Abstract
Two novel genes encoding for heat and solvent stable lipases from strictly anaerobic extreme thermophilic bacteria Thermoanaerobacter thermohydrosulfuricus (LipTth) and Caldanaerobacter subterraneus subsp. tengcongensis (LipCst) were successfully cloned and expressed in E. coli. Recombinant proteins were purified to homogeneity by heat precipitation, hydrophobic interaction, and gel filtration chromatography. Unlike the enzymes from mesophile counterparts, enzymatic activity was measured at a broad temperature and pH range, between 40 and 90°C and between pH 6.5 and 10; the half-life of the enzymes at 75°C and pH 8.0 was 48 h. Inhibition was observed with 4-(2-aminoethyl)-benzenesulfonyl fluoride hydrochloride and phenylmethylsulfonylfluorid indicating that serine and thiol groups play a role in the active site of the enzymes. Gene sequence comparisons indicated very low identity to already described lipases from mesophilic and psychrophilic microorganisms. By optimal cultivation of E. coli Tuner (DE3) cells in 2-l bioreactors, a massive production of the recombinant lipases was achieved (53–2200 U/l) Unlike known lipases, the purified robust proteins are resistant against a large number of organic solvents (up to 99%) and detergents, and show activity toward a broad range of substrates, including triacylglycerols, monoacylglycerols, esters of secondary alcohols, and p-nitrophenyl esters. Furthermore, the enzyme from T. thermohydrosulfuricus is suitable for the production of optically pure compounds since it is highly S-stereoselective toward esters of secondary alcohols. The observed E values for but-3-yn-2-ol butyrate and but-3-yn-2-ol acetate of 21 and 16, respectively, make these enzymes ideal candidates for kinetic resolution of synthetically useful compounds.
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Introduction
Lipases (triacylglycerol acylhydrolases, EC 3.1.1.3) are best defined as carboxylesterases that catalyze both the hydrolysis and synthesis of long-chain acylglycerols (Jaeger et al. 1999). True lipases can be defined as carboxylesterases that catalyze the hydrolysis and synthesis of relatively long-chain acylglycerols with acyl chain lengths of >10 carbon atoms. Lipases share a similar active site consisting of three residues: a nucleophilic serine residue in a Gly-X-Ser-X-Gly motif, an acidic residue (aspartic acid or glutamic acid), and a histidine. These residues act cooperatively in the catalytic mechanism of ester hydrolysis. The enzymes also display a common α/β hydrolase fold (Ollis et al. 1992) which is also found in other hydrolases, such as haloalkane dehalogenase, acetylcholinesterase, dienelactone hydrolase, and serine carboxypeptidase. Based on comparisons of amino acid sequences and biological properties, prokaryote-derived lipases have been classified into eight different families (I–VIII) (Arpigny and Jaeger 1999).
Lipases are an important group of biotechnologically relevant enzymes, and they find applications in food, diary, detergent, and pharmaceutical industries. Most lipases, that are derived from mesophilic microorganisms, can act in a wide range of pH but are mostly unstable at temperatures above 70°C. Bacterial lipases generally have temperature optima in the range of 30–65°C. Recently, reports on diverse microbial, moderate thermoactive lipases from mesophiles have been published (Chung et al. 1991; Gilbert et al. 1991; Sugihara et al. 1991, 1992; Shabtai and Daya-Mishne 1992). Several lipases have been purified and characterized from moderate thermophilic isolates, mainly representatives of the genus Bacillus (Sugihara et al. 1991; Fakhreddine et al. 1998), such as the lipases from Bacillus thermoleovorans ID-1 (Lee et al. 1999), Bacillus thermocatenulatus (Schmidt-Dannert et al. 1994, 1996, 1997), Bacillus stearothermophilus (Kim et al. 1998, 2000; Sinchaikul et al. 2002), Bacillus sp. J33 (Nawani and Kaur 2000) or the lipase from Bacillus strain A30-1 (Wang et al. 1995). Several Pseudomonas (Sugihara et al. 1992; Lee and Rhee 1993; Ahn et al. 1999) and Lactobacillus (Lopes Mde et al. 2002) species have also been reported to produce moderate thermoactive lipases.
Microorganisms living at temperatures above 70°C (extreme thermophiles), however, are an interesting source of stable enzymes (extremozymes). They are in general superior to the traditional biocatalysts, because they produce proteins with unique properties and show reasonable activity even at 100°C and in the presence of organic solvents and detergents (Antranikian 2008). Little, however, is known on the lipolytic enzyme systems of extreme thermophiles, especially from strictly anaerobic bacteria. Their enzymes are expected to be a powerful tool in industrial biotransformation processes (Coolbear et al. 1992; Lasa and Berenguer 1993; Haki and Rakshit 2003).
