12 ml of M9 medium supplemented with 0.2% glucose and 0.2%methionine assay mix (Difco). E. coli BL21(DE3) harboring pUCPSKwas used as a control. The expression of T7-RNA polymerase inE. coli BL21(DE3)(pLysS) was induced by the addition at t = 0of 0.4 mM isopropyl- $beta$ -D-thiogalactopyranoside (IPTG). After 30min of incubation (t = 30), a sample was taken and E. coli RNApolymerase was inhibited by the addition of 200 µg of rifampinper ml. Additional samples were taken after 30 (t = 60) and 60(t = 90) min of incubation with rifampin. These samples were labeledin vivo by supplementing 1 ml of culture with 1 µl of L-[³⁵S]methionine-L-[³⁵S]cysteine (10 µCi/ml; Amersham) and incubating the mixture for10 min at 37°C. The cells were harvested, lysed, and denatured,and the proteins were separated by sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) and visualized by autoradiographicdetection on hyperfilm (Amersham) for 48h.

SDS-PAGE. SDS-PAGE was performed as described by Laemmli (30) with a 5% stacking gel and a 15% separatinggel.

DNA sequencing. DNA sequencing was kindly performed by Genencor International, Delft, The Netherlands, using the method described by Sangeret al. (43).

Software. The program BLAST X (2, 16) was used for protein homology searching, PSORT was used for prediction of protein localization(34), and DNAstar (Lasergene) was used for sequencealignments.

Nucleotide sequence accession number. The DNA sequence of estA from P. aeruginosa has been deposited in GenBank (accession no. AF005091).

	RESULTS AND DISCUSSION

Top Abstract Introduction Materials and Methods Results and Discussion References

Screening of a genomic library. A genomic library containing P. aeruginosa DNA cloned in pLAFR3 was transferred from E. coli S17-1 into the lipase-negativemutant P. aeruginosa PABS1 by conjugation, and bacteria were platedon esterase indicator plates containing tributyrin. Although thistriglyceride is a classical lipase substrate, it is partiallysoluble in water and is therefore also hydrolyzed by esterases(7). Colonies with extracellular esterase or lipase activityformed clear halos on these plates. As shown in Fig. 1A, lipaseproduction in the wild-type strain P. aeruginosa PAO1 caused theformation of a large halo, which appeared after overnight incubation,whereas the halo formed by the lipase-negative mutant PABS1 wasmuch smaller and appeared only after incubation of the platesfor at least 48 h. Our screening was based on the assumption thatsuch a halo would appear earlier and with increased diameter ifseveral copies of the esterase gene cloned in pLAFR3 were expressedin the lipase-negative mutant. After a library consisting of 15,000clones was screened, 11 positive clones with halos of intermediatesize, i.e., smaller than that formed by the wild type but largerthan that of the lipase-negative mutant, were identified. Severalclones identified on esterase indicator plates were further assayedfor lipase and esterase activity in the culture supernatant (Fig.1B). The wild-type strain, PAO1, showed high lipase activity andsignificantly lower esterase activity. However, its esterase activitywas still higher than that of the lipase-negative mutant, PABS1,presumably because of the ability of lipase to cleave the esterasesubstrate. Introduction of pLAFR3-21.P into P. aeruginosa PABS1yielded a 10-fold increase in esterase activity (Fig. 1B). Theslightly increased lipase activity was presumably caused by theability of esterase to hydrolyze the lipase substrate p-nitrophenylpalmitate.

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FIG. 1. Lipolytic activity of P. aeruginosa strains, wild-type PAO1, lipase-negative mutant PABS1, and PABS1pLAFR3-21.P containing a cosmid with a 22.1-kb insert of chromosomal DNA from P. aeruginosa PAO1. (A) Halo formation of bacterial colonies on esterase indicator plates after incubation for 3 days at 30°C. (B) Lipolytic activities of culture supernatants in liquid assays, assayed with p-nitrophenylpalmitate (C₁₆) for lipase activity and p-nitrophenylcaproate (C₆) for esterase activity. Relative enzyme activities were determined as the ratio of OD₄₁₀ (enzyme activity) to OD₅₈₀ (cell density) per milliliter of culture supernatant.

