Characterization of the lipA gene encoding the major lipase from Pseudomonas aeruginosa strain IGB83

The lipases produced by Pseudomonas have a wide range of potential biotechnological applications. Pseudomonas aeruginosa IGB83 was isolated as a highly lipolytic strain which produced a thermotolerant and alkaline lipase. In the present work, we have characterized the P. aeruginosa IGB83 gene (lipA) encoding this enzyme. We describe the construction of a lipA mutant and report on the effect of two carbon sources on lipase expression.     

Substrate-induced lipase gene expression and aflatoxin production in Aspergillus parasiticus and Aspergillus flavus

AIMS: To establish a relationship between lipase gene expression and aflatoxin production by cloning the lipA gene and studying its expression pattern in several aflatoxigenic and nontoxigenic isolates of Aspergillus flavus and A. parasiticus. METHODS AND RESULTS: We have cloned a gene, lipA, that encodes a lipase involved in the breakdown of lipids from aflatoxin-producing A. flavus, A. parasiticus and two nonaflatoxigenic A. flavus isolates, wool-1 and wool-2. The lipA gene was transcribed under diverse media conditions, however, no mature mRNA was detected unless the growth medium was supplemented with 0.5% soya bean or peanut oil or the fungus was grown in lipid-rich medium such as coconut medium. The expression of the lipase gene (mature mRNA) under substrate-induced conditions correlated well with aflatoxin production in aflatoxigenic species A. flavus (SRRC 1007) and A. parasiticus (SRRC 143). CONCLUSIONS: Substrate-induced lipase gene expression might be indirectly related to aflatoxin formation by providing the basic building block 'acetate' for aflatoxin synthesis. No direct relationship between lipid metabolism and aflatoxin production can be ascertained, however, lipase gene expression correlates well with aflatoxin formation. SIGNIFICANCE AND IMPACT OF THE STUDY: Lipid substrate induces and promotes aflatoxin formation. It gives insight into genetic and biochemical aspects of aflatoxin formation.     

The diversity of lipases from psychrotrophic strains of Pseudomonas : a novel lipase from a highly lipolytic strain of Pseudomonas fluorescens

Strains of Pseudomonas fluorescens and Ps. fragi are the predominant psychrotrophs found in raw milk and may cause spoilage due to the secretion of hydrolytic enzymes such as lipase and protease. The diversity of lipases has been examined in Pseudomonas isolates from raw milk which represent different taxonomic groups (phenons). Significant diversity was found using both DNA hybridization and immunoblotting techniques, which has implications for the development of a diagnostic test. The lipase-encoding gene ( lipA ) was cloned from one strain, C9, of Ps. fluorescens biovar V. In contrast to previously reported lipase sequences from Ps. fluorescens , the gene encodes a lipase of M_r 33 kDa. Alignment of all known Pseudomonas and Burkholderia lipase amino acid sequences indicates the existence of two major groups, one of M_r approximately 30 kDa comprising sequences from Ps. fragi , Ps. aeruginosa , Ps. fluorescens C9 and Burkholderia , and one of approximately 50 kDa comprising Ps. fluorescens lipases. The lipase from C9 does not contain a signal peptide and is presumed to be secreted via a signal peptide-independent pathway. The lipA gene of strain C9 was disrupted by insertional mutagenesis. The mutant retained its lipolytic phenotype, strongly suggesting the presence of a second lipase in this strain.     

Role of the lipB gene product in the folding of the secreted lipase of Pseudomonas glumae

The LipB protein of Pseudomonas glumae is essential for the production of active extracellular lipase encoded by the lipA gene. When lipase is overproduced in P. glumae in the absence of a functional lipB gene, the enzyme accumulates intracellularly in an inactive conformation. Heterologous expression of the lipase in Pseudomonas aeruginosa, Bacillus subtilis and Escherichia coli indicated that LipB is not directly involved in the trans location of the lipase across the inner or outer membrane. However, the presence of LipB was essential for obtaining active lipase and had a profound influence on the stability of the protein to proteolytic degradation. Inactive iipase, produced in the absence of LipB could be activated in vitro by unfolding and refolding, which demonstrates that LipB activity is not responsible for an essential covalent modification of the enzyme. We propose that LipB is a lipase-specific foldase. Furthermore, proper folding of the lipase in the periplasm appears to be essential for Xcp-mediated translocation across the outer membrane.     