The ability of Thermosyntropha lipolytica gen. nov., sp. nov., to utilize short- and long-chain fatty acids was described (Svetlitshnyi et al. 1996) and the cloning, purification, and characterization of a thermostable esterase from Thermoanaerobacter tengcongensis was reported (Zhang et al. 2003). To our knowledge, however, there are no reports on detailed characteristics of lipases from extreme thermophilic anaerobic bacteria.
In this work, we report on the properties of novel recombinant thermostable lipases from the extreme thermophilic anaerobic bacteria Thermoanaerobacter thermohydrosulfuricus and Caldanaerobacter subterraneus subsp. tengcongensis (Royter 2006).
Materials and methods
Bacterial strains and plasmids
The strain DSM 7021 Thermoanaerobacter thermohydrosulfuricus (basonym: Clostridium thermohydrosulfuricum) SOL1 was isolated from a Solar Lake and belongs to the genus Thermoanaerobacter (Klingeberg et al. 1990; Lee et al. 1993).
Caldanaerobacter subterraneus subsp. tengcongensis (basonym: Thermoanaerobacter tengcongensis) was obtained from German Collection of Microorganisms and Cell Cultures (DSMZ) number DSM 15242, Braunschweig, Germany (Fardeau et al. 2004). The genome of C. subterraneus subsp. tengcongensis has been sequenced (Bao et al. 2002) (GenBank AE008691). The extremely thermophilic anaerobic bacterium, designated strain MB4T, was isolated from a Chinese hot spring in Tengcong (Xue et al. 2001).
The Escherichia coli strains used in DNA manipulations were: TOP-10 [F- mcrA Δ (mrr-hsdRMS-mcrBC) φ80lacZΔM15 ΔlacX74 recA1 deoR araD139 Δ (ara-leu)7697 galU galK rpsL (StrR) endA1 nupG] (Invitrogen), NovaBlue [endA1 hsdR17(rK12 – mK12 +) supE44 thi-1 recA1 gyrA96 relA1 lac F′[proA + B + lacIqZ ΔM15 ::Tn10(TcR)] (Novagen) and Tuner™(DE3)pLacI [F– ompT hsdSB(rB – mB –) gal dcm lacY1 (DE3) pLacI (CamR)] (Novagen). E. coli TOP-10 was used in combination with the cloning vector pCR 2.1-TOPO (Invitrogen) suitable for blue/white assays. E. coli Tuner™(DE3)pLacI and NovaBlue were used in combination with vector pETBlue-1 (Novagen) containing the T7 promoter to clone and express the lipase gene.
Media and culture conditions
The basal medium for cultivation of T. thermohydrosulfuricus and C. subterraneus subsp. tengcongensis was prepared by the modified Hungate technique (Balch and Wolfe 1976). Medium for cultivation of the thermophilic anaerobic strains contained (per liter): NaCl 3.0 g; KH2PO4 2.5 g; NaH2PO4 0.8 g; MgSO4·7H2O, 0.1 g; CaCl2·2H2O 0.05; FeCl3·6H2O 0.01 g; (NH4)2SO4 1.5 g; SrCl2·6H2O 0.03 g; H3BO3 0.03 g; Na2WO4 0.03 g; yeast extract 1.5 g; peptone 1.5 g; trace element solution (×10) [according to medium 141 (DSMZ 1998)] 1 ml; vitamin solution (×10) (according to medium 141) 1 ml; resazurin 0.001 g; NaHCO3 1.0 g; cysteine 0.3 g; pH 7.2.
Prior to inoculation, 1 mg Na2S·9H2O was added to 20 ml of medium and followed by the addition of 0.05 g Na2S2O3.
For lipase production, the thermophilic anaerobic strains were cultivated on a rotary shaker (160 rpm) for 32 h at 65°C in 50-ml bottles under anaerobic conditions containing 20 ml of the corresponding liquid medium. All E. coli strains were cultivated in Luria–Bertani medium [1% (w/v) tryptone, 0.5% (w/v) yeast extract, 1% (w/v) NaCl per liter of deionized water, pH 7.0] at 37°C. Carbenicillin, when added, was used at a final concentration of 50 μg/ml.
Recombinant DNA techniques
DNA manipulations were performed as described by Sambrook et al. (2001), unless otherwise stated. Restriction enzymes and other DNA-modifying enzymes were used according to the manufacturer’s (Fermentas International Inc, Canada) recommendations. Genomic DNA was extracted from T. thermohydrosulfuricus and C. subterraneus subsp. tengcongensis using Qiagen column technology (Ausubel et al. 1987). E coli cells were transformed by “heat shock” method. Small-scale purification of plasmid DNA was performed using Qiagen column technology (Birnboim and Doly 1979; Birnboim 1983; Kraft et al. 1988). DNA fragments were isolated from agarose gels using a QIAquick gel extraction kit (Qiagen, USA), according to the manufacturer’s instructions.
