Engineering the genetic components of a whole-cell catalyst for improved enzymatic CO2 capture and utilization

Carbonic anhydrase (CA) is a diffusion-limited enzyme that rapidly catalyzes the hydration of carbon dioxide (CO₂). CA has been proposed as an eco-friendly yet powerful catalyst for CO₂ capture and utilization. A bacterial whole-cell biocatalyst equipped with periplasmic CA provides an option for a cost-effective CO₂-capturing system. However, further utilization of the previously constructed periplasmic system has been limited by its relatively low activity and stability. Herein, we engineered three genetic components of the periplasmic system for the construction of a highly efficient whole-cell catalyst: a CA-coding gene, a signal sequence, and a ribosome-binding site (RBS). A stable and halotolerant CA (hmCA) from the marine bacterium Hydrogenovibrio marinus was employed to improve both the activity and stability of the system. The improved secretion and folding of hmCA and increased membrane permeability were achieved by translocation via the Sec-dependent pathway. The engineering of RBS strength further enhanced whole-cell activity by improving both the secretion and folding of hmCA. The newly engineered biocatalyst displayed 5.7-fold higher activity and 780-fold higher stability at 60°C compared with those of the previously constructed periplasmic system, providing new opportunities for applications in CO₂ capture and utilization.     

Construction and characterization of a thermostable whole-cell chitinolytic enzyme using yeast surface display

To develop a novel yeast whole-cell biocatalyst by yeast surface display technology that can hydrolyze chitin, the chitinaseC gene from Serratia marcescens AS1.1652 strain was cloned and subcloned into the yeast surface display plasmid pYD1, and the recombinant plasmid pYD1/SmchiC was electroporated into Saccharomyces cerevisiae EBY100 cell. Aga2p-SmChiC fusion protein was expressed and anchored on the yeast cell surface by induction with galactose, which was verified by indirect immunofluorescence and Western blotting. The chitinolytic activity of the yeast whole-cell biocatalyst or partially purified enzyme was detected by agar plate clear zone test, SDS-PAGE zymography and dinitrosalicylic acid method. The results showed that the chitinaseC gene from S. marcescens AS1.1652 strain was successfully cloned and expressed on the yeast cell surface, Aga2p-SmChiC fusion protein with molecular weight (67 kDa) was determined. Tests on the effect of temperature and pH on enzyme activity and stability revealed that the yeast whole-cell biocatalyst and partially purified enzyme possessed both thermal stability and activity, and even maintained some activity under acidic and weakly alkaline conditions. The optimum reaction temperature and pH value were set at 52 °C and 5.0, respectively. Yeast surface display technology succeeded in preparing a yeast whole-cell biocatalyst with chitinolytic activity, and the utilization of chitin could benefit from this process of enzyme preparation.     

Synthesisof fructose laurate esters catalyzed by a CALB-displaying Pichia pastoris whole-cell biocatalyst in a non-aqueous system

Earlier studies on fructose laurate ester products have shown that recombinant Pichia pastoris displaying Candida antarctica lipase B (CALB) on the cell surface acts as an efficient whole-cell biocatalyst for sugar ester production from fructose and lauric acid in an organic solvent. The effects of various reaction factors, including solvent composition, substrate molar ratio, enzyme dose, temperature and water activity, on esterification catalyzed by the CALB-displaying P. pastoris whole-cell biocatalyst were examined in the present study. Under the preferred reaction conditions, specifically, 5 mL organic solvent mixture of 2-methyl-2-butanol/DMSO (20% v/v), 2 mmol fructose with a lauric acid to fructose molar ratio of 2:1, 0.3 g whole-cell biocatalyst (1,264 U/g dry cell) with an initial water activity of 0.11, 1.2 g 4Å molecular sieve, reaction temperature of 55oC and 200 rpm stirring speed, the fructose mono laurate ester yield was 78% (w/w). The CALBdisplaying P. pastoris whole-cell biocatalyst exhibited good operational stability, with an evident increase, rather than decrease, in relative activity after the continuous recover and reuse cycle. The relative activity of the biocatalyst remained 50% higher than that of the first batch, even following reuse for 15 batches. Our results collectively indicate that the CALB-displaying P. pastoris whole-cell biocatalyst may be potentially utilized in lieu of free or immobilized enzyme to effectively produce non-ionic surfactants such as fatty acid sugar esters, offering the significant advantages of cost-effectiveness, good operational stability and mild reaction conditions.

