Cloning and Expression of <Emphasis Type="Italic">lipP</Emphasis>, A Gene Encoding a Cold-Adapted Lipase from <Emphasis Type="Italic">Moritella</Emphasis> sp.2-5-10-1

A gene (lipP, 837 bp in length) coding for a cold-adapted lipase of psychrophilic bacterium Moritella sp. 2-5-10-1 isolated from Antarctic region was cloned and sequenced in this study. The deduced amino acid sequence revealed a protein of 278 amino acid residues with a molecular mass of 30,521. The primary structure of the lipase deduced from the nucleotide sequence showed consensus pentapeptide containing the active serine [Gly-Trp-Ser-Leu-Gly] and a conserved His-Gly dipeptide in the N-terminal part of the enzyme. These sequences were involved in the lipase active site conformation. Structure factors that would allow proper enzyme flexibility at low temperatures were discussed. It was suggested that the changes in the primary structure of the psychrophilic lipases compared to the thermophilic ones could account for their ability to catalyze lipolysis at temperatures close to 0°C. For expression, the sequence corresponding to the cold-adapted lipase of strain 2-5-10-1 was subcloned into the pET-28a expression vector to construct a recombinant lipase protein. Expression of the lipase by Escherichia coli BL21 (DE3) cells was observed as clear halos on 1% (vol/vol) tributyrin upon induction with IPTG at 25°C.     

Production of extracellular lipases by Penicillium cyclopium purification and characterization of a partial acylglycerol lipase

Penicillium cyclopium, grown in stationary culture, produces a type I lipase specific for triacylglycerols while, in shaken culture, it produces a type II lipase only active on partial acylglycerols. Lipase II has been purified by ammonium sulfate precipitation and chromatographies on Sephadex G-75 and DEAE-Sephadex. The enzyme exists in several glycosylated forms of 40-43 kDa, which can be converted to a single protein of 37 kDa by enzymatic deglycosylation. Activity of lipase II is maximal at pH 7.0 and 40 degrees C. The enzyme is stable from pH 4.5 to 7.0. Activity is rapidly lost at temperatures above 50 degrees C. The enzyme specifically hydrolyzes monoacylglycerols and diacylglycerols, especially of medium chain fatty acids. The sequence of the 20 first amino acid residues is similar to the N-terminal region of P. camembertii lipase and partially similar to lipases from Humicola lanuginosa and Aspergillus oryzae, but is different from Penicillium cyclopium lipase I. However, it can be observed that residues of valine and serine at positions 2 and 5 in Penicillium cyclopium lipase II are conserved in Penicillium expansum lipase, of which 16 out of the 20 first amino acid residues are similar to Penicillium cyclopium lipase I.     

Structural and functional roles of highly conserved serines in human lipoprotein lipase. Evidence that serine 132 is essential for enzyme catalysis

The structure of human lipoprotein lipase was recently deduced from its cDNA sequence. It contains 8 serine residues (residues 45, 132, 143, 172, 193, 244, 251, and 363) that are absolutely conserved in both lipoprotein lipase and hepatic lipase across all species studied. The high homology between lipoprotein lipase, hepatic lipase, and pancreatic lipase suggests that the catalytic functions of these enzymes share a common mechanism and that one of the 8 conserved serines in human lipoprotein lipase must play a catalytic role as does serine 152 in the case of pancreatic lipase (Winkler, F. K., D'Arcy, A., and Hunziker, W. Nature 343, 771-774). We expressed wild-type and site-specific mutants of human lipoprotein lipase in COS cells in vitro. We produced two to four substitution mutants involving each of the 8 serines and assayed a total of 22 mutants for both enzyme activity and the amount of immunoreactive enzyme mass produced. Immunoreactive lipase was detected in all cases. With the exception of Ser132, for each of the 8 serine mutants we studied, at least one of several mutants at each position showed detectable enzyme activity. All three substitution mutants at Ser132, Ser----Thr, Ser----Ala, and Ser----Asp, were totally inactive. Ser132 occurs in the consensus sequence Gly-Xaa-Ser-Xaa-Gly present in all serine proteinases and in human pancreatic lipase. The x-ray crystallography structure of human pancreatic lipase suggests that the analogous serine residue in human pancreatic lipase, Ser152, is the nucleophilic residue essential for catalysis. Our biochemical data strongly support the conclusion that Ser132 in human lipoprotein lipase is the crucial residue required for enzyme catalysis. The observed specific activities of the variants involving the other seven highly conserved serines in human lipoprotein lipase are consistent with the interpretation that this enzyme has a three-dimensional structure very similar to that of human pancreatic lipase.     