Sequencing and analysis of the genes
To determine the sequences of lipase gene of T. thermohydrosulfuricus, the PCR products and vectors with inserts were sequenced by SeqLab (Sequences Laboratories), Göttingen, Germany. The DNA and deduced amino acid sequences and chromatogram readouts were analyzed using the sequence analysis software VectorNTI and Chromas 1.45 (shareware).
Sequence and database similarity searches were done using the server at the National Center for Biotechnology Information, Bethesda, MD (http://www.ncbi.nlm.nih.gov). Analysis of the lipase genes was done with the Expasy Molecular Biology Server (http://www.expasy.org/tools). Sequence alignments were generated using ClustalW and Pairwise BLAST. Open reading frame analysis, translations, restriction mapping, polarity, hydrophobicity, and isoelectric point prediction were analyzed with the VectorNTI software (Infor-Max Inc., Oxford, UK).
Cloning and expression of the T. thermohydrosulfuricus and C. subterraneus subsp. tengcongensis lipase genes
The N-terminal sequence from T. thermohydrosulfuricus was compared with those of various known lipases from bacteria deposited in EMBL 29.0 and Swissprot 20.0 databases. On the basis of the best hits of the BLAST analysis, twelve various oligonucleotide primers were synthesized (Table 1a). Using these primers in all possible combinations, different internal fragments of the T. thermohydrosulfuricus DNA were amplified by PCR.
The PCR-products were sequenced and compared with other known hydrolase sequences. The DNA fragments identified as parts of hydrolase gene were completed using inverse-PCR techniques, in order to be able to express it actively in E. coli. The genomic DNA (~1.4 μg) was digested into small fragments with restriction enzymes BamHI and HindIII. The DNA-fragments were ligated and the circular DNA-fragments were used as templates for amplification of lipase fragments using specific primers (Table 1b).
The program ContigExpress™ (Vector NTI®, software package for Mac OS users developed by InforMax, Inc., North Bethesda, MD, USA) was used for analysis of the sequences and to complete the lipase gene.
AccepTor Vector Kit (Novagen) was used for IPTG-inducible expression of lipase genes in E. coli under the control of the T7lac promoter in pETBlue-1 vector. Purified genomic DNAs from T. thermohydrosulfuricus and C. subterraneus subsp. tengcongensis were used as templates for amplification of complete lipase genes. The primers used for amplification of the T. thermohadrosulfuricus lipase gene were LipTth-for (5′-ATGCAAAAGGCT-GTTGAAATTAC-3′) and LipTth-rev (5′-TTATCCCTTTAACAATTCCTTTTTG-3′). The C. subterraneus subsp. tengcongensis lipase gene was amplified using constructed primers LipCs-for (5′-ATGCAGAAGGCTGTAGAGTTTAC-3′) and LipCs-rev (5′-TTATCCCTT-TAATTCTCTTTCAAAG-3′).
In the expression phase of the experiment, the clone containing lipase gene in reverse orientation was used as a negative control. 5 ml of starter culture of the pETBlue-1 recombinant in an E. coli (DE3) pLacI expression host strain was grown in LB medium with 50 μg ml−1 of carbenicillin, 34 μg ml−1 of chloramphenicol and 1% glucose. 200 ml medium inoculated with starter culture was incubated to an OD595 of 0.9. The cells were induced with 1 mM isopropyl-ß-d-thiogalactopyranoside (IPTG), and cultures were incubated with shaking at 37°C for 4 h for full induction.
E. coli clone containing T. thermohydrosulfuricus lipase gene was cultivated in a 2-l fermentor (Bioengineering, Switzerland) with a working volume of 1.5 l for 6 h at 37°C, agitation at 1000 rpm and aeration (30 l h−1).
Lipase assay
Positive recombinant clones isolated from triolein plates were cultivated in Luria–Bertani medium and assayed for lipase activity after 24 h incubation.
Spectrophotometric assay with p-nitrophenyl palmitate as substrate
Cleavage of p-nitrophenyl palmitate (Sigma, USA) was determined at 70°C in 0.025 M Tris–HCl buffer, pH 8.0, according to Winkler and Stuckmann (1979). A buffered p-nitrophenyl palmitate emulsion was sonicated for 2 min at room temperature before the kinetic measurement was started by the addition of the enzyme. A blank absorption at 410 nm was measured immediately after enzyme addition. All values were determined in triplicates and corrected for autohydrolysis using an extinction coefficient of ε = 12750 M−1 cm−1. The activity toward other p-nitrophenyl esters was measured in the same manner, by using 1 mM of each substrate. One unit (1 U) of lipase activity is defined as the amount of enzyme needed to liberate 1 μmol of p-nitrophenol per minute at the conditions described above.
Spectrophotometric assay with olive oil as substrate
In order to determine pH optimum of the enzymes a modified assay was used (Schmidt-Dannert et al. 1994). The hydrolytic activity of the lipase was measured by the spectrophotometric assay at 430 nm using the formation of copper soaps for the detection of free fatty acids. Enzyme reaction was carried out under shaking for 90 min at 70°C. One unit (1 U) of lipase activity is defined as the amount of enzyme needed to liberate 1 μmol of free fatty acids per minute at the conditions described above.
