Lipases from the genus Rhizopus: Characteristics,expression, protein engineering and application

Lipases are versatile catalysts that hydrolyze ester bonds of water-insoluble glycerides or carry out reversible reactions at the water/lipid interface. The remarkable characteristics of lipases from the genus Rhizopus are their high sn-1,3-positional specificity, enantioselectivity and activity in nonaqueous media, which make them one of the most desirable enzymes for many applications, including lipid modification and biodiesel and chiral organic compound synthesis. sn-1,3-Position-specific Rhizopus lipases are particularly useful for the production of structured triacylglycerols. Significant progress has been made regarding lipases from the genus Rhizopus, including gene sequencing, elucidation of the protein structure and catalytic function, heterologous expression and redesigning Rhizopus lipases for valuable properties, which is receiving increasing academic and industrial attention. In this review, we present a comprehensive overview of Rhizopus lipases, focusing on (a) the characteristics of Rhizopus lipases, (b) Rhizopus lipase genes and structural features, (c) strategies for heterologous expression of Rhizopus lipase genes in yeast system, (d) progress in protein engineering for the improvement of the properties of Rhizopus lipases, and (e) development of biotechnological applications.     

Solvent tolerant Pseudomonads as a source of novel lipases for applications in non-aqueous systems

Abstract

Lipases (triacylglycerol acylhydrolases, EC 3.1.1.3) are ubiquitous biocatalysts known to catalyze the hydrolysis of water insoluble triglycerides in aqueous medium and carry out the reverse reaction (synthesis) under organic solvent rich medium. Microbial lipases have received a great deal of attention in the field of food technology, pharmaceutical sciences, chemical and detergent industries due to their stability, selectivity, mild operation conditions and broad substrate specificity. Despite these advantages, low activity and stability displayed in organic medium has restricted their commercial application in organic synthesis. Researchers have explored alternative ways to modify the enzymes making them suitable for use in non-conventional media. In this context, harvesting lipases from “Solvent Tolerant Microbes” has recently become an attractive approach. These microbes are able to grow in the presence of high concentrations of organic solvents, generally known to have detrimental effect on microorganisms. Such microbes survive through novel adaptation mechanisms and secretion of solvent stable enzymes having efficient functionality in solvent-rich media. These enzymes could be useful for bioconversion in non-conventional media. In the current review, this approach is described with an emphasis on characteristics, applications and genetic aspect of lipases from the genus Pseudomonas.     

Bacterial lipases: an overview of production,purification and biochemical properties

Lipases, triacylglycerol hydrolases, are an important group of biotechnologically relevant enzymes and they find immense applications in food, dairy, detergent and pharmaceutical industries. Lipases are by and large produced from microbes and specifically bacterial lipases play a vital role in commercial ventures. Some important lipase-producing bacterial genera include Bacillus, Pseudomonas and Burkholderia. Lipases are generally produced on lipidic carbon, such as oils, fatty acids, glycerol or tweens in the presence of an organic nitrogen source. Bacterial lipases are mostly extracellular and are produced by submerged fermentation. The enzyme is most commonly purified by hydrophobic interaction chromatography, in addition to some modern approaches such as reverse micellar and aqueous two-phase systems. Most lipases can act in a wide range of pH and temperature, though alkaline bacterial lipases are more common. Lipases are serine hydrolases and have high stability in organic solvents. Besides these, some lipases exhibit chemo-, regio- and enantioselectivity. The latest trend in lipase research is the development of novel and improved lipases through molecular approaches such as directed evolution and exploring natural communities by the metagenomic approach.     

Cold active microbial lipases: some hot issues and recent developments

Lipases are glycerol ester hydrolases that catalyze the hydrolysis of triglycerides to free fatty acids and glycerol. Lipases catalyze esterification, interesterification, acidolysis, alcoholysis and aminolysis in addition to the hydrolytic activity on triglycerides. The temperature stability of lipases has regarded as the most important characteristic for use in industry. Psychrophilic lipases have lately attracted attention because of their increasing use in the organic synthesis of chiral intermediates due to their low optimum temperature and high activity at very low temperatures, which are favorable properties for the production of relatively frail compounds. In addition, these enzymes have an advantage under low water conditions due to their inherent greater flexibility, wherein the activity of mesophilic and thermophilic enzymes are severely impaired by an excess of rigidity. Cold-adapted microorganisms are potential source of cold-active lipases and they have been isolated from cold regions and studied. Compared to other lipases, relatively smaller numbers of cold active bacterial lipases were well studied. Lipases isolated from different sources have a wide range of properties depending on their sources with respect to positional specificity, fatty acid specificity, thermostability, pH optimum, etc. Use of industrial enzymes allows the technologist to develop processes that closely approach the gentle, efficient processes in nature. Some of these processes using cold active lipase from C. antarctica have been patented by pharmaceutical, chemical and food industries. Cold active lipases cover a broad spectrum of biotechnological applications like additives in detergents, additives in food industries, environmental bioremediations, biotransformation, molecular biology applications and heterologous gene expression in psychrophilic hosts to prevent formation of inclusion bodies. Cold active enzymes from psychrotrophic microorganisms showing high catalytic activity at low temperatures can be highly expressed in such recombinant strains. Thus, cold active lipases are today the enzymes of choice for organic chemists, pharmacists, biophysicists, biochemical and process engineers, biotechnologists, microbiologists and biochemists.     