     

Export of functional <Emphasis Type="Italic">Streptomyces coelicolor</Emphasis> alditol oxidase to the periplasm or cell surface of <Emphasis Type="Italic">Escherichia coli</Emphasis> and its application in whole-cell biocatalysis

Streptomyces coelicolor A3(2) alditol oxidase (AldO) is a soluble monomeric flavoprotein in which the flavin cofactor is covalently linked to the polypeptide chain. AldO displays high reactivity towards different polyols such as xylitol and sorbitol. These characteristics make AldO industrially relevant, but full biotechnological exploitation of this enzyme is at present restricted by laborious and costly purification steps. To eliminate the need for enzyme purification, this study describes a whole-cell AldO biocatalyst system. To this end, we have directed AldO to the periplasm or cell surface of Escherichia coli. For periplasmic export, AldO was fused to endogenous E. coli signal sequences known to direct their passenger proteins into the SecB, signal recognition particle (SRP), or Twin-arginine translocation (Tat) pathway. In addition, AldO was fused to an ice nucleation protein (INP)-based anchoring motif for surface display. The results show that Tat-exported AldO and INP-surface-displayed AldO are active. The Tat-based system was successfully employed in converting xylitol by whole cells, whereas the use of the INP-based system was most likely restricted by lipopolysaccharide LPS in wild-type cells. It is anticipated that these whole-cell systems will be a valuable tool for further biological and industrial exploitation of AldO and other cofactor-containing enzymes.     

Coexpression of molecular chaperone enhances activity and export of organophosphorus hydrolase in Escherichia coli

Periplasmic secretion has been used in attempts to construct an efficient whole‐cell biocatalyst with greatly reduced diffusion limitations. Previously, we developed recombinant Escherichia coli that express organophosphorus hydrolase (OPH) in the periplasmic space using the twin‐arginine translocation (Tat) pathway to degrade environmental toxic organophosphate compounds. This system has the advantage of secreting protein into the periplasm after folding in the cytoplasm. However, when OPH was expressed with a Tat signal sequence in E. coli, we found that the predominant OPH was an insoluble premature form in the cytoplasm, and thus, the whole‐cell OPH activity was significantly lower than its cell lysate activity. In this work, we, for the first time, used a molecular chaperone coexpression strategy to enhance whole‐cell OPH activity by improving the periplasmic translocation of soluble OPH. We found that the effect of GroEL‐GroES (GroEL/ES) assistance on the periplasmic localization of OPH was secretory pathway dependent. We observed a significant increase in the amount of soluble mature OPH when cytoplasmic GroEL/ES was expressed; this increase in the amount of mature OPH might be due to enhanced OPH folding in the cytoplasm. Importantly, the whole‐cell OPH activity of the chaperone–coexpressing cells was ～5.5‐fold greater at 12 h after induction than that of cells that did not express the chaperone as a result of significant Tat‐based periplasmic translocation of OPH in the chaperone–coexpressing cells. Collectively, these data suggest that molecular chaperones significantly enhance the whole‐cell activity of periplasmic OPH‐secreting cells, yielding an effective whole‐cell biocatalyst system with highly reduced diffusion limitations. © 2012 American Institute of Chemical Engineers Biotechnol. Prog., 28: 925–930, 2012     

Synthesis of functional dipeptide carnosine from nonprotected amino acids using carnosinase-displaying yeast cells