Cloning and expression of cDNA encoding human lysosomal acid lipase/cholesteryl ester hydrolase. Similarities to gastric and lingual lipases.

Molecular cloning of a full-length cDNA for human lysosomal acid lipase/cholesteryl ester hydrolase (EC 3.1.1.13) reveals that it is structurally related to previously described enteric acid lipases, but lacks significant homology with any characterized neutral lipases. The lysosomal enzyme catalyzes the deacylation of triacylglyceryl and cholesteryl ester core lipids of endocytosed low density lipoproteins; this activity is deficient in patients with Wolman disease and cholesteryl ester storage disease. Its amino acid sequence, as deduced from the 2.6-kilobase cDNA nucleotide sequence, is 58 and 57% identical to those of human gastric lipase and rat lingual lipase, respectively, both of which are involved in the preduodenal breakdown of ingested triglycerides. Notable differences in the primary structure of the lysosomal lipase that may account for discrete catalytic and transport properties include the presence of 3 new cysteine residues, in addition to the 3 that are conserved in this lipase gene family, and of two additional potential N-linked glycosylation sites. Transfection of the cDNA into Cos-1 cells resulted in the expression of acid lipase activity with the substrate range of the native enzyme at a level that was greater than 40 times the endogenous activity.     

Analysis of Comparative Sequence and Genomic Data to Verify Phylogenetic Relationship and Explore a New Subfamily of Bacterial Lipases

Thermostable and organic solvent-tolerant enzymes have significant potential in a wide range of synthetic reactions in industry due to their inherent stability at high temperatures and their ability to endure harsh organic solvents. In this study, a novel gene encoding a true lipase was isolated by construction of a genomic DNA library of thermophilic Aneurinibacillus thermoaerophilus strain HZ into Escherichia coli plasmid vector. Sequence analysis revealed that HZ lipase had 62% identity to putative lipase from Bacillus pseudomycoides. The closely characterized lipases to the HZ lipase gene are from thermostable Bacillus and Geobacillus lipases belonging to the subfamily I.5 with ≤ 57% identity. The amino acid sequence analysis of HZ lipase determined a conserved pentapeptide containing the active serine, GHSMG and a Ca²⁺-binding motif, GCYGSD in the enzyme. Protein structure modeling showed that HZ lipase consisted of an α/β hydrolase fold and a lid domain. Protein sequence alignment, conserved regions analysis, clustal distance matrix and amino acid composition illustrated differences between HZ lipase and other thermostable lipases. Phylogenetic analysis revealed that this lipase represented a new subfamily of family I of bacterial true lipases, classified as family I.9. The HZ lipase was expressed under promoter P_lac using IPTG and was characterized. The recombinant enzyme showed optimal activity at 65°C and retained ≥ 97% activity after incubation at 50°C for 1h. The HZ lipase was stable in various polar and non-polar organic solvents.     

Functional topology of a surface loop shielding the catalytic center in lipoprotein lipase.

Lipoprotein lipase (LPL), hepatic lipase, and pancreatic lipase show high sequence homology to one another. The crystal structure of pancreatic lipase suggests that it contains a trypsin-like Asp-His-Ser catalytic triad at the active center, which is shielded by a disulfide bridge-bounded surface loop that must be repositioned before the substrate can gain access to the catalytic residues. By sequence alignment, the homologous catalytic triad in LPL corresponds to Asp156-His241-Ser132, absolutely conserved residues, and the homologous surface loop to residues 217-238, a poorly conserved region. To verify these assignments, we expressed in vitro wild-type LPL and mutant LPLs having single amino acid mutations involving residue Asp156 (to His, Ser, Asn, Ala, Glu, or Gly), His241 (to Asn, Ala, Arg, Gln, or Trp), or Ser132 (to Gly, Ala, Thu, or Asp) individually. All 15 mutant LPLs were totally devoid of enzyme activity, while wild-type LPL and other mutant LPLs containing substitutions in other positions were fully active. We further replaced the 22-residue LPL loop which shields the catalytic center either partially (replacing 6 of 22 residues) or completely with the corresponding hepatic lipase loop. The partial loop-replacement chimeric LPL was found to be fully active, and the complete loop-replacement mutant had approximately 60% activity, although the primary sequence of the hepatic lipase loop is quite different. In contrast, replacement with the pancreatic lipase loop completely inactivated the enzyme. Our results are consistent with Asp156-His241-Ser132 being the catalytic triad in lipoprotein lipase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cloning of the Pseudomonas glumae lipase gene and determination of the active site residues.