Purification of recombinant lipases
After induction E. coli cells were harvested by centrifugation at 10000g at 4°C for 30 min. All purification procedures were performed at room temperature. After harvesting, the cells were washed twice with 50 mM Tris–HCl buffer pH 8.0, resuspended in 10 ml of this buffer and stored at −20°C for 1 h. After thawing, lysozyme was added at a concentration of 100 mg/ml and Triton-X 100–0.1%. The cells were incubated in the lysing reagents for 1 h on ice. DNAse was added to 100 mg/ml to one set and incubated at 37°C for 30 min. After centrifugation the cell free extract was heated at 60°C for 30 min. Proteins were precipitated and separated by centrifugation for 20 min at 10000g. NaCl was added to a concentration of 1 M, and 20 ml of this supernatant were loaded on a 35-ml phenyl sepharose high performance hydrophobic column (20.0 × 2.6 cm, packed with 60 ml 6F high substituted resin) (Pharmacia, Sweden) preequilibrated with 50 mM Tris–HCl buffer pH 8.0 containing 1 M NaCl. The protein was eluted with a linear reverse gradient from 1 to 0 M NaCl at a flow rate of 1 ml min−1. Lipase containing fractions were pooled and dialyzed against 3 l of standard buffer (pH 8.0). The protein solutions were concentrated by ultrafiltration through a 10-kDa cut-off membrane (Amicon). The samples were then fractionated on a HiLoad 16/60 Superdex 200 preparative grade column (160 × 16 cm) (Pharmacia, Sweden) preequilibrated with standard buffer (pH 8.0) containing 1% NaCl and 1% DMSO. The flow rate was adjusted to 1 ml/min. Protein fractions with lipase activity were collected and dialyzed against standard buffer (pH 8.0). The purified enzyme was stored at +4°C. Protein concentration was measured according the method of Bradford (1976). Bovine serum albumin was used as standard.
Gel electrophoresis
Protein samples were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) using 12% polyacrylamide resolving gel and a 4% polyacrylamide stacking gel according to the method of Laemmli (1970) after the samples had been heated at 95°C for 5 min. The low molecular markers (Amersham, UK) used were: phophorylase b (97 kDa), albumin (66 kDa), ovalbumin 45 kDa), carbonic anhydrase (830 kDa), trypsin inhibitor 20 kDa), a-lactalbumin (14.4 kDa). Proteins were visualized in the gels by staining with Coomassie brilliant blue R-250 (Sigma, USA). The zymogram staining with α-naphthyl acetate for lipolytic activity was performed according to the method of Khalameyzer et al. (1999). When activity staining was performed, the sample applied to the gel was not boiled, and after electrophoresis SDS was removed by washing the gel with 0.5% Triton X-100 for 20 min and with distilled water for 10 min.
Influence of pH and temperature
The lipase activity was measured at a pH range from 4.0 to 12.0 using various buffers (100 mM). All activity assays were performed at 70°C. To study the pH stability of the enzyme, the lipase was incubated for 1 and 2 h at 30°C in the following buffers (100 mM): acetic acid/sodium acetate (pH 4.0–5.5), potassium phosphate (pH 5.0–8.0), Tris/HCl (pH 7.5–9.0) and glycine/NaCl/NaOH (pH 9.0–13.0) without substrate. To determine the influence of the temperature on the enzymatic activity, samples were incubated at temperatures from 30 to 95°C for 15 min. Thermostability was investigated after incubation of the samples at different temperatures from 70 to 90°C and pH 8.0 at various time intervals.
Effect of various compounds on lipase activity
The effects of various substances (metal ions, inhibitors, organic solvents and surfactants) on lipase activity were examined using the spectrophotometric assay with p-nitrophenyl palmitate as substrate. The purified lipase was preincubated with various reagents in different concentrations at 30°C for 90 min without substrate, and residual lipase activity was measured using p-nitrophenyl palmitate.
Substrate range
The enzyme specificity was studied with p-nitrophenyl alkanoate esters of varying alkyl chain lengths from C2 to C18 compared with p-nitrophenyl palmitate as substrate. The reaction was carried out at 70°C for 15 min. The lipase specificity was tested toward the following triglycerides: triacetin (C2:0), tributyrin (C4:0), tricaproin (C6:0), tricaprylin (C8:0), tricaprin (C10:0), trilaurin (C12:0), trimyristin (C14:0), tripalmitin (C16:0), tristearin (C18:0), triolein (C18:1), compared with olive oil as substrate. Incubation was performed at 70°C for 24 h.