Identification of the esterase. The cosmid pLAFR3-21.P was digested with various restriction endonucleases, and fragments were subcloned into plasmid pUCPSK,transferred into the lipase-negative mutant, PABS1, and assayedfor esterase activity. After several subcloning steps, one clonecontaining plasmid pUCPSK carrying a 3.3-kb XhoI fragment wasisolated. This fragment was cloned in both orientations, and thecorresponding plasmids were named pSKX+ and pSKX $-$ , respectively.P. aeruginosa PABS1(pSKX+) showed high esterase activity (datanot shown), whereas no increase in esterase activity was observedfor P. aeruginosa PABS1(pSKX $-$ ). The DNA fragment cloned in plasmidpUCPSK in the positive orientation is expressed from the lac promoter,which is constitutively expressed in P. aeruginosa, thereby explainingthe observed esterase activity, whereas in the opposite (negative)orientation it is under control of the T7 promoter. To identifya putative protein encoded by this fragment, we used an E. coliT7-RNA polymerase expression system. Samples were taken at severaltime intervals, and each of them was immediately labeled withL-[³⁵S]methionine-L-[³⁵S]cysteine in vivo. Expression from pSKX $-$ yielded a single 66-kDaprotein band visible upon autoradiography, which appeared whencellular protein synthesis was inhibited by addition of rifampin(Fig. 2). Since no protein bands were detected in cells harboringeither the control plasmid pUCPSK or pSKX+, we concluded thatthe 3.3-kb XhoI fragment of P. aeruginosa DNA cloned in pSKX $-$ contained a single open reading frame (ORF) expressed from P_T7which encoded a protein with M_r = 66,000.

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FIG. 2. Autoradiography of L-[³⁵S]methionine-L-[³⁵S]cysteine-labeled proteins from cell lysates of E. coli BL21(DE3)(pLysS) containing pSKX $-$ separated by SDS-PAGE. Samples were labeled prior to induction of T7 RNA polymerase expression (t = 0; lane A), 30 min after induction but prior to inhibition of E. coli RNA polymerase with rifampin (t = 30; lane B), and 30 min (t = 60; lane C) and 60 min (t = 90; lane D) after addition of rifampin. Lane M contains prestained molecular mass markers (Bio-Rad).

Nucleotide sequence analysis. Determination of the nucleotide sequence of this DNA fragment (Fig. 3) revealed an ORF of 1,941 bp, which was designated estA.A putative Shine-Dalgarno sequence was located 7 bp upstream ofthe ATG start codon, and a consensus sequence typical for an RpoN-dependentpromoter [TGGCACN₅TTGC(a/t)] (33) was identified 135 bp upstreamof the translational start codon. The G+C content was 66.9% andthe frequency of C or G at the third codon position was 89.2%,indicating a typical P. aeruginosa codon usage (62). The esteraseencoded by estA is synthesized as a 646-amino-acid precursor witha calculated M_r of 69,526, including a predicted 24-amino-acidsignal sequence (35). The mature esterase has a calculated molecularweight of 67,000, which is consistent with the M_r determined bySDS-PAGE and autoradiography. A BLAST X (2, 16) analysisof estA revealed homologies to an ORF located in the trpE-trpGregion of P. putida (11), to apeE encoding an outer membraneesterase from Salmonella typhimurium (9), to lip-1 encodinga lipase from Xenorhabdus (Photorhabdus) luminescens (59), andto the GCAT gene encoding a acyltransferase of Aeromonas hydrophila(32). These proteins and the esterase of P. aeruginosa belongto a novel family of lipolytic enzymes identified on the basisof sequence homology (55). Many of the prokaryotic proteinsof this new family exhibited lipolytic activity; eukaryotic memberswere found in higher plants (6), and their physiological functionsare as yet unknown. Five conserved blocks of high amino acid homologywere identified (Fig. 4). The enzymes belonging to this novelfamily differ from other lipases in the location and structureof the active-site consensus motif G-X-S-X-G (22). In this family,this motif is located close to the N terminus and consists ofG-D-S-X-S, with the terminal glycine of the characteristic lipaseconsensus motif replaced in most cases by serine. The active siteof these enzymes consists of a catalytic triad formed by the aminoacids serine, histidine, and aspartate. For A. hydrophilia lipase/acyltransferase,serine 16, histidine 291, and aspartate 116, located in blocksI, V, and III, respectively (Fig. 4), were shown by site-directedmutagenesis to form the catalytic triad (8). Aspartate 116could not unequivocally be assigned to the active site, and asecond aspartate residue at position 288 was identified as anotherlikely candidate (8). Recently, the three-dimensional structureof an esterase from Streptomyces scabies was determined by X-raycrystallography (61). This enzyme is unique among all knownlipolytic enzymes in that instead of a triad, it contains an active-sitedyad consisting of a serine and a histidine residue. The correctorientation of the histidine imidazole ring is normally ensuredby hydrogen bonding to the carboxyl group of a third residue (aspartateor glutamate), which is replaced here by the backbone carbonylof a tryptophan. The three-dimensional structure of an esteraseisolated from bovine brain has a similar active-site architecture.In this case, however, the tryptophan is indeed replaced by aspartate(18). A comparison of the amino acid sequences of S. scabiesand bovine brain esterases with the sequences of A. hydrophilalipase/acyltransferase and of P. aeruginosa EstA (3) indicatedthat in these enzymes, aspartate residues at positions 288 and286, respectively, belong to the catalytic triad, as indicatedin Fig. 4. Therefore, we predict that the catalytic triad of theP. aeruginosa esterase is formed by serine 14, histidine 289,and aspartate 286.

