lip2, a novel lipase gene cloned from Aspergillus niger exhibits enzymatic characteristics distinct from its previously identified family member

We have cloned a novel lipase gene, lip2, from Aspergillus niger and expressed it in Escherichia coli. Upon purification of the recombinant Lip2 protein, its properties were characterized. In comparison with a previously identified lipase Lip1, both enzymes are acid lipases (optimal pH <6.5), Ca²⁺-dependent and PMSF-sensitive, but have different molecular weights (35 and 43 kDa), optimal substrate spectra (C10 and C8), optimal reaction temperatures (45 and 50°C) and thermal stability. Circular dichroism spectroscopy revealed that Lip2 contains a typical Ca²⁺-active site. This first report on the cloning of the Lip2 gene and its enzymatic characteristics may greatly facilitate its potential industrial application.     

Enantioselectivity of Candida rugosa lipases (Lip1, Lip3, and Lip4) towards 2-bromo phenylacetic acid octyl esters controlled by a single amino acid

Enantiomer discrimination by enzymes is a very accurate mechanism, which often involves few amino acids located at the active site. Lipase isoforms from Candida rugosa are very good enzymatic models to study this phenomenon as they display high sequence homology (>80%) and their enantioselectivity is often pointed out. In the present work, we investigated three lipases from C. rugosa (Lip1, Lip3, and Lip4, respectively) towards the resolution of 2-bromo-arylacetic acid esters, an important class of chemical intermediates in the pharmaceutical industry. All exhibited a high enantioselectivity, with Lip4 preferring the R-enantiomer (E-value = 15), while Lip1 and Lip3 showed an S-enantioselectivity >200. A combination of sequence and structure analysis of the three C. rugosa lipases suggested that position 296 could play a role in S- or R-enantiomer preference of C. rugosa lipases. This led to the construction by site-directed mutagenesis of Lip1 and Lip4 variants in which position 296 was, respectively, exchanged by a Gly, Ala, Leu, or Phe amino acid. Screening of these variants for their enantioselectivity toward 2-bromo phenyl acetic acid octyl esters revealed that steric hindrance of the amino acid residue introduced at position 296 controls both the enantiopreference and the enantioselectivity value of the lipase: bulkier is the amino acid at position 296, larger is the selectivity towards the S-enantiomer. To investigate further these observations at an atomic level, we carried out a preliminary modeling study of the tetrahedral intermediates formed by Lip1 and Lip4 with the (R, S)-2-bromo-phenylacetic acid octyl ester enantiomers that provides some insight regarding the determinants responsible for lipase enantiodiscrimination.     

Engineering of Yarrowia lipolytica lipase Lip8p by circular permutation to alter substrate and temperature characteristics

Applications of lipases are mainly based on their catalytic efficiency and substrate specificity. In this study, circular permutation (CP), an unconventional protein engineering technique, was employed to acquire active mutants of Yarrowia lipolytica lipase Lip8p. A total of 21 mutant lipases exhibited significant shifts in substrate specificity. Cp128, the most active enzyme mutant, showed higher catalytic activity (14.5-fold) and higher affinity (4.6-fold) (decreased K _m) to p-nitrophenyl-myristate (pNP-C₁₄) than wild type (WT). Based on the three-dimensional (3D) structure model of the Lip8p, we found that most of the functional mutation occurred in the surface-exposed loop region in close proximity to the lid domain (S112–F122), which implies the steric effect of the lid on lipase activity and substrate specificity. The temperature properties of Cp128 were also investigated. In contrast to the optimal temperature of 45 °C for the WT enzyme, Cp128 exhibited the maximal activity at 37 °C. But it is noteworthy that there is no change in thermostability.     

Expression,purification, crystallization,and diffraction analysis of a selenomethionyl lipase Lip8 from Yarrowia lipolytica