Further substrates tested were: p-nitrophenyl esters of the following: benzoate, 2-(4-isobutylphenyl) propanoate (ibuprofen), 2-phenylpropanoate, 3-phenylbutanoate, cyclohexanoate, 2-(3-benzoylphenyl) propanoate (ketoprofen), 2-naphthoate, 1-naphthoate, adamantanoate and 2-(6-methoxynaphthalene-2-yl) propanoate (naproxen). The reaction was carried out at 70°C for 40 min. The reaction mixture contained 950 μl of buffer (100 mM Tris–HCl, pH 7.5), 50 μl substrate (5 mg/ml in DMSO) and 0.3 μg of lipase. Activity was determined at 410 nm after 40 min of incubation at 75°C.
Determination of catalytic activity and enantioselectivity by GC analysis
The enantioselectivity of the lipase from T. thermohydrosulfuricus toward racemic compounds was studied with 8 substrates. 6 of them were acetates, one a butyrate of a secondary alcohol and one an acetate of a tertiary (3-phenyl-but-1-in-3-yl-acetate) alcohol. The general procedure for the preparation of the acetates 1–3 and 5–6 was already described (Musidlowska-Persson and Bornscheuer 2002; Schmidt et al. 2005). (R,S)-racemic substrates were dissolved in sodium phosphate buffer (50 mM, pH 7.5) giving 1 ml of a 10 mM solution. The solution was mixed by vortex for 2 min. The hydrolysis was carried out in 1.5-ml reaction vials in a thermomixer (Eppendorf) at 70°C. 0.1 U of the T. thermohydrosulfuricus lipase (based on the spectrophotometric p-NPP assay) was used for each reaction. The samples were taken after 2, 4, 16, 24, and 40 h. Reactions were terminated by extraction with methylene chloride and the organic phases were dried over anhydrous sodium sulfate. For the detection of enantiomeric purity and conversion, gas chromatography was used (gas chromatograph, GC-14A, Shimadzu). The following conditions were used for the GC analyses: injection temperature 200°C, detection temperature 200°C, column (Heptakis-(2,6-O-methyl-3-O-pentyl)-β-cyclodextrin, 25 m × 0.25 mm), carrier gas: H2, flame ionization detector (FID), temperature 110°C (isothermal) for 1-phenyl-1-ethyl acetate (1), 1-phenyl-2-pentyl acetate (2), 1-phenyl-2-butyl acetate (3), and 2-phenyl-but-1-in-3-yl acetate (4), column temperature 120°C (isothermal) for 1-phenyl-2-butyl acetate (5) and 1-phenyl-2-propyl acetate (6), column temperature 40°C (isothermal) for but-3-yn-2-ol acetate (7) and but-3-yn-2-ol butyrate (8) (Schmidt et al. 2006). The volume of the injected sample was 0.1 μl. With the help of the chromatogram the enantioselectivity (E) and conversion (c) were calculated according to Chen et al. (Schmidt et al. 2006).
Other esters (listed in Table 6) were incubated while the lipase from T. thermohydrosulfuricus in a mixture of 400 μl buffer (125 mM Tris–HCl, pH 7.5), 50 μl substrate (10 mg/ml in Acetonitrile) and 3 μg enzyme at 30°C. Sample were taken after 1 h, 24 h and 2 days (500 μl each), extracted with 300 μl dichloromethane and analyzed by GC. The regioisomers of pentan-1,4-diyl diacetate-hydrolysis were resolved using a DB-Wax column [Hewlett-Packard, Palo Alto, CA, USA, 30 m (length), 0.32 mm (diameter), 0.25 μm (film thickness)]. The relative activity was calculated on the basis of initial rates.
Results
Sequence analysis of lipases from T. thermohydrosulfuricus and C. subterraneus subsp. tengcongensis
Sequences of the N-terminal amino acid (17 amino acids) of the lipase from T. thermohydrosulfuricus indicated high identity to the sequences of the hydrolase from C. subterraneus subsp. tengcongensis (NP 623397.1). Based on these identities, the hydrolase sequence C. subterraneus subsp. tengcongensis was compared to in NCBI BLAST database. Highest identity was obtained to hydrolases from Clostridium acetobutylicum and Deinococcus radiodurans. 12 different oligonucleotide primers were synthesized and used to amplify the gene of T. thermohydrosulfuricus by PCR (Table 1a). The 142-bp fragment was amplified and had 84% identity to the nucleotide sequence of the hydrolase α/β superfamily from C. subterraneus subsp. tengcongensis (NP 623397.1). On the basis of this sequence, specific oligonucleotide primers were synthesized (Table 1b) to obtain the complete gene sequences of the lipase from T. thermohydrosulfuricus shown in Fig. 1. Nucleotide sequencing of this fragment revealed the presence of a unique open reading frame (ORF), starting at a putative ATG start codon and being 780-bp long. The lipase from T. thermohydrosulfuricus exhibits a low G + C content (36.15%). Preceeding the ATG start codon (6 bp upstream), a potential ribosome-binding site Shine-Dalgarno sequence (5′-GGAGG-3′) was found. The deduced protein encoded by the lipase from T. thermohydrosulfuricus is composed of 259 residues, with a predicted molecular mass of 29161 Da and a pI of 5.41. 35% of the amino acids are hydrophobic, 18% polar, 16% are acidic, and 13% are basic. The N-terminus of this protein contains no signal peptide (SignalP V3 program).