Directed evolution of Bacillus licheniformis lipase for improvement of thermostability

Lipases catalyze the hydrolysis of carboxylic acid esters and owing to their vast substrate specificity, they have many industrial applications. Due to the demand of thermostable lipases in industrial applications, we have enhanced the thermostability of lipase from Bacillus licheniformis RSP-09. The thermostable mutant lipases of Bacillus licheniformis RSP-09 were isolated following two rounds of directed evolution using error-prone PCR. The best mutant lipases obtained after first and second round of error-prone PCR were purified and characterized. The mutant lipases showed increased thermostability and retained catalytic function. The best mutant lipase (eP-231-51) showed 13.5-fold increase in percentage thermal stability (% remaining activity after incubation of purified enzyme at 60 °C for 1 h) than wild-type lipase. Also, this mutant lipase (ep-231-51) showed 30% improved catalytic efficiency compared with the wild-type which is due to significant decrease in K_m and marginal increase in k_cat. In addition, the thermostable mutant lipases have shown resistance to hydrophobic organic solvents. The role of mutations in the best mutant lipases of second round i.e. eP-231-51 (Asp72Gly, Asp61Gly, Tyr129His, and Thr101Pro) and eP-231-137 (Leu49Arg, Thr101Pro, Asp72Gly), that led to thermostability have been postulated after the comparison of molecular models of wild-type and mutated enzymes.     

Lipases as practical biocatalysts

Lipases are the most used enzymes in synthetic organic chemistry, catalyzing the hydrolysis of carboxylic acid esters in aqueous medium or the reverse reaction in organic solvents. Recent methodological advancements regarding practical factors affecting lipase activity and enantioselectivity are reviewed. Select practical examples concerning the use of lipases in the production of chiral intermediates are also highlighted.     

Technical methods to improve yield,activity and stability in the development of microbial lipases

Lipases are ubiquitous biocatalysts that catalyze various reactions in organic solvents or in solvent-free systems and are increasingly applied in various industrial fields. In view of the excellent catalytic activities and the huge application potential, more than 20 microbial lipases have been realized in large-scale commercial production. The potential for commercial exploitation of a microbial lipase is determined by its yield, activity, stability and other characteristics. This review will survey the various technical methods that have been developed to enhance yield, activity and stability of microbial lipases from four aspects, including improvements in lipase-producing strains, modification of lipase genes, fermentation engineering of lipases and downstream processing technology of lipase products.     

Effect of pretreatment by different organic solvents on esterification activity and conformation of immobilized Pseudomonas cepacia lipase

Experiments were carried out to investigate the effect of pretreatment by organic solvents with different hydrophobicities, functional groups and molecular constitutions as activation agents on initial esterification activity and secondary structure of immobilized Pseudomonas cepacia lipase. The results showed that esterification activity of immobilized P. cepacia lipase treated with organic solvents containing –CO– and –CN– functional groups was highest, followed by the one treated with –C–C– functional groups but the lowest with –OH and aromatics functional groups. An organic solvent with a branched structure was more favorable compared with a straight chain in terms of enhancing enzyme activity. Conformational studies via Fourier transform-infrared spectroscopy indicated that the catalytic activity variance was attributed to the secondary structure changes for immobilized P. cepacia lipase treated with organic solvents. Moreover, the effects of moisture, pH and temperature on the esterification activity of immobilized P. cepacia lipase were also addressed.     