Yarrowia lipolytica is a nonconventional model micro-organism with multiple biotechnological applications. It is also considered to be an excellent producer for lipase. Genome survey shows that Y. lipolytica possesses various paralogs of genes coding for extracellular, cell-bound, and intracellular lipolytic enzymes. However, little structural information on these isoenzymes is available. With the aim to facilitate crystal structure solution of Lip8, one of the most valuable lipases from Y. lipolytica, a less conventional protein expression technique—selenomethionyl protein expression was used to produce recombinant selenomethionine (SeMet)-Lip8 in Escherichia coli. Finally, three Met residues of Lip8 were all substituted with SeMet. A total of 72?mg of SeMet-Lip8 was obtained from a liter of the SeMet medium. Using sodium acetate as a precipitant and ammonium sulfate as an additive, crystals of the SeMet-Lip8 with 1.9?Å were successfully cultured through hanging-drop vapor diffusion method. The estimated crystal dimensions were 0.11?×?0.11?×?0.14?mm². The crystal belonged to the space group I4 with unit cell parameters a?=?b?=?128.87?Å, c?=?171.77?Å, α?=?β?=?γ?=?90°. It is the second member of lipase crystal family from Y. lipolytica. This work will provide a platform for further studying lipases from a structural insight.     

Characterization of a cold-active lipase from Psychrobacter cryohalolentis K5T and its deletion mutants

A gene coding for cold-active lipase from the psychrotrophic Gram-negative bacterium Psychrobacter cryohalolentis K5^T isolated from a Siberian cryopeg has been cloned and expressed in Escherichia coli. The recombinant protein Lip1Pc with a 6× histidine tag at its C-terminus was purified by nickel affinity chromatography. With p-nitrophenyl dodecanoate (C12) as a substrate, the purified recombinant protein displayed maximum lipolytic activity at 25°C and pH 8.0. Increasing the temperature above 40°C and addition of various metal ions and organic solvents inhibited the enzymatic activity of Lip1Pc. Most nonionic detergents, such as Triton X-100 and Tween 20, slightly increased the lipase activity, while SDS completely inhibited it. To investigate the functional significance of the Lip1Pc N-terminal domain, we constructed five deletion mutants of this protein. The ND1 and ND2 mutants displayed specific activity reduced by 30–35%, while other truncated proteins were completely inactive. Both mutants demonstrated increased activity towards p-nitrophenyl decanoate (C10) and impaired utilization of C16 substrate. Although optimum reaction temperature of ND2 lowered to 20°C, it displayed enhanced stability by 44% after incubation at 40°C. The results prove that the N-terminal domain of Lip1Pc has a fundamental impact on the activity and stability of the protein.     

Cloning,expression and characterization of a novel cold-active and organic solvent-tolerant esterase from <Emphasis Type="Italic">Monascus ruber</Emphasis> M7

Cold active esterases are a class of important biocatalysts that exhibit high activity at low temperatures. In this study, a search for putative cold-active esterase encoding genes from Monascus ruber M7 was performed. A cold-active esterase, named Lip10, was isolated, cloned, purified, and characterized. Amino acid sequence analysis reveals that Lip10 contained a conserved sequence motif Gly¹⁷³-Xaa-Ser¹⁷⁵-Xaa-Gly¹⁷⁷ that is also present in the majority of esterases and lipases. Phylogenetic analysis indicated that Lip10 was a novel microbial esterase. The lip10 gene was cloned and heterologously expressed in Escherichia coli BL21(DE3), resulting in the expression of an active and soluble protein that constituted 40 % of the total cell protein content. Lip10 maintained almost 50 % of its maximal activity at 4–10 °C, with optimal activity at 40 °C. Furthermore, Lip10 retained 184–216 % of its original activity, after incubation in 50 % (v/v) hydrophobic organic solvents for 24 h. The enzyme also exhibited high activity under alkaline conditions and good tolerance to metal ions in the reaction mixture. These results indicate that Lip10 may have potential uses in chemical synthesis and food processing industrial applications as an esterase.     

Improving the activity and stability of Yarrowia lipolytica lipase Lip2 by immobilization on polyethyleneimine-coated polyurethane foam