Cloning and expression of the T. thermohydrosulfuricus and C. subterraneus subsp. tengcongensis lipase genes
A 780-bp fragment containing the T. thermohydrosulfuricus lipase encoding gene (Fig. 1) and a 777-bp ORF (AE013133) encoding the C. subterraneus subsp. tengcongensis hydrolase (NP 623397.1) were amplified by PCR with specific primers (LipTth-for and LipTth-rev) and (LipCst-for and LipCst-rev), respectively (Royter 2006). Purified DNAs from T. thermohydrosulfuricus and C. subterraneus subsp. tengcongensis were used as template. T. thermohydrosulfuricus lipase encoding gene containing the ATG start codon was amplified without modification. A GTG start codon in the C. subterraneus subsp. tengcongensis hydrolase encoding gene, however, was replaced with the E. coli-specific ATG start codon at the 5′ end using special constructed primers. The purified PCR products with single 3′-dA overhangs were ligated into containing T7lac promoter linearized expression vector pETBlue-1 (Novagen, USA) designed for IPTG-inducible expression of target genes.
For initial expression studies in E. coli, plasmids pETBlue-1 containing complete lipase genes were constructed and transformed into the expression host strains Tuner™(DE3)pLacI. Expression was induced by the addition of Isopropyl-β-d-thiogalactopyranoside (IPTG) when the culture had attained late log phase (OD600 = 0.9). The expression was optimized by testing various IPTG concentrations (0.4, 0.6, 0.8, 1.0, 1.5, and 2 mM). A halo around the colonies with lipase activity was observed on tributyrin plates. Expression levels were measured by SDS-PAGE (data not shown). Lipase activities were tested in cell-free supernatant and in cell lysate with p-nitrophenyl palmitate as substrate. The best expression (53–59 U/l) was achieved with 1 mM IPTG for 4 h. The enzyme level increased dramatically when cultivation was performed in a 2-l fermentor at the optimal process parameters. The production of the recombinant lipase of T. thermohydrosulfuricus by E. coli Tuner (DE3) was increased 42-fold (from 53 to 2200 U/l).
Purification of recombinant lipases
The recombinant lipases were purified by employing a three-step procedure: heat precipitation of cell free extract, hydrophobic interaction chromatography and gel filtration (Table 2). On phenyl sepharose column the enzymes were eluted at NaCl concentration between 0.90 and 0.95 M. The final gel filtration resulted in one peak of the active protein and in electrophoretically homogeneous preparations. The T. thermohydrosulfuricus lipase was purified 108.7-fold with 13% recovery and C. subterraneus subsp. tengcongensis lipase 93.6-fold with 8.1% recovery. The specific activity of the recombinant enzymes ranged from 10.90 to 12.15 U/mg. The purified enzymes showed on SDS-PAGE single bands with molecular weight of 34.2 kDa for T. thermohydrosulfuricus and 32.1 kDa for C. subterraneus subsp. tengcongensis (Fig. 2).
Physicochemical properties
The purified recombinant lipases exhibited maximum activity at a temperature of 75°C (Fig. 3) at pH 8.0. Both lipases were stable without significant loss of activity for 24-h incubation at temperatures up to 70°C (Fig. 4). After incubation at 85°C for 50 min, 90% of the lipase activity of T. thermohydrosulfuricus was measured.
The enzyme from C. subterraneus subsp. tengcongensis is less thermostable so that after 10-min incubation at 85°C, around 20% of residual activity was detected. The half-lives of the T. thermohydrosulfuricus lipase at 90°C is 50 min and of the C. subterraneus subsp. tengcongensis is 6 min. The lipases were stable to freezing (−20°C) and thawing. After first cycle of freezing and thawing, the enzymes showed 90% of residual activity and after second cycle the remaining activity was 85%.
The purified T. thermohydrosulfuricus lipase is active over a broad range of pH and showed maximum activity at pH 8.0 and above 80% of activity at pH of 6.5 and 9.0 (Fig. 5). The C. subterraneus subsp. tengcongensis lipase showed an optimum activity at pH 7.0 and above 60% of activity at pH 6.5 and 9.0 (Fig. 5). The enzymes were completely stable in a pH range between 7.5 and 12 for 2 h.