Lipase-Catalyzed Synthesis of Fatty Acid Esters Useful in the Food Industry

Enzyme reactions are very attractive in food technology because they can be carried out under mild conditions and without toxic solvents and other catalysts. Lipases can esterify various alcohols with fatty acids. There are opportunities to synthesize useful compounds with special functions as food materials by using the catalytic function of lipase. Reverse micellar systems are discussed as reaction systems for lipases in organic solvents, especially in triacylglycerol synthesis using phosphatidylcholine as the surfactant. Syntheses of some amphiphilic substances including O-acyl-L-homoserine are also discussed.     

Substrate specificity,regioselectivity and hydrolytic activity of lipases activated from Geotrichum sp.

Substrate specificity (typoselectivity), regioselectivity and hydrolytic activity of induced lipases from three strains (4012, 4013, 4166) of Geotrichum candidum and that of Geotrichum ludwigii (48) were investigated. The lipases were induced in two types of culture media, of which the medium containing peptone as nitrogen source was proved to give better results. Olive oil was employed as inductor for the lipase activity. Activated lipases represented mostly extracelullar lipases, which penetrated through cellular membrane into medium. The activity of cell-bound lipase was also determined. Most of lipases belong to the group of specific lipases able to hydrolyse ester bonds in the positions sn-1 and sn-3 ester of triacylglycerols (1,3-selective lipases) and display specificity to saturated fatty acids. All activated lipases from Geotrichum sp., extracellular and cell-bound, were used as biocatalyst in the blackcurrant oil hydrolysis.     

Lipase-Catalyzed Synthesis of Fatty Acid Esters Useful in the Food Industry

Enzyme reactions are very attractive in food technology because they can be carried out under mild conditions and without toxic solvents and other catalysts. Lipases can esterify various alcohols with fatty acids. There are opportunities to synthesize useful compounds with special functions as food materials by using the catalytic function of lipase. Reverse micellar systems are discussed as reaction systems for lipases in organic solvents, especially in triacylglycerol synthesis using phosphatidylcholine as the surfactant. Syntheses of some amphiphilic substances including O-acyl-L-homoserine are also discussed.     

<Emphasis Type="Italic">Acinetobacter</Emphasis> lipases: molecular biology,biochemical properties and biotechnological potential

Lipases (EC 3.1.1.3) have received increased attention recently, evidenced by the increasing amount of information about lipases in the current literature. The renewed interest in this enzyme class is due primarily to investigations of their role in pathogenesis and their increasing use in biotechnological applications [38]. Also, many microbial lipases are available as commercial products, the majority of which are used in detergents, cosmetic production, food flavoring, and organic synthesis. Lipases are valued biocatalysts because they act under mild conditions, are highly stable in organic solvents, show broad substrate specificity, and usually show high regio- and/or stereo-selectivity in catalysis. A number of lipolytic strains of Acinetobacter have been isolated from a variety of sources and their lipases possess many biochemical properties similar to those that have been developed for biotechnological applications. This review discusses the biology of lipase expression in Acinetobacter, with emphasis on those aspects relevant to potential biotechnology applications.     

微生物脂肪酶稳定性研究进展

脂肪酶广泛应用于食品、药物、生物燃料、诊断、生物修复、化学品、化妆品、清洁剂、饲料、皮革和生物传感器等工业领域,微生物脂肪酶是商品化脂肪酶的重要来源。高温、酸性、碱性和有机溶剂等恶劣的工业生产环境使得脂肪酶的进一步工业应用受到限制,获取稳定性好的脂肪酶成为打破这一限制的关键环节。本文重点对提高微生物脂肪酶稳定性的策略进行了综述:挖掘极端微生物脂肪酶资源;利用定向进化、理性设计和半理性设计等蛋白质工程策略改造脂肪酶;利用物理吸附、封装、共价结合和交联等酶的固定化技术提高脂肪酶的稳定性;利用物理/化学修饰、表面展示以及多种改良策略相结合提高脂肪酶的稳定性。结合作者前期对酶工程的研究发现,新型酶催化剂的获得应该基于明确的设计思路,结合多种改造方法,基于定向进化-理性设计、定向进化-半理性设计、蛋白质工程-酶的固定化、蛋白质工程-物理/化学修饰、酶的固定化-物理/化学修饰等组合改造,比单一的改造方法具有更高的效率。     

Customizing lipases for biocatalysis: a survey of chemical, physical and molecular biological approaches