The lipA gene encoding the extracellular lipase produced by Pseudomonas glumae PG1 was cloned and characterized. A sequence analysis revealed an open reading frame of 358 codons encoding the mature lipase (319 amino acids) preceded by a rather long signal sequence of 39 amino acids. As a first step in structure-function analysis, we determined the Ser-Asp-His triad which makes up the catalytic site of this lipase. On the basis of primary sequence homology with other known Pseudomonas lipases, a number of putative active site residues located in conserved areas were found. To determine the residues actually involved in catalysis, we constructed a number of substitution mutants for conserved Ser, Asp, and His residues. These mutant lipases were produced by using P. glumae PG3, from which the wild-type lipase gene was deleted by gene replacement. By following this approach, we showed that Ser-87, Asp-241, and His-285 make up the catalytic triad of the P. glumae lipase. This knowledge, together with information on the catalytic mechanism and on the three-dimensional structure, should facilitate the selection of specific modifications for tailoring this lipase for specific industrial applications.     

Role of the calcium ion and the disulfide bond in the Burkholderia glumae lipase

The role of the Ca²⁺ ion that is present in the structure of Burkholderia glumae lipase was investigated. Previously, we demonstrated that the denatured lipase could be refolded in vitro into an active enzyme in the absence of calcium. Thus, an essential role for the ion in catalytic activity or in protein folding can be excluded. Therefore, a possible role of the Ca²⁺ ion in stabilizing the enzyme was considered. Chelation of the Ca²⁺ ion by EDTA severely reduced the enzyme activity and increased its protease sensitivity, however, only at elevated temperatures. Furthermore, EDTA induced unfolding of the lipase in the presence of urea. From these results, it appeared that the Ca²⁺ ion in B. glumae lipase fulfils a structural role by stabilizing the enzyme under denaturing conditions. In contrast, calcium appears to play an additional role in the Pseudomonas aeruginosa lipase, since, unlike B. glumae lipase, in vitro refolding of this enzyme was strictly dependent on calcium. Besides the role of the Ca²⁺ ion, also the role of the disulfide bond in B. glumae lipase was studied. Incubation of the native enzyme with dithiothreitol reduced the enzyme activity and increased its protease sensitivity at elevated temperatures. Therefore, the disulfide bond, like calcium, appears to stabilize the enzyme under detrimental conditions.     

Cloning and sequencing of the triacylglycerol lipase gene of Aspergillus oryzae and its expression in Escherichia coli

Aspergillus oryzae produces at least three extracellular lipolytic enzymes, L1, L2 and L3 (cutinase, mono- and diacylglycerol lipase, and triacylglycerol lipase, respectively). We cloned the triacylglycerol lipase gene (provisionally designated tglA) by screening a genomic library using a PCR product obtained with two degenerate oligonucleotide primers corresponding to amino acid sequences of L3 as probes. Nucleotide sequencing of the genomic DNA and cDNA revealed that the L3 gene (tglA) has an open reading frame comprising 954 nucleotides, which contains three introns of 47, 83 and 62 bp. The deduced amino acid sequence of the tglA gene corresponds to 254 amino acid residues including a signal sequence of 30 amino acids and, in spite of the difference in substrate specificity, it is homologous to those of cutinases from fungi. Three residues presumed to form the catalytic triad, Ser, Asp and His, are conserved. The cloned cDNA of the tglA gene was expressed in Escherichia coli, and enzyme assaying and zymography revealed that the cloned cDNA encodes a functional triacylglycerol lipase.     

Cloning of the Pseudomonas glumae lipase gene and determination of the active site residues.