Effects of different reagents
The effect of various compounds is shown in Table 3. The following metal ions up to 10 mM did not have any influence on the enzymes: Na+, K+, Ca2+, Cu2+, Ag+, Mg2+, Mn2+, Sr2+, Rb+, Co2+, Ni2+, and Al3+. In contrast, Zn2+, Fe3+, and Cr3+ ions were inhibitory. CHAPS (3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid) has a slight activating effect on both enzymes. A decrease in enzyme activity was observed after incubation with Tween-20, Tween-80, Triton X-100 or SDS. The two lipases showed high activity in the presence of various solvents such as tert-butanol, acetonitrile, isopropanol, pyridine, and acetone up to a concentration of 99% (v/v). In contrast, DMSO (dimethyl sulfoxide), benzene, toluol, amylalcohol, and methanol at a concentration of 99% (v/v) caused a significant reduction in enzyme activity (Table 3).
β-Mercaptoethanol, DTT (dithiotreitol), guanidine hydrochloride, Urea, pHMB (p-hydroxymercuribenzoate), and iodo-acetate showed no effect. From the deduced amino acid sequences, it was suggested that these lipases harbor a catalytic triad consisting of Ser, His, and Asp, and accordingly they were inhibited by PMSF (phenylmethylsulfonyl fluoride) and pefablock (4-(2-aminoethyl)-benzenesulfonyl fluoride hydrochloride) (Table 3).
Substrate specificity
The recombinant lipases were active on a wide range of substrates. First, the specificity of the enzymes toward the length of different acyl chains of p-nitrophenyl esters was investigated (Table 4a). The enzymes were active on p-nitrophenyl esters of carboxylic acids of medium chain length (C6–C14). For both enzymes, p-nitrophenyl caprate (C10) was the most suitable substrate among the p-nitrophenyl esters examined. Both lipases exhibited very low levels of activity (<10%) toward the short- (C2) and long-chain (C18) substrates. The lipases from T. thermohydrosulfuricus and from C. subterraneus subsp. tengcongensis were able to hydrolyze further p-nitrophenyl ester substrates (Table 4b). Neither enzyme was able to hydrolyze p-nitrophenyl 2-naphthoate. Unlike the enzyme from C. subterraneus subsp. tengcongensis the lipase from T. thermohydrosulfuricus was active toward 4-nitrophenol cyclohexanoate but not with p-nitrophenyl-1-naphthoate or p-nitrophenyl adamantanoate. Accordingly, the described lipases displayed different substrate spectra (Table 4b).
Both lipases showed high activities in the presence of the triacylglycerols with chain lengths of C6 and C8 (80 and 100%) and lower activity with C16 (30%) (Table 4c).
Enantioselectivity
In order to determine the stereoselectivity of the thermoactive lipase from T. thermohydrosulfuricus, the substrates shown in Table 5 were investigated. With (R,S)-but-3-yn-2-ol butyrate and (R,S)-but-3-yn-2-ol acetate, the lipase showd (S)-preference and catalyzed the synthesis of the building block (–)-but-3-yn-2-ol. After 2-h incubation, the enzyme exhibited the highest enantioselectivity and an E value of 21 toward the butyrate was determined.
As shown in Table 5 the increase in conversion rate was accompanied with a decrease in the E value. The T. thermohydrosulfuricus lipase showed higher preference to (S)-enantiomers; but over time, their ability to distinguish between the two enantiomers decreased. For two other substrates, 1-phenyl-2-propyl-acetate and 1-phenyl-1-ethyl-acetate, the enantioselectivities of the enzyme where very low (E ≥ 1) but constant over time.
Furthermore, a broad range of esters was tested, and it was found that the lipase from T. thermohydrosulfuricus converted preferentially esters of secondary alcohols rather than esters of primary alcohols (Table 6).
Discussion
Microorganisms that thrive in extreme habitats especially at elevated temperatures (70–100°C) are able to produce thermoactive enzymes that in general show high catalytic activity at the optimal growth conditions. Few moderate thermophilic strains (50–60°C), especially representatives of the genus Bacillus, are able to produce extracellular enzymes, e.g., proteases that are even active at temperatures above their growth optimum (Schmidt-Dannert et al. 1994, 1997; Kambourova et al. 1996; Lee et al. 1999; Markossian et al. 2000; Nawani and Kaur 2000). Regarding lipases, however, there are few reports on the production of such enzymes by extreme thermophilic microorganisms (70–80°C), especially strict anaerobes. The thermophilic bacterium Thermosyntropha lipolytica gen. nov., sp. nov., is able to utilize short- and long-chain fatty acids indicating its ability to produce lipase (Svetlitshnyi et al. 1996). The thermophilic bacterium T. tengcongensis produces an esterase, which is inactive toward olive oil and shows very low activity toward long chain p-NP esters (C16) (Zhang et al. 2003). The analysis of the robust lipolytic enzyme systems from extreme thermophiles allows a comparative analysis of these enzymes with enzymes from their mesophilic and phsychrophilic counterparts. Comparison of the gene sequences of the heat stable lipases indicate very low identity to already known sequences. The lipase gene from Thermoanaerobacter thermohydrosulfuricus has 19% identity with the lipase 3 from the human pathogen Mycoplasma pneumoniae (PIR accession number S73694), 17% with the lipase 3 from the psychotropic strain Moraxella sp. TA144 (PIR accession number S14276) and 16% with the lipase 1 from the psychrophilic strain Psychrobacter immobilis (PIR accession number S57275). Therefore, it is speculative to make any predictions regarding structure–function relationships of enzymes from various groups. However, it was interesting to note that both the studied lipases lack signal peptides that are usually present in enzymes that are secreted by bacteria. It can be speculated that probably another mechanism for enzyme secretion is present in these extremophiles or the signal peptide could not be identified by SignalP V3 program.