In this study, polyurethane foam (PUF) was used for immobilization of Yarrowia lipolytica lipase Lip2 via polyethyleneimine (PEI) coating and glutaraldehyde (GA) coupling. The activity of immobilized lipases was found to depend upon the size of the PEI polymers and the way of GA treatment, with best results obtained for covalent-bind enzyme on glutaraldehyde activated PEI-PUF (MW 70,000 Da), which was 1.7 time greater activity compared to the same enzyme immobilized without PEI and GA. Kinetic analysis shows the hydrolytic activity of both free and immobilized lipases on triolein substrate can be described by Michaelis–Menten model. The K_m for the immobilized and free lipases on PEI-coated PUF was 58.9 and 9.73 mM, respectively. The V_max values of free and immobilized enzymes on PEI-coated PUF were calculated as 102 and 48.6 U/mg enzyme, respectively. Thermal stability for the immobilization preparations was enhanced compared with that for free preparations. At 50 °C, the free enzyme lost most of its initial activity after a 30 min of heat treatment, while the immobilized enzymes showed significant resistance to thermal inactivation (retaining about 70% of its initial activity). Finally, the immobilized lipase was used for the production of lauryl laurate in hexane medium. Lipase immobilization on the PEI support exhibited a significantly improved operational stability in esterification system. After re-use in 30 successive batches, a high ester yield (88%) was maintained. These results indicate that PEI, a polymeric bed, could not only bridge support and immobilized enzymes but also create a favorable micro-environment for lipase. This study provides a simple, efficient protocol for the immobilization of Y. lipolytica lipase Lip2 using PUF as a cheap and effective material.     

Response surface methodology-based optimization of glucose acylation bio-catalyzed by immobilized lipase

This paper describes in detail the selection and optimization of immobilized lipases for enhanced regioselective acylation of glucose into glucose monolaurate (GlcML). Initially, nature of biocatalyst, immobilization approach, reaction media, glucose, and lauric acid concentration were screened out. Finally, lipases from Rhizopus arrhizus immobilized on dead mycelia were investigated under various reaction conditions (Temperature, shaking speed, enzyme dose, and water content) following a fully rotatable central composite design (FRCCD) to optimize the activity of lipases. The immobilized lipases-based biocatalysts in the presence of polar solvents (tertiary alcohols) and higher concentrations of substrates i.e. glucose and lauric acid (100 and 300?mmol?L^?1, respectively) offered conversion rate of 1.5 mmolmin^?1?L^?1. Moreover, optimization of reaction conditions revealed that 162.5 lipase units/100mL at 31.25?°C, 3% water content, and 105?RPM shaking speed enhanced the conversion rate by 0.5 mmolmin^?1?L^?1 rendering the reaction more economical. Hence, lipases-based immobilized biocatalysts may provide an intelligent and green choice for commercial scale synthesis of GlcML for food and pharmaceutical industries.     

A new alkaline lipase obtained from the metagenome of marine sponge <Emphasis Type="Italic">Ircinia</Emphasis> sp.

Microorganisms associated with marine sponges are potential resources for marine enzymes. In this study, culture-independent metagenomic approach was used to isolate lipases from the complex microbiome of the sponge Ircinia sp. obtained from the South China Sea. A metagenomic library was constructed, containing 6568 clones, and functional screening on 1 % tributyrin agar resulted in the identification of a positive lipase clone (35F4). Following sequence analysis 35F4 clone was found to contain a putative lipase gene lipA. Sequence analysis of the predicted amino acid sequence of LipA revealed that it is a member of subfamily I.1 of lipases, with 63 % amino acid similarity to the lactonizing lipase from Aeromonas veronii (WP_021231793). Based on the predicted secondary structure, LipA was predicted to be an alkaline enzyme by sequence/structure analysis. Heterologous expression of lipA in E. coli BL21 (DE3) was performed and the characterization of the recombinant enzyme LipA showed that it is an alkaline enzyme with high tolerance to organic solvents. The isolated lipase LipA was active in the broad alkaline range, with the highest activity at pH 9.0, and had a high level of stability over a pH range of 7.0–12.0. The activity of LipA was increased in the presence of 5 mM Ca²⁺ and some organic solvents, e.g. methanol, acetone and isopropanol. The optimum temperature for the activity of LipA is 40 °C and the molecular weight of LipA was determined to be ~30 kDa by SDS-PAGE. LipA is an alkaline lipase and shows good tolerance to some organic solvents, which make it of potential utility in the detergent industry and enzyme mediated organic synthesis. The result of this study has broadened the diversity of known lipolytic genes and demonstrated that marine sponges are an important source for new enzymes.     