The lipA gene encoding the extracellular lipase produced by Pseudomonas glumae PG1 was cloned and characterized. A sequence analysis revealed an open reading frame of 358 codons encoding the mature lipase (319 amino acids) preceded by a rather long signal sequence of 39 amino acids. As a first step in structure-function analysis, we determined the Ser-Asp-His triad which makes up the catalytic site of this lipase. On the basis of primary sequence homology with other known Pseudomonas lipases, a number of putative active site residues located in conserved areas were found. To determine the residues actually involved in catalysis, we constructed a number of substitution mutants for conserved Ser, Asp, and His residues. These mutant lipases were produced by using P. glumae PG3, from which the wild-type lipase gene was deleted by gene replacement. By following this approach, we showed that Ser-87, Asp-241, and His-285 make up the catalytic triad of the P. glumae lipase. This knowledge, together with information on the catalytic mechanism and on the three-dimensional structure, should facilitate the selection of specific modifications for tailoring this lipase for specific industrial applications.     

The lid is a structural and functional determinant of lipase activity and selectivity

In several lipases access to the enzyme active site is regulated by the position of a mobile structure named the lid. The role of this region in modulating lipase function is reviewed in this paper analysing the results obtained with three different recombinant lipases modified in the lid sequence: Candida rugosa lipase isoform 1 (CRL1), Pseudomonas fragi lipase (PFL) and Bacillus subtilis lipase A (BSLA). A CRL chimera enzyme obtained by replacing its lid with that of another C. rugosa lipase isoform (CRL1LID3) was found to be affected in both activity and enantioselectivity in organic solvent. Variants of the PFL protein in which three polar lid residues were replaced with amino acids strictly conserved in homologous lipases displayed altered chain length preference profile and increased thermostability. On the other hand, insertion of lid structures from structurally homologous enzymes into BSLA, a lipase that naturally does not possess such a lid structure, caused a reduction in the enzyme activity and an altered substrate specificity. These results strongly support the concept that the lid plays an important role in modulating not only activity but also specifity, enantioselectivity and stability of lipase enzymes.     

Secretion of mono- and diacylglycerol lipase from Penicillium camembertii U-150 by Saccharomyces cerevisiae and site-directed mutagenesis of the putative catalytic sites of the lipase.

Yeast cells carrying intronless mono- and diacylglycerol lipase (MDGL) genes, constructed by recombination of the genomic gene and cDNA, secreted MDGL into the culture supernatant. Most of the yeast MDGL were extensively glycosylated while they had a similar glyceride specificity to that of native MDGL. Site-directed mutagenesis was used to directly confirm the involvements in enzyme activity of the presumptive amino acid residues to form the catalytic center of MDGL. These residues were conserved in the primary structure alignment of a lipase family from filamentous fungi. Mutant lipase proteins in which Ser83, Ser145, or His259 was replaced with glycine were secreted by yeast transformants as inactive proteins. Mutant proteins replacing Asp199 with glycine or asparagine were not detected in the culture supernatant. Replacing other two highly conserved aspartic acids (at positions 232 and 243) with glycine did not render the enzyme inactive. These results indicate that Ser83, Ser145, and His259 in MDGL, are essential to enzyme activity. Asp199 is also likely to be involved.     

Binding of hepatic lipase to heparin. Identification of specific heparin-binding residues in two distinct positive charge clusters

The interaction of hepatic lipase (HL) with heparan sulfate is critical to the function of this enzyme. The primary amino acid sequence of HL was compared to that of lipoprotein lipase (LPL), a related enzyme that possesses several putative heparin-binding domains. Of the three putative heparin-binding clusters of LPL (J. Biol. Chem. 1994. 269: 4626-4633; J. Lipid Res. 1998. 39: 1310-1315), one was conserved in HL (Cluster 1; residues Lys 297-Arg 300 in rat HL) and two were partially conserved (Cluster 2; residues Asp 307-Phe 320, and Cluster 4; residues Lys 337, and Thr 432-Arg 443). Mutants of HL were generated in which potential heparin-binding residues within Clusters 1 and 4 were changed to Asn. Two chimeras in which the LPL heparin-binding sequences of Clusters 2 and 4 were substituted for the analogous HL sequences were also constructed. These mutants were expressed in Chinese hamster ovary (CHO) cells and assayed for heparin-binding ability using heparin-Sepharose chromatography and a CHO cell-binding assay. The results suggest that residues within the homologous Cluster 1 region (Lys 297, Lys 298, and Arg 300), as well as some residues in the partially conserved Cluster 4 region (Lys 337, Lys 436, and Arg 443), are involved in the heparin binding of hepatic lipase. In the cell-binding assay, heparan sulfate-binding affinity equal to that of LPL was seen for the RHL chimera mutant that possessed the Cluster 4 sequence of LPL. Mutation of Cluster 1 residues of HL resulted in a major reduction in heparin binding ability as seen in both the cell-binding assay and the heparin-Sepharose elution profile. These results suggest that Cluster 1, the N-terminal heparin-binding domain, is of primary significance in RHL. This is different for LPL: mutations in the C-terminal binding domain (Cluster 4) cause a more significant shift in the salt required for elution from heparin-Sepharose than mutations in the N-terminal domain (Cluster 1).     