Carnosine (β-alanyl-l-histidine) is one of the bioactive dipeptides and has antioxidant, antiglycation, and cytoplasmic buffering properties. In this study, to synthesize carnosine from nonprotected amino acids as substrates, we cloned the carnosinase (CN1) gene and constructed a whole-cell biocatalyst displaying CN1 on the yeast cell surface with α-agglutinin as the anchor protein. The display of CN1 was confirmed by immunofluorescent labeling, and CN1-displaying yeast cells showed hydrolytic activity for carnosine. When carnosine was synthesized by the reverse reaction of CN1, organic solvents were added to the reaction mixture to reduce the water content. The CN1-displaying yeast cells were lyophilized and examined for organic solvent tolerance. Results showed that the CN1-displaying yeast cells retained their original hydrolytic activity in hydrophobic organic solvents. In the hydrophobic organic solvents and hydrophobic ionic liquids, the CN1-displaying yeast cells catalyzed carnosine synthesis, and carnosine was synthesized from nonprotected amino acids in only one step. The results of this research suggest that the whole-cell biocatalyst displaying CN1 on the yeast cell surface can be used to synthesize carnosine with ease and convenience.     

Bacterial cell surface display of lipase and its randomly mutated library facilitates high-throughput screening of mutants showing higher specific activities

The thermostable lipase (TliA) from Pseuodmonas fluorescens was functionally displayed on the surface of Escherichia coli using the ice-nucleation protein (INP) as an anchor. The INP–TliA fusion proteins were correctly synthesized and localized on the surface, confirmed by flow cytometer and halo forming activity on tributyrin emulsion agar plate. Lipase-displaying cells were used as an alternative immobilized biocatalyst to hydrolyze olive oil in aqueous–organic solvent two phases reaction. Furthermore, the randomly generated library of TliA was also displayed on E. coli. In order to be able to screen mutants showing increased specific activities, we optimized culture conditions, induction condition and host cell types. From more than 10⁵ members of library, top four mutants were selected. Selected clones of T48, T54, T61, and T68 showed 29-, 24-, 2-, and 19-fold increases, respectively, in whole-cell activities compared to wild-type enzyme. The DNA sequencing showed that one or three amino acids were exchanged and positions critical for increased activities were random. These results demonstrate that surface display provide a useful technology for directed evolution of industrially important lipases.     

Transgalactosylation in a water-solvent biphasic reaction system with beta-galactosidase displayed on the surfaces of Bacillus subtilis spores

The ever-increasing industrial demand for biocatalysis necessitates innovations in the preparation and stabilization of biocatalysts. In this study, we demonstrated that beta-galactosidase (beta-Gal) displayed on Bacillus spores by fusion to the spore coat proteins (CotG) may be used as a whole-cell immobilized biocatalyst for transgalactosylation in water-solvent biphasic reaction systems. The resulting spores had a specific hydrolytic activity of 5 x 10(3) U/g (dry weight) of spores. The beta-Gal was tightly attached to the spore surface and was more stable in the presence of various organic solvents than its native form was. The thermostability of the spore-displayed enzyme was also increased, and the enzyme was further stabilized by chemically cross-linking it with glutaraldehyde. With spore-displayed beta-Gal, octyl-beta-D-galactopyranoside was synthesized at concentrations up to 27.7 mM (8.1 g/liter) with a conversion yield of 27.7% (wt/wt) after 24 h from 100 mM lactose and 100 mM octanol dissolved in phosphate buffer and ethyl ether, respectively. Interestingly, the spores were found to partition mainly at the interface between the water and solvent phases, and they were more available to catalysis between the two phases, as determined by light microscopy and confocal fluorescence microscopy. We propose that spore display not only offers a new and facile way to construct robust biocatalysts but also provides a novel basis for phase transfer biocatalytic processes.     