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FIG. 3. Nucleotide sequence and derived amino acid sequence of the esterase gene estA. The putative Shine-Dalgarno sequence is underlined, the consensus sequence for the RpoN ( $sigma$ ⁵⁴)-dependent promoter is marked by dashed lines, and the putative signal sequence is indicated by an arrow.

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FIG. 4. Sequence comparison between P. aeruginosa esterase (EstA) and members of a novel family of lipolytic enzymes (55). Identical amino acids are shaded in grey; numbers in parentheses refer to the number of amino acid residues between the conserved blocks. The putative catalytic triad residues (*) are printed in bold, and the G-D-S-L-S consensus motif is underlined.

Secretion. Esterase activity could be detected in the bacterial culture supernatant (Fig. 1B). Furthermore, a putative signal sequenceprecedes the mature esterase protein, leading us to assume thatthis enzyme could be secreted by the general secretory pathway(GSP) (12). This pathway consists of two steps: the secretedprotein is translocated through the inner membrane via the Sec-dependentmechanism and is subsequently translocated through the outer membraneby the Xcp machinery (12). The lipase-negative mutant P. aeruginosaPABS1 and two different xcp mutants were transformed with plasmidsencoding either lipase (pLip1) or esterase (pSKX+), and the extracellularenzyme activities were determined. In mutant 2B18, the xcpA gene,encoding the prepilin-peptidase, which is required for the processingof several Xcp components, is disrupted (36, 49), and in mutantPUS13, the outer membrane secretin XcpQ is absent. Since the lipaseis known to be secreted via the GSP (24), it served as a control.As shown in Table 2, xcp mutants did not show extracellular lipaseactivity. However, the extracellular esterase activity remainedunaffected, demonstrating that the esterase is not secreted viathe GSP.

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TABLE 2. Extracellular enzyme activities of a lipase-negative P. aeruginosa strain and mutants defective in the general secretory pathway