Identification of essential residues for catalysis of rat intestinal phospholipase B/lipase

Intestinal brush border membrane-associated phospholipase B/lipase (PLB/LIP) consists of four tandem homologous domains (repeats 1 through 4) and a COOH-terminal membrane binding domain, and repeat 2 is the catalytic domain that catalyzes phospholipase A2, lysophospholipase, and lipase activities. We examined the structural basis of the catalysis of PLB/LIP with this unique substrate specificity by site-directed mutagenesis of recombinant repeat 2 enzyme. Ser414 and Ser459 within the active serine-containing consensus sequence G-X-S-X-G in the best-established lipase family were dispensable for activity. In contrast, substitution of Ala for Ser404 almost completely inactivated the three lipolytic activities of PLB/LIP, even though the gross conformation was not altered as determined by CD spectroscopy. Notably, this Ser is located within the conserved G-D-S-L sequence on the NH2-terminal side in lipolytic enzymes of another group proposed recently. Furthermore, mutagenesis and CD spectroscopic analyses suggested that Asp518 and His659, lying within conserved short stretches in the latter group of lipolytic enzymes, were essential for activity. These three essential residues are conserved in the known PLB/LIP enzymes, suggesting that they form the catalytic triad in the active site. These results indicate that PLB/LIP represents a distinct class of the lipase family. PLB/LIP is the first mammalian member of that family. Repeat 2 is equipped with the triad, but not the other repeats, accounting for why only repeat 2 is the catalytic domain. Replacing Thr406 with Gly, matching the enzyme's sequence to the lipase consensus sequence exactly, led to a great decrease in secretion and accumulation of inactive enzyme in the cells, suggesting a role of Thr406 in the structural stability.     

In silico and empirical approaches toward understanding the structural adaptation of the alkaline-stable lipase KV1 from Acinetobacter haemolyticus

Interests in Acinetobacter haemolyticus lipases are showing an increasing trend concomitant with growth of the enzyme industry and the widening search for novel enzymes and applications. Here, we present a structural model that reveals the key catalytic residues of lipase KV1 from A. haemolyticus. Homology modeling of the lipase structure was based on the structure of a carboxylesterase from the archaeon Archaeoglobus fulgidus as the template, which has a sequence that is 58% identical to that of lipase KV1. The lipase KV1 model is comprised of a single compact domain consisting of seven parallel and one anti-parallel β-strand surrounded by nine α-helices. Three structurally conserved active-site residues, Ser165, Asp259, and His289, and a tunnel through which substrates access the binding site were identified. Docking of the substrates tributyrin and palmitic acid into the pH 8 modeled lipase KV1 active sites revealed an aromatic platform responsible for the substrate recognition and preference toward tributyrin. The resulting binding modes from the docking simulation correlated well with the experimentally determined hydrolysis pattern, for which pH 8 and tributyrin being the optimum pH and preferred substrate. The results reported herein provide useful insights into future structure-based tailoring of lipase KV1 to modulate its catalytic activity.     