Analysis of the deduced amino acid sequence of newly described lipases indicated that these enzymes belong to family V of lipolytic enzymes, described by Agripny and Jaeger (1999). In spite of the low identity, the four conserved regions shown in Fig. 6 are present: the HGF block containing the hydrophobic stretch in front of the lid putative oxyanion hole, the SMGG block containing the putative active-site serine, the G(DK)D block containing the putative active-site aspartic acid, and the GH block with the putative active-site histidine. The enzymes grouped in family V so far originate from mesophilic bacteria (Pseudomonas oleovorans, Haemophilus influenzae, Acetobacter pasteurianus) as well as from cold-adapted bacteria (Moraxella sp., Psy. immobilis) and from the thermoacidophilic archaeon Sulfolobus acidocaldarius (Arpigny and Jaeger 1999). Interestingly, the lid region of the thermostable described lipases contains no tryptophane (W) residue, which is usually located in close contact with the active-site serine (Woolley and Petersen 1994).
Comparison of the 3D structure of lipases from psychrophiles, mesophiles and thermophiles indicates that these enzymes have the same catalytic mechanism with a similar 3D architecture (Vieille and Zeikus 2001). Due to the high sensitivity of cysteine to oxidation at elevated temperatures, its content seems to be reduced in thermoactive enzymes. Both lipases have no cysteines.
The lipase from T. thermohydrosulfuricus shows also enantioselectivity in the kinetic resolution of various racemic esters of secondary and tertiary alcohols (Table 5). Several biotransformations using lipases are already performed on an industrial scale (Bornscheuer and Kazlauskas 1999; Bornscheuer et al. 2000), but novel enzymes with high selectivity in combination with high stability under process condition are still needed. The majority of compounds investigated so far are secondary alcohols, because most hydrolases show sufficient enantioselectivity toward these compounds (Theil 1997) and they are important chiral modules for organic synthesis (Bornscheuer and Kazlauskas 1999). Lipase LipTth shows moderate S-enantioselectivity toward (R,S)-but-3-yn-2-ol, which is an important building block (Lesot et al. 1997; Graner et al. 2001; Cappelli et al. 2002; Schmidt et al. 2006). Furthermore, the lipase from T. thermohydrosulfuricus is able to convert other industrially relevant substrates. Interestingly, the enzyme shows a high preference for esters of secondary alcohols and a high selectivity for (R) enantiomers of pharmaceutically important substrates as well as C. antarctica lipase B (CALB) (Orrenius et al. 1995), Alcaligenes QL (Naemura et al. 1996), C. rugosa and P. cepacia lipases (PCLs) (Kazlauskas et al. 1991). It is highly enantioselective for (R,S)-octan-2-yl acetate, (R,S)-octan-3-yl acetate and (R,S)-1-(2-naphthyl)-ethyl acetate with E value >200. The E value for (R,S)-1-cyclohexylethyl acetate was also synthetically useful with E = 110. The enzyme prefers (R)-enantiomers of chiral alcohols according to the Kazlauskas-rule (Lesot et al. 1997; Graner et al. 2001; Cappelli et al. 2002; Schmidt et al. 2006).
The finding that the investigated lipases are active at elevated temperatures and high pH (90°C, pH 11), in addition to their resistance against organic solvents (up to 99%) makes these enzymes very attractive for biotransformation processes in water-free media (Jaeger et al. 1994; Kirk et al. 2002; Bommarius and Riebel 2004).
In summary, we were able to identify, clone and functionally express two novel lipases showing very high thermoactivity and stability. Moreover, both enzymes accept a very broad range of esters in hydrolysis and show good to excellent stereoselectivities in the kinetic resolution of a broad set of synthetically useful compounds important in organic synthesis.
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We acknowledge the financial support by the German Environmental Foundation (DBU), Osnabrück, Germany.
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Royter, M., Schmidt, M., Elend, C. et al. Thermostable lipases from the extreme thermophilic anaerobic bacteria Thermoanaerobacter thermohydrosulfuricus SOL1 and Caldanaerobacter subterraneus subsp. tengcongensis . Extremophiles 13, 769–783 (2009). https://doi.org/10.1007/s00792-009-0265-z
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DOI: https://doi.org/10.1007/s00792-009-0265-z