Cellular localization. EstA was predicted to be anchored to the outer membrane by the computer program PSORT (34). Additional observations suggestedan outer membrane location of the 28-kDa C-terminal fragment ofEstA (amino acids 374 to 622): (i) it contains many putative amphipathic $beta$ -strands, and (ii) as in the vast majority of bacterial outermembrane proteins (50), the C-terminal amino acid residue isa phenylalanine. These observations led us to compare the C-terminalfragment of EstA with other outer membrane proteins (Fig. 5),revealing a significant similarity to a family of proteins whichis secreted by gram-negative bacteria and has been designatedthe autotransporter family (31). These proteins, which are believedto be virulence factors, are secreted by the so-called type IVsecretion mechanism (13), which has so far not been found tooperate in P. aeruginosa (17). Autotransporter proteins aretranslocated through the inner membrane via a Sec-dependent mechanismand cross the periplasm, and their $beta$ -domain inserts into the outermembrane. The catalytically active $alpha$ -domain (i) remains attachedto the outer membrane, (ii) is autoproteolytically cleaved off,or (iii) is cleaved off by another protease (17). Significantamino acid homologies to recognized members of the autotransporterfamily, such as Ssp (22.6%), a serine protease from Serratia marcescens(64), and VacA (23.3%), a vacuolating cytotoxin from Helicobacterpylori (44), were detected. However, the highest homology scoreswere found to an outer membrane-located esterase from S. typhimurium(24.6%) (9) and to a secreted lipase from X. luminescens (29.3%)(59). Interestingly, this lipase inserts into the outer membraneupon expression in E. coli (59). So far, these lipolytic enzymeshave not been found to possess a C-terminal autotransporter domain.Autotransporters share a number of characteristic features, whichalso exist in the P. aeruginosa esterase. (i) They possess anN-terminal leader peptide. (ii) The mature protein consists ofa surface-exposed N-terminal passenger domain (or $alpha$ -domain), whichharbors the catalytic site, and a C-terminal $beta$ -domain locatedin the outer membrane (17). The $alpha$ -domain usually contains theN-terminally located active-site motifs followed by a stretchof amino acids with few cysteine residues (Cys258 and Cys264 inEstA). The C-terminal $beta$ -domains of autotransporters are predictedto contain 14 amphipathic $beta$ -strands, which may form a $beta$ -barrelpore, allowing the translocation of the $alpha$ -domain to the bacterialcell surface (31). (iii) The terminal amino acid residue isalways a phenylalanine or tryptophan, which is preceded by fouralternating charged/polar and hydrophobic/aromatic residues (31,50). In EstA the terminal amino acid residue is F622 and ispreceded by D-L-S-L-A-L-S-V. (iv) Proline 171 and glycine 275have been identified as two fully conserved residues by the aligningautotransporter domains of several proteins (31). These residuesare also present in EstA (Fig. 5).

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FIG. 5. Multiple alignment of C-terminal domains. EstA, outer membrane proteins, and secreted proteins belonging to the autotransporter family (31) were compared. Boxes indicate putative amphiphathic $beta$ -barrels, and the two fully conserved amino acids from the ATF are marked with an asterisk.

Based on these predictions, we investigated experimentally the localization of EstA in the lipase-negative mutant P. aeruginosaPABS1 (wild type for esterase) and the esterase-overexpressingstrain P. aeruginosa PABS1 containing estA on pBBX+. Cellularcompartments were fractionated into culture supernatant, cytoplasmic-periplasmicfraction, and a crude membrane fraction. The absolute esteraseactivity was about 10-fold higher in the overexpressing strain,but in both strains more than 95% of the esterase activity wasdetected in the crude membrane fraction (Fig. 6A). Only 2 to 3%of the enzyme activity was released into the culture supernatant,which did not contain glucose-6-phosphate dehydrogenase activity(Fig. 6B), indicating that no significant cell lysis had occurred.These results showed that EstA is tightly membrane bound in P.aeruginosa. A comparable result was obtained when estA was expressedin the heterologous host E. coli, although the absolute amountsof esterase activity were smaller. The small amount of extracellularesterase may have two possible explanations: (i) the enzyme wascleaved by a protease and remained bound to the outer membrane,as found for the Ag43 protein from E. coli (39), with only asmall amount released into the extracellular medium; or (ii) theenzyme remained bound to the outer membrane, as shown for Hsrfrom Helicobacter mustelae (38). A small part of the esterasemight have been released either in a free form or in the formof membrane vesicles which contain in P. aeruginosa periplasmic,membrane-bound, and extracellular proteins (4).