Study on the potential of cold-active lipases from psychrotrophic fungi for detergent formulation

Lipases from psychrotrophic fungal isolates BPF4 and BPF6 identified as Penicilium canesense and Pseudogymnoascus roseus respectively were characterized for their compatibility towards laundry detergent. BPF4 and BPF6 lipases showed maximum activity at pH 11 and 9 respectively and at 40?°C. The residual activities at 20?°C and 4?°C of BPF4 lipase were 35% and 20% and of BPF6 lipase were 70% and 20?°C respectively. Both the enzymes were stable at 4?°C, 20?°C and 40?°C for 2?h losing at the most 20% of activities. Both the enzymes were metalloenzymes with activity enhancement by nearly threefold by Ca²⁺. Contrary to BPF6 lipase, BPF4 enzyme was not stimulated by EDTA nor inhibited, rather stimulated by SDS and Triton X-100 by 125% and 330% respectively. Both the lipases showed minor to moderate inhibition by NaClO₃ and H₂O₂, and exhibited nearly 90% residual activity after 1?h of incubation in selected detergent brands thus indicating potential for their inclusion in detergent formulation thereby facilitating cold-washing as a step towards mitigation of climate change.     

Acidic lipase Lip I.3 from a Pseudomonas fluorescens‐like strain displays unusual properties and shows activity on secondary alcohols

Aims

Identification, cloning, expression and characterization of a novel lipase – Lip I.3 – from strain Pseudomonas CR‐611.

Methods and Results

The corresponding gene was identified and isolated by PCR‐amplification, cloned and expressed in Escherichia coli, and purified by refolding from inclusion bodies. Analysis of the deduced amino acid sequence revealed high homology with members of the bacterial lipase family I.3, showing 97% identity to a putative lipase from Pseudomonas fluorescens Pf0‐1, and 93% identity to a crystallized extracellular lipase from Pseudomonas sp. MIS38. A typical C‐terminal type I secretion signal and several putative Ca²⁺ binding sites were also identified. Experimental data confirmed that Lip I.3 requires Ca²⁺ ions for correct folding and activity. The enzyme differs from the previously reported family I.3 lipases in optimal pH, being the first acidophilic lipase reported in this family. Furthermore, Lip I.3 shows a strong preference for medium chain fatty acid esters and does not display interfacial activation. When tested for activity on secondary alcohol hydrolysis, Lip I.3 displayed higher efficiency on aromatic alcohols rather than on alkyl alcohols.

Conclusions

A new family I.3 lipase with unusual properties has been isolated, cloned and described. This will contribute to a better knowledge of family I.3 lipases, a family that has been scarcely explored, and that might provide a novel source of biocatalysts.

Significance and Impact of the Study

The unusual properties shown by Lip I.3 and the finding of activity and enantioselectivity on secondary alcohol esters may contribute to the development of new enzymatic tools for applied biocatalysis.     

Extracellular expression and characterization of thermostable lipases, LIP8, LIP14 and LIP18, from Yarrowia lipolytica

Two new lipases, LIP14 and LIP18, along with LIP8 from Yarrowia lipolytica MSR80 were functionally expressed as extracellular proteins with an IgG tag using Escherichia coli HB101 pEZZ18 host vector system. Each enzyme had an optimal activity at pH 7 and 40?°C and was activated by 6?mM Ca(2+) and 90?% (v/v) non-polar solvents but inhibited by 10?mM of each 1,10-phenanthraline, DTNB, PMSF and N-bromosuccinamide. All the enzymes were thermostable with t(1/2) of 52?min, 49?min and 68?min for LIP8, LIP14 and LIP18 at 80?°C, respectively. LIP18 was most thermostable among all with a high arginine: lysine ratio and proline content. All the three lipases showed a preference for oleic acid rich triacylglycerols and oils.     

Differential behaviour of Pseudomonas sp. 42A2 LipC,a lipase showing greater versatility than its counterpart LipA

Growth of Pseudomonas sp. 42A2 on oleic acid releases polymerized hydroxy-fatty acids as a result of several enzymatic conversions that could involve one or more lipases. To test this hypothesis, the lipolytic system of strain Pseudomonas sp. 42A2 was analyzed, revealing the presence of at least an intracellular carboxylesterase and a secreted lipase. Consensus primers derived from a conserved region of bacterial lipase subfamilies I.1 and I.2 allowed isolation of two secreted lipase genes, lipA and lipC, highly homologous to those of Pseudomonas aeruginosa PAO1. Homologous cloning of the isolated lipA and lipC genes was performed in Pseudomonas sp. 42A2 for LipA and LipC over-expression. The overproduced lipases were further purified and characterized, both showing preference for medium fatty acid chain-length substrates. However, significant differences could be detected between LipA and LipC in terms of enzyme kinetics and behaviour pattern. Accordingly, LipA showed maximum activity at moderate temperatures, and displayed a typical Michaelis–Menten kinetics. On the contrary, LipC was more active at low temperatures and displayed partial interfacial activation, showing a shift in substrate specificity when assayed at different temperatures, and displaying increased activity in the presence of certain heavy metal ions. The versatile properties shown by LipC suggest that this lipase could be expressed in response to variable environmental conditions.     