Genetic and biochemical characterization of a new extracellular lipase from Streptomyces cinnamomeus.

Streptomyces cinnamomeus Tü89 secretes a 30-kDa esterase and a 50-kDa lipase. The lipase-encoding gene, lipA, was cloned from genomic DNA into Streptomyces lividans TK23 with plasmid vector pIJ702. Two lipase-positive clones were identified; each recombinant plasmid had a 5.2-kb MboI insert that contained the complete lipA gene. The two plasmids differed in the orientation of the insert and the degree of lipolytic activity produced. The lipA gene was sequenced; lipA encodes a proprotein of 275 amino acids (29,213 Da) with a pI of 5.35. The LipA signal peptide is 30 amino acids long, and the mature lipase sequence is 245 amino acids long (26.2 kDa) and contains six cysteine residues. The conserved catalytic serine residue of LipA is in position 125. Sequence similarity of the mature lipases (29% identity, 60% similarity) was observed mainly in the N-terminal 104 amino acids with the group II Pseudomonas lipases; no similarity to the two Streptomyces lipase sequences was found. lipA was also expressed in Escherichia coli under the control of lacZ promoter. In the presence of the inducer isopropyl-beta-D-thiogalactopyranoside (IPTG), growth of the E. coli clone was severely affected, and the cells lysed in liquid medium. Lipase activity in the E. coli clone was found mainly in the pellet fraction. In sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis, three additional protein bands of 50, 29, and 27 kDa were visible. The 27-kDa protein showed lipolytic activity and represents the mature lipase; the 29- and 50-kDa forms showed no activity and very probably represent the unprocessed form and a dimeric misfolded form, respectively. For higher expression of lipA in S. lividans, the gene was cloned next to the strong aphII promoter. In contrast to the lipA-expressing E. coli clone, S. cinnamomeus and the corresponding S. lividans clone secreted only an active protein of 50 kDa. The lipase showed highest activity with C6 and C18 triglycerides; no activity was observed with phospholipids, Tween 20, or p-nitrophenylesters. Upstream of lipA and in the same orientation, an open reading frame, orfA, is found whose deduced protein sequence (519 amino acids) shows similarity to various membrane-localized transporters. Downstream of lipA and in the opposite orientation, an open reading frame, orfB (encoding a 199-amino-acid protein) is found, which shows no conspicuous sequence similarity to known proteins, other than an NAD and flavin adenine dinucleotide binding-site sequence.     

A strain of Pseudomonas fluorescens with two lipase-encoding genes, one of which possibly encodes cytoplasmic lipolytic activity

AIMS: A lipase-encoding gene (lipA) from a psychrotrophic strain of Pseudomonas fluorescens C9 has previously been characterized. It was also shown that when this gene was insertionally-inactivated, lipase activity was retained, suggesting that a second lipase may be present in this strain. The aim of this study was to determine whether this was the case. METHODS AND RESULTS: Using molecular cloning, chromosomal mutagenesis and enzymatic analysis, the presence of a second lipase-encoding gene (lipB) has been confirmed. The molecular weights of the putative products of lipA and lipB are 33 and 64.5 kDa, respectively, and their sequences are quite dissimilar (< 10% sequence identity). The lipB gene encodes a secreted lipase and is solely responsible for the 'lipolytic phenotype' of Ps. fluorescens C9. Expression of the lipA gene can be detected when expressed using an expression vector, but activity was only detected intracellularly in Ps. fluorescens C9, and not in the culture medium. CONCLUSION: Pseudomonas fluorescens C9 contains two dissimilar lipases. One (LipB) is secreted and responsible for the lipolytic phenotype; the evidence suggests that the other (LipA) could be intracellular, but it could be secreted and not detectable. SIGNIFICANCE AND IMPACT OF THE STUDY: Bacteria may contain more than one lipase activity. Ascribing phenotypes to particular enzymes therefore requires mutational analysis. The notion of an intracellular lipase activity is novel, and, if further substantiated, begs the question as to its normal substrate and physiological role.     