Lipases (triacylglycerol ester hydrolases, EC 3.1.1.3) are ubiquitous enzymes that catalyze the breakdown of fats and oils with subsequent release of free fatty acids, diacylglycerols, monoglycerols and glycerol. Besides this, they are also efficient in various reactions such as esterification, transesterification and aminolysis in organic solvents. Therefore, those enzymes are nowadays extensively studied for their potential industrial applications. Examples in the literature are numerous concerning their use in different fields such as resolution of racemic mixtures, synthesis of new surfactants and pharmaceuticals, oils and fats bioconversion and detergency applications. However, the drawbacks of the extensive use of lipases (and biocatalysts in general) compared to classical chemical catalysts can be found in the relatively low stability of enzyme in their native state as well as their prohibitive cost. Consequently, there is a great interest in methods trying to develop competitive biocatalysts for industrial applications by improvement of their catalytic properties such as activity, stability (pH or temperature range) or recycling capacity. Such improvement can be carried out by chemical, physical or genetical modifications of the native enzyme. The present review will survey the different procedures that have been developed to enhance the properties of lipases. It will first focus on the physical modifications of the biocatalysts by adsorption on a carrier material, entrapment or microencapsulation. Chemical modifications and methods such as modification of amino acids residues, covalent coupling to a water-insoluble material, or formation of cross-linked lipase matrix, will also be reviewed. Finally, new and promising methods of lipases modifications by genetic engineering will be discussed.     

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.     

Burkholderia cepacia lipase is a promising biocatalyst for biofuel production

Lipases resistant to inhibition and denaturation by methanol are valuable tools for biotechnological applications, in particular for biofuel production. Microbial lipases have attracted a great deal of interest because of their stability at high concentrations of organic solvents. Burkholderia cepacia lipase (BCL) is tested here for robustness towards methanol in terms of conformational stability and catalytic activity in transesterification assays. This lipase turns out to be even more tolerant than the homologous and better characterized enzyme from Burkholderia glumae. BCL unfolding transition, as monitored by far‐UV circular dichroism (CD) and intrinsic fluorescence, displays a T_m above 60°C in the presence of 50% methanol. The protein unfolds at low pH, and the organic solvent affects the nature of the denatured state under acidic conditions. The protein performs well in transesterification assays upon prolonged incubations at high methanol concentrations. BCL is highly tolerant to methanol and displays particularly high conformational stability under conditions employed for transesterification reactions. These features depict BCL as a promising enzyme for biofuel industry.     

Geotrichum candidum produces several lipases with markedly different substrate specificities.

We have purified and examined the substrate specificity of four lipases from two strains of the mould Geotrichum candidum, ATCC 34614 and CMICC 335426. We have designated the lipases I and II (ATCC 34614), and A and B (CMICC 335426). The enzymes are monomeric and have similar molecular masses and pI. Thus, lipases I and II have native molecular masses of 50.1 kDa and 55.5 kDa, and pI of 4.61 and 4.47, respectively. Lipases A and B are very similar to lipases I and II with native molecular masses of 53.7 kDa and 48.9 kDa, and pI of 4.71 and 4.50, respectively. Treatment with endo-beta-N-acetylglucosaminidase caused a reduction in molecular mass of approximately 4.5 kDa for all four lipases, indicating that these enzymes are glycosylated. Western blotting shows that the lipases are related. However, lipase B from CMICC 335426 shows a remarkable specificity for unsaturated substrates with a double bond at position 9 (cis configuration), and this specificity is not exhibited by the other three lipases. No lipase of this unique specificity has previously been purified to homogeneity. Structural studies using these four lipases should allow insight into the molecular basis of this remarkable specificity.     

Novel microbial lipases: catalytic activity in reactions in organic media

2,000 microbial strains were isolated from soil samples and tested to determine their lipolytic activity by employing screening techniques on solid and in liquid media. Culture broths were initially tested with 1,2-O-dilauryl-rac-glycero-3-glutaric acid-resorufinyl ester, a chromogenic substrate specific for lipases. Fourteen lipase-producing microorganisms were selected and their taxonomic identification was carried out. Hydrolysis of tributyrin or olive oil and the esterification of oleic acid with heptanol were selected to preliminary evaluate the catalytic activity of these lipases. All the selected lipases catalysed this esterification reaction with good yields. Resolution of (R,S)-2-(4-isobutylphenyl) propionic acid, (R,S)-1-phenylethanol, (R,S) 1-phenylethylamine and of (R) or (S) glycidol were performed to evaluate the stereoselectivity of these novel enzymes as biocatalysts in reactions in organic media. Lipases from the fungi Fusarium oxysporum and Ovadendron sulphureo-ochraceum gave the best yields and enantioselectivities in the resolution of racemic ibuprofen and 1-phenylethanol. Several lipases displayed a high stereoselectivity in the resolution of chiral amines by an alcoxycarbonylation reaction.