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.     

Cloning,expression and characterization of an organic solvent tolerant lipase from Pseudomonas fluorescens JCM5963

A novel lipase gene from an organic solvent degradable strain Pseudomonas fluorescens JCM5963 was cloned, sequenced, and overexpressed as an N-terminus His-tag fusion protein in E. coli. The alignment of amino acid sequences revealed that the protein contained a lipase motif and shared a medium or high similarity with lipases from other Pseudomonas strains. It could be defined as a member of subfamily I.1 lipase. Most of the recombinant proteins expressed as enzymatically active aggregates soluble in 20 mM Tris–HCl buffer (pH 8.0) containing sodium deoxycholate are remarkably different from most subfamily I.1 and I.2 members of Pseudomonas lipases expressed as inactive inclusion body formerly described in E. coli. The recombinant lipase (rPFL) was purified to homogeneity by Ni-NTA affinity chromatography and Sephacryl S-200 gel filtration chromatography. The purified lipase was stable in broad ranges of temperatures and pH values, with the optimal temperature and pH value being 55 °C and 9.0, respectively. Its activity was found to increase in the presence of metal ions such as Ca²⁺, Sn²⁺ and some non-ionic surfactants. In addition, rPFL was activated by and remained stable in a series of water-miscible organic solvents solutions and highly tolerant to some water-immiscible organic solvents. These features render this novel lipase attraction for biotechnological applications in the field of organic synthesis and detergent additives.     

Functional expression,extracellular production,purification, structure modeling and biochemical characterization of Carica papaya lipase 1

Carica papaya latex has been reported to contain lipolytic activity since 1925, nevertheless the efforts to isolate lipolytic enzymes directly from the latex matrix have been unsuccessful. Nowadays papaya genome is known and heterologous expression is an alternative to overcome this problem. Therefore, in this study, Carica papaya lipase 1 sequence (CpLip1) has been identified in papaya genome and for the first time, functionally expressed using Pichia pastoris as host system. Purification of the recombinant enzyme was carried out by affinity chromatography and reached a 7-fold purification factor with 25 U/mg in the purified fraction. Interestingly, homology modeling with lipases of known structure revealed homology with microbial lipases. The biochemical characterization of the purified enzyme shows that CpLip1 hydrolyzed preferentially long-chain triglycerides, it has an optimal pH of 8.5 and an optimal temperature of 35 °C. Finally, the study of its stability in organic solvents showed that, as many lipases, CpLip1 activity is affected in polar solvents. This contribution opens the possibility of studying the catalytic performance of pure CpLip1 in several reactions, and a better understanding of the role of lipases in Carica papaya.     

Influence of N- and/or C-terminal regions on activity, expression, characteristics and structure of lipase from Geobacillus sp. 95

GD-95 lipase from Geobacillus sp. strain 95 and its modified variants lacking N-terminal signal peptide and/or 10 or 20 C-terminal amino acids were successfully cloned, expressed and purified. To our knowledge, GD-95 lipase precursor (Pre-GD-95) is the first Geobacillus lipase possessing more than 80 % lipolytic activity at 5 °C. It has maximum activity at 55 °C and displays a broad pH activity range. GD-95 lipase was shown to hydrolyze p-NP dodecanoate, tricaprylin and canola oil better than other analyzed substrates. Structural and sequence alignments of bacterial lipases and GD-95 lipase revealed that the C-terminus forms an α helix, which is a conserved structure in lipases from Pseudomonas, Clostridium or Staphylococcus bacteria. This work demonstrates that 10 and 20 C-terminal amino acids of GD-95 lipase significantly affect stability and other physicochemical properties of this enzyme, which has never been reported before and can help create lipases with more specific properties for industrial application. GD-95 lipase and its modified variants GD-95-10 can be successfully applied to biofuel production, in leather and pulp industries, for the production of cosmetics or perfumes. These lipases are potential biocatalysts in processes, which require extreme conditions: low or high temperature, strongly acidic or alkaline environment and various organic solvents.     