The lipA gene of Serratia marcescens which encodes an extracellular lipase having no N-terminal signal peptide.

The lipA gene encoding an extracellular lipase was cloned from the wild-type strain of Serratia marcescens Sr41. Nucleotide sequencing showed a major open reading frame encoding a 64.9-kDa protein of 613 amino acid residues; the deduced amino acid sequence contains a lipase consensus sequence, GXSXG. The lipase had 66 and 56% homologies with the lipases of Pseudomonas fluorescens B52 and P. fluorescens SIK W1, respectively, but did not show any overall homology with lipases from other origins. The Escherichia coli cells carrying the S. marcescens lipA gene did not secrete the lipase into the medium. The S. marcescens lipase had no conventional N-terminal signal sequence but was also not subjected to any processing at both the N-terminal and C-terminal regions. A specific short region similar to the regions of secretory proteins having no N-terminal signal peptide was observed in the amino acid sequence. Expression of the lipA gene in S. marcescens was affected by the carbon source and the addition of Tween 80.     

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.     

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.     

Cloning and characterization of the lipase and lipase activator protein from Vibrio vulnificus CKM-1

The gene (lipA) encoding the extracellular lipase and its downstream gene (lipB) from Vibrio vulnificus CKM-1 were cloned and sequenced. Nucleotide sequence analysis and alignments of amino acid sequences suggest that Lip Ais a member of bacterial lipase family I.1 and that LipB is a lipase activator of LipA. The active LipA was produced in recombinant Escherichia coli cells only in the presence of the lipB. In the hydrolysis of p-nitrophenyl esters and triacylglycerols, using the reactivated LipA, the optimum chain lengths for the acyl moiety on the substrate were C14 for ester hydrolysis and C10 to C12 for triacylglycerol hydrolysis.     

表皮葡萄球菌SarA对atlE、lipA和zinC基因表达调控的研究

表皮葡萄球菌(Staphylococcusepidermids)是一种条件致病菌,SarA(StaphylococcalaccessoryregulatorA)是该菌中一个全局性调控因子,它控制着细胞中许多与毒性相关的基因表达.报道了SarA在转录水平直接调控atlE、lipA和zinC基因的表达.RT-PCR和lacZ报告基因的分析结果显示,在表皮葡萄球菌ATCC35984中,SarA对atlE(自溶酶基因)表达起负调控作用,而对lipA(脂肪酶基因)和zinC(膜相关锌金属蛋白酶基因)的表达则有正调控作用.生物信息学分析表明,SarA控制atlE,lipA和zinC3种基因表达可能是通过与被调控基因上游的特定DNA序列的结合来实现的,该DNA结合区保守并富含AT碱基.根据已报道的金黄色葡萄球菌中SarA的结合位点序列,利用Omiga软件分析并推测了SarA结合atlE,lipA和zinC的可能区域.基于SarA是一种多功能的毒素相关调控因子,结果提示,SarA能调控众多因子,可以作为防治表皮葡萄球菌感染的一个药物筛选靶点.     

Promoter recognition and activation by the global response regulator CbrB in Pseudomonas aeruginosa