Separation and characterization of two molecular forms of Geotrichum candidum lipase

Southern blot analysis of the Geotrichum candidum genome with a cloned lipase cDNA as the probe indicated the existence of two genes on the chromosome of the fungus which are homologous to the cDNA. As expected, two forms of lipase (lipases I and II) were actually isolated by hydrophobic interaction chromatography after a multistep procedure including ammonium sulfate fractionation, anion exchange chromatography, and gel filtration of the culture filtrate. Lipase I, the first eluted fraction, was the predominant form, and more than 80% of the total activity was attributed to this form. Amino acid sequence analysis of the amino and carboxyl termini of these two enzyme preparations indicated that lipase I was the product of the lipase gene whose cDNA had previously been cloned and sequenced [Shimada et al. (1989) J. Biochem. 106, 383-388]. Lipase II, on the other hand, had similar amino acid composition, but different terminal sequences which were not found in the primary structure of lipase I deduced from the cDNA sequence. These results gave lines of evidence for the expression of truely different lipase genes and ruled out the possibility that the observed multiple forms are caused by proteolytic digestion. The molecular mass estimated by SDS-PAGE and the isoelectric point of lipase I were 64 kDa and 4.3, while those of lipase II were 66 kDa and 4.3, respectively. The two lipases had essentially the same specific activities, substrate specificities, pH stabilities, and optimal temperatures, but different pH optima and thermal stabilities.     

The cold-active lipase of Pseudomonas fragi. Heterologous expression, biochemical characterization and molecular modeling.

A recombinant lipase cloned from Pseudomonas fragi strain IFO 3458 (PFL) was found to retain significant activity at low temperature. In an attempt to elucidate the structural basis of this behaviour, a model of its three-dimensional structure was built by homology and compared with homologous mesophilic lipases, i.e. the Pseudomonas aeruginosa lipase (45% sequence identity) and Burkholderia cepacia lipase (38%). In this model, features common to all known lipases have been identified, such as the catalytic triad (S83, D238 and H260) and the oxyanion hole (L17, Q84). Structural modifications recurrent in cold-adaptation, i.e. a large amount of charged residues exposed at the protein surface, have been detected. Noteworthy is the lack of a disulphide bridge conserved in homologous Pseudomonas lipases that may contribute to increased conformational flexibility of the cold-active enzyme.     

Human hepatic lipase. Cloned cDNA sequence, restriction fragment length polymorphisms, chromosomal localization, and evolutionary relationships with lipoprotein lipase and pancreatic lipase

Human hepatic lipase is an important enzyme in high density lipoprotein (HDL) metabolism, being implicated in the conversion of HDL2 to HDL3. Three human hepatic lipase cDNA clones were identified in two lambda gt11 libraries from human liver. The cDNA-derived amino acid sequence predicts a protein of 476 amino acid residues, preceded by a 23-residue signal peptide. Four potential N-glycosylation sites are identified, two of which are conserved in rat hepatic lipase. On alignment with human, mouse, and bovine lipoprotein lipase, the same two sites were also conserved in lipoprotein lipase in all three species. Stringent conservation of the cysteine residues was also evident. Comparative analysis of amino acid sequences shows that hepatic lipase evolves at a rapid rate, 2.07 x 10(-9) substitutions/site/year, about four times that in lipoprotein lipase and half that in pancreatic lipase. Further, hepatic lipase and pancreatic lipase appear to be evolutionarily closer to each other than either of them is to lipoprotein lipase. Southern blot analysis revealed high frequency restriction fragment length polymorphisms of the hepatic lipase gene for the enzymes HindIII and MspI. these polymorphisms will be useful for haplotype and linkage analysis of the hepatic lipase gene. Using cloned human hepatic lipase cDNA as a hybridization probe, we performed Southern blot analysis of a panel of 13 human-rodent somatic cell hybrids. Concordance analysis of the various hybrid clones indicates that the hepatic lipase gene is located on the long arm of human chromosome 15. Analysis of hybrids containing different translocations of chromosome 15 localized the gene to the region 15q15----q22.     

Cloning and sequence analysis of cDNA encoding Rhizopus niveus lipase.

Complementary DNA encoding Rhizopus niveus lipase (RNL) was isolated from the R. niveus IF04759 cDNA library using a synthetic oligonucleotide corresponding to the amino acid sequence of the enzyme. A clone, which had an insert of 1.0 kilobase pairs, was found to contain the coding region of the enzyme. The lipase gene was expressed in Escherichia coli as a lacZ fusion protein. The mature RNL consisted of 297 amino acid residues with a molecular mass of 32 kDa. The RNL sequence showed significant overall homology to Rhizomucor miehei lipase and the putative active site residues were strictly conserved.