Homologous yeast lipases/acyltransferases exhibit remarkable cold-active properties

Lipases/acyltransferases catalyse acyltransfer to various nucleophiles preferentially to hydrolysis even in aqueous media with high thermodynamic activity of water (a _w >0.9). Characterization of hydrolysis and acyltransfer activities in a large range of temperature (5 to 80 °C) of secreted recombinant homologous lipases of the Pseudozyma antarctica lipase A superfamily (CaLA) expressed in Pichia pastoris, enlighten the exceptional cold-activity of two remarkable lipases/acyltransferases: CpLIP2 from Candida parapsilosis and CtroL4 from Candida tropicalis. The activation energy of the reactions catalysed by CpLIP2 and CtroL4 was 18–23 kJ mol^?1 for hydrolysis and less than 15 kJ mol^?1 for transesterification between 5 and 35 °C, while it was respectively 43 and 47 kJ mol^?1 with the thermostable CaLA. A remarkable consequence is the high rate of the reactions catalysed by CpLIP2 and CtroL4 at very low temperatures, with CpLIP2 displaying at 5 °C 65 % of its alcoholysis activity and 45 % of its hydrolysis activity at 30 °C. These results suggest that, within the CaLA superfamily and its homologous subgroups, common structural determinants might allow both acyltransfer and cold-active properties. Such biocatalysts are of great interest for the efficient synthesis or functionalization of temperature-sensitive lipid derivatives, or more generally to lessen the environmental impact of biocatalytic processes.     

Production and activity of extracellular lipase from Luteibacter sp.

Microbial lipases are widely used in industrial applications due to their versatility, and the characterization of new lipase-producing microorganisms could provide new sources of these enzymes, with different specificities and better activities. In this context, we have improved lipase production by Luteibacter sp. by using basal medium supplemented with 2 % olive oil, a pH of 6 and a growth temperature of 37 °C. The enzyme extraction process with the addition of 0.25 % Tween 80 increased lipase activity. Implementation of these modifications increased lipase activity by approximately 430 %. The lipase activities produced in the culture supernatant (LCS) and extracted with Tween 80 (LCST80) were characterized. Both extracts hydrolyzed ρ-nitrophenyl (ρNP) esters with different acyl chain lengths, with a preference for short acyl lengths, and had optimum activity at 45 °C. The LCS was stable at acidic and alkaline pH, but LCST80 was only stable at alkaline pH. Methanol, SDS, Triton X-100, EDTA, and EGTA did not affect lipase activity, while divalent cations (Ca²⁺, Zn²⁺, Mg²⁺) - with the exception of Co²⁺— increased lipase activity. Both extracts showed transesterification activity on ρNP ester substrates, and both were able to hydrolyze different natural lipids. The characterization of lipase produced by Luteibacter sp. introduces this recently described genus as a new source of lipases with great biotechnological potential.     

Synthesis of cinnamyl acetate catalysed by highly reusable cotton-immobilized Pseudomonas fluorescens lipase

Cinnamyl acetate as an important fragrance ingredient could be synthesized by lipase-catalysed transesterification in organic systems, but enzyme proteins tended to denature and inactivate for no water lubrication. To improve the non-aqueous stability of lipases, absorbent cotton was taken as an alternative “water” phase to stabilize enzyme proteins. In a mass ratio of 1:1, Pseudomonas fluorescens lipase was immobilized on cotton fibres by physical absorption in a column glass bottle, forming a facile cotton-lipase bioreactor in which the transesterification between cinnamyl alcohol and vinyl acetate processed efficiently. From the molar conversions after reaction for 2?h at 37?°C and 160?rpm, the ability of cotton-lipase to transform substrate was more than 5-folds of native lipase. And even in static state and at 4?°C, the conversion of reaction catalysed by cotton-PFL had 11-fold increase relative to native lipase after 8?h. Recycles showed that the cotton-lipase had an extra-long half-life of activity (t_1/2?=?693?h) and a negligible decay rate in the ability to transform substrate (D_r?=?0.08% h^?1). All these showed that this lipase had been effectively activated and stabilized by cotton fibres for the numerous hydroxyl groups and fluffy structure.