In Pseudomonas aeruginosa, the CbrA/CbrB two-component system is instrumental in the maintenance of the carbon-nitrogen balance and for growth on carbon sources that are energetically less favorable than the preferred dicarboxylate substrates. The CbrA/CbrB system drives the expression of the small RNA CrcZ, which antagonizes the repressing effects of the catabolite repression control protein Crc, an RNA-binding protein. Dicarboxylates appear to cause carbon catabolite repression by inhibiting the activity of the CbrA/CbrB system, resulting in reduced crcZ expression. Here we have identified a conserved palindromic nucleotide sequence that is present in upstream activating sequences (UASs) of promoters under positive control by CbrB and σ(54) RNA polymerase, especially in the UAS of the crcZ promoter. Evidence for recognition of this palindromic sequence by CbrB was obtained in vivo from mutational analysis of the crcZ promoter and in vitro from electrophoretic mobility shift assays using crcZ promoter fragments and purified CbrB protein truncated at the N terminus. Integration host factor (IHF) was required for crcZ expression. CbrB also activated the lipA (lipase) promoter, albeit less effectively, apparently by interacting with a similar but less conserved palindromic sequence in the UAS of lipA. As expected, succinate caused CbrB-dependent catabolite repression of the lipA promoter. Based on these results and previously published data, a consensus CbrB recognition sequence is proposed. This sequence has similarity to the consensus NtrC recognition sequence, which is relevant for nitrogen control.     

In vivo functional expression of a screened P. aeruginosa chaperone-dependent lipase in E.coli

ABSTRACT: BACKGROUND: Microbial lipases particularly Pseudomonas lipases are widely used for biotechnological applications. It is a meaningful work to design experiments to obtain high-level active lipase. There is a limiting factor for functional overexpression of the Pseudomonas lipase that a chaperone is necessary for effective folding. As previously reported, several methods had been used to resolve the problem. In this work, the lipase (LipA) and its chaperone (LipB) from a screened strain named AB which belongs to Pseudomonas aeruginosa were overexpressed in E.coli with two dual expression plasmid systems to enhance the production of the active lipase LipA without in vitro refolding process. RESULTS: In this work, we screened a lipase-produced strain named AB through the screening procedure, which was identified as P. aeruginosa on the basis of 16S rDNA. Genomic DNA obtained from the strain was used to isolate the gene lipA (936 bp) and lipase specific foldase gene lipB (1023 bp). One single expression plasmid system E.coli BL21/pET28a-lipAB and two dual expression plasmid systems E.coli BL21/pETDuet-lipA-lipB and E.coli BL21/pACYCDuet-lipA-lipB were successfully constructed. The lipase activities of the three expression systems were compared to choose the optimal expression method. Under the same cultured condition, the activities of the lipases expressed by E.coli BL21/pET28a-lipAB and E.coli BL21/pETDuet-lipA-lipB were 1300U/L and 3200U/L, respectively, while the activity of the lipase expressed by E.coli BL21/pACYCDuet-lipA-lipB was up to 8500U/L. The lipase LipA had an optimal temperature of 30[degree sign]C and an optimal pH of 9 with a strong pH tolerance. The active LipA could catalyze the reaction between fatty alcohols and fatty acids to generate fatty acid alkyl esters, which meant that LipA was able to catalyze esterification reaction. The most suitable fatty acid and alcohol substrates for esterification were octylic acid and hexanol, respectively. CONCLUSIONS: The effect of different plasmid system on the active LipA expression was significantly different. pACYCDuet-lipA-lipB was more suitable for the expression of active LipA than pET28a-lipAB and pETDuet-lipA-lipB. The LipA showed obvious esterification activity and thus had potential biocatalytic applications. The expression method reported here can give reference for the expression of those enzymes that require chaperones.     

Cloning, sequencing and expression of the lipase gene from Pseudomonas fragi IFO-12049 in E. coli

The lipase gene from Pseudomonas fragi IFO-12049 was isolated using the expression library and the primary structure of lipase deduced from the nucleotide sequence was determined. It is composed of 277 amino acid residues and a protein of Mr 29,966, which was close to the value of the lipase expressed in E. coli.     

Cloning, expression, and nucleotide sequence of a lipase gene from Pseudomonas fluorescens B52.

In this study, we report the cloning and expression of lipase gene from Pseudomonas fluorescens B52, a psychrotrophic spoilage bacterium isolated from refrigerated raw milk. Sequence analysis revealed one major open reading frame of 1,428 nucleotides that was predicted to encode a protein with a molecular weight of 50,241. The predicted enzyme was found to contain an amino acid sequence highly homologous to the putative substrate-binding domain present within all lipases examined to date.