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FIG. 6. Distribution of esterase (A) and glucose-6-phosphate dehydrogenase (B) activity in cellular compartments of P. aeruginosa PABS1 and E. coli JM109 containing estA on pBBX+. The percentages of total enzyme activities present in culture supernatants (SN), cytoplasmic-periplasmic fractions (CP/PP), and membranes (M) are given.

Inspection of the C-terminal domain of EstA revealed several segments that could form amphipathic $beta$ -strands. Assuming thatthe $beta$ -domains of all autotransporters have similar tertiary structures,we expect that the amphipathic character should be conserved inall $beta$ -strands that are actually part of the $beta$ -barrel. When thenew members of the autotransporter family identified in this studyare aligned with the recognized members of the family (examplesare given in Fig. 5), 11 segments that could form amphipathic $beta$ -strands in all sequences could be distinguished. These segmentsare almost devoid of $beta$ -turn predictions, when the criteria describedby Paul and Rosenbusch (40) are applied, whereas turn predictionsare generally found in the intervening segments (data not shown).Since a closed $beta$ -barrel should consist of an even number of $beta$ -strands,the $beta$ -barrel may consist of as few as 10 $beta$ -strands, with the firstsegment reaching through the interior of the barrel, thereby exposingthe $alpha$ -domain to the cell surface. Alternatively, the barrel formedmay not be closed, creating an instability that may result inthe destruction of the $beta$ -domain after the translocation of the $alpha$ -domain. In this respect, it should be noted that the fate ofthe $beta$ -domain after having performed its job has hardly been investigatedso far. A 10- or 11-stranded $beta$ -barrel could enclose only a smallpore, which indicates that the passenger domain should be transportedin a delineated fashion. In agreement, the periplasmic foldingof an artificial passenger domain has been demonstrated to preventouter membrane translocation (26). However, it should be notedthat the $beta$ -domain does not necessarily have to form a $beta$ -barrelwith an enclosed pore to exert its function. The molecular mechanismof transport may be entirely different. For example, it has beenreported that a lipid-modified domain of OmpA, encompassing onlyfive $beta$ -strands, can transport a periplasmic passenger proteinto the cell surface (14). Clearly, these five $beta$ -strands cannotform a pore through which the passenger is transported. A tentativetopology model of the $beta$ -domain of EstA is depicted in Fig. 7.As in the porins, the $beta$ -strands are connected by short periplasmicturns and longer extracellular loops. Furthermore, two girdlesof aromatic residues that may surround the putative $beta$ -barrel atthe height of the polar head groups of the lipids in the membranecan readily be discerned. Further experiments are required toinvestigate the structure and function of the autotransporterdomain of P. aeruginosa EstA as well as of other members of thefamily.

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FIG. 7. One possible model of the C-terminal domain of P. aeruginosa esterase (EstA) located in the outer membrane. The C-terminal domain (~G 374 to F 622) is predicted to consist of 11 amphipathic $beta$ -strands with 10 to 12 amino acid residues per strand, sufficient to traverse the hydrophobic core of the membrane. The two amino acids fully conserved in proteins belonging to the autotransporter family (31) are marked with asterisks; amino acids printed in bold indicate the hydrophobic side of the $beta$ -strands; and amino acids shaded in grey represent two girdles of aromatic residues, which seem to be present in outer membrane proteins of known structure.

Our model predicts that the catalytically active N-terminal domain of EstA is exposed to the surface and should at least partlybe accessible to proteolytic cleavage. Therefore, whole cellsof P. aeruginosa and E. coli expressing estA were treated withtrypsin and the residual cell-bound esterase activity was determined.As shown in Fig. 8 a significant amount of esterase activity wasremoved (20% for P. aeruginosa and 10% for E. coli). Increasingthe amount of trypsin did not result in an increased amount ofesterase removed from cells. Increasing the concentration of MgCl₂during trypsin treatment led to a decrease in the amount of esteraseactivity removed, whereas increasing the concentration of EDTAled to a increase in the amount of esterase activity removed (datanot shown). These results indicate the following. (i) The esteraseexpressed in P. aeruginosa and in E. coli is partly accessibleto trypsin treatment of whole cells. Since the localization andthe protease accessibility in E. coli and in P. aeruginosa arevery similar, the information allowing the enzyme to reach thecell surface must be independent of specific factors present onlyin the homologous host and should therefore reside in EstA itself.(ii) Removal of a significant part of the esterase activity fromwhole cells of P. aeruginosa and E. coli by trypsin treatmentstrongly suggests that EstA is attached to the bacterial outermembrane, as predicted by our model (Fig. 7). (iii) The trypsin-resistantportion of the esterase may be shielded by association with lipopolysaccharideand/or exopolysaccharide as described for outer membrane proteins(48) and also for extracellular lipase from P. aeruginosa (53).Further experiments are required to decide whether the accessibilityof esterase to trypsin is different in appropriate mutants alteredin lipopolysaccharide or exopolysaccharide (e.g., alginate) composition.

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FIG. 8. Effect of trypsin treatment on esterase activities of whole cells of P. aeruginosa and E. coli containing estA on pBBX+.

In summary, a novel esterase was identified which is located in the outer membrane of P. aeruginosa. This enzyme presumablybelongs to a family of putative virulence factors which are self-secretedvia a C-terminally located autotransporter domain. Determinationof esterase activity in a cell-free culture supernatant led usto assume that the catalytically active N-terminal esterase domainmay be released into the external medium by a so far unknown mechanism.At present, we are trying to identify the enzyme responsible forproteolytic cleavage of surface-exposed EstA and are investigatingthe physiological significance of this novel lipolyticenzyme.

	ACKNOWLEDGMENTS

We thank Alain Filloux, IBSM-CNRS, Marseille, France, and Steve Lory, University of Washington, Seattle, Wash., for providingP. aeruginosa mutantstrains.

This work was supported by grant BIO4-CT96-0119 from the European Commission in the framework of the Biotechnology Program.S.W. is a recipient of a graduate fellowship from the DeutscheForschungsgemeinschaft (Graduiertenkolleg: "Biogenese und Mechanismenkomplexer Zellfunktionen").

	FOOTNOTES

^* Corresponding author. Mailing address: Ruhr Universität Bochum, Lehrstuhl Biologie der Mikroorganismen, Universitätsstrasse150, D-44780 Bochum, Germany. Phone: 49 234 322 3101. Fax: 49234 321 4425. E-mail: karl-erich.jaeger{at}ruhr-uni-bochum.de.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results and Discussion
References

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1.	Akrim, M., M. Bally, G. Ball, J. Tommassen, H. Teerink, A. Filloux, and A. Lazdunski. 1993. Xcp-mediated protein secretion in Pseudomonas aeruginosa: identification of two additional genes and evidence for regulation of xcp gene expression. Mol. Microbiol. 10:431-443[Medline].
2.	Altschul, S. F., W. Gish, W. Miller, and D. J. Lipman. 1990. Basic local alignment search tool. J. Mol. Biol. 215:403-410[Medline].
3.	Arpigny, J. L., and K.-E. Jaeger. 1999. Bacterial lipolytic enzymes: classification and properties. Biochem. J. 343:177-189.
4.	Beveridge, T. J. 1999. Structures of gram-negative cell walls and their derived membrane vesicles. J. Bacteriol. 181:4725-4733[Free Full Text].
5.	Birnboim, H. C., and J. Doly. 1979. A rapid alkaline extraktion procedure for screening recombinant plasmid DNA. Nucleic Acids Res. 7:1513-1523[Abstract/Free Full Text].
6.	Brick, D. J., M. J. Brumlik, J. T. Buckley, J.-X. Cao, P. C. Davies, S. Misra, T. J. Tranbarger, and C. Upton. 1995. A new family of lipolytic plant enzymes with members in rice, arabidopsis and maize. FEBS Lett. 377:475-480[Medline].
7.	Brockerhoff, H. 1969. Action of pancreatic lipase on emulsions of water-soluble esters. Arch. Biochem. Biophys. 134:366-371[Medline].
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