Functional periplasmic secretion of organophosphorous hydrolase using the twin-arginine translocation pathway in Escherichia coli

Recombinant Escherichia coli systems expressing organophosphorous hydrolase (OPH) have been proposed for biotransformation of toxic organophosphate compounds. However, whole cell biocatalyst systems are critically disadvantaged due to substrate diffusion limitations. To enhance whole cell biocatalytic efficiency, we engineered E. coli, for the first time, to secrete metal ion cofactor-requiring OPH into the periplasmic space using the twin-arginine translocation (Tat) pathway. In particular, the twin-arginine signal sequence of E. coli trimethylamine N-oxide (TMAO) reductase (TorA) was employed. Even though total OPH activity in the cell lysate fraction was lower in the periplasmic-secreting strain than in the control cytosolic-expressing strain, whole cell OPH activity was approximately 2.8-fold higher due to successful translocation of OPH into the periplasmic space. In addition, whole cell OPH activity in the periplasmic-secreting strain was far more stable than that in the cytosolic-expressing strain. Therefore, Tat-driven periplasmic-secreting E. coli can be successfully employed as efficient whole cell biocatalysts.     

A robust whole-cell biocatalyst that introduces a thermo- and solvent-tolerant lipase into Aspergillus oryzae cells: Characterization and application to enzymatic biodiesel production

To develop a robust whole-cell biocatalyst that works well at moderately high temperature (40–50 °C) with organic solvents, a thermostable lipase from Geobacillus thermocatenulatus (BTL2) was introduced into an Aspergillus oryzae whole-cell biocatalyst. The lipase-hydrolytic activity of the immobilized A. oryzae (r-BTL) was highest at 50 °C and was maintained even after an incubation of 24-h at 60 °C. In addition, r-BTL was highly tolerant to 30% (v/v) organic solvents (dimethyl carbonate, ethanol, methanol, 2-propanol or acetone). The attractive characteristics of r-BTL also worked efficiently on palm oil methanolysis, resulting in a nearly 100% conversion at elevated temperature from 40 to 50 °C. Moreover, r-BTL catalyzed methanolysis at a high methanol concentration without a significant loss of lipase activity. In particular, when 2 molar equivalents of methanol were added 2 times, a methyl ester content of more than 90% was achieved; the yield was higher than those of conventional whole-cell biocatalyst and commercial Candida antarctica lipase (Novozym 435). On the basis of the results regarding the excellent lipase characteristics and efficient biodiesel production, the developed whole-cell biocatalyst would be a promising biocatalyst in a broad range of applications including biodiesel production.     

脂肪酶的表面展示及其应用

脂肪酶是一种广泛应用的水解酶类。脂肪酶的表面展示技术不仅是脂肪酶蛋白质工程中一种有效的高通量筛选方法,而且展示的脂肪酶与自由酶相比具备更高的温度稳定性、有机溶剂稳定性等优点,其作为全细胞催化剂与传统的固定化脂肪酶相比也具备诸多优点。脂肪酶表面展示的宿主包括噬菌体、细菌以及酵母等,本文将分别介绍这三种宿主中脂肪酶表面展示的概况以及其作为高通量筛选和全细胞等方面的应用。     

解脂耶氏酵母脂肪酶Lip2的表面展示及其酶学性质

表面展示酶作为全细胞催化剂具备诸如能提高酶的稳定性、省去纯化过程、节约成本等优点。脂肪酶是应用最为广泛的工业酶之一。本研究利用酿酒酵母细胞壁蛋白Cwp2作为锚定蛋白,将解脂耶氏酵母脂肪酶Lip2展示在酿酒酵母细胞表面,以制备脂肪酶全细胞催化剂。Lip2被融合到Cwp2的N端,Cwp2通过其C端的GPI锚定信号共价结合到细胞壁上。表面展示的Lip2可以水解三丁酸甘油酯及对硝基苯酚辛酸酯(pNPC),其pNPC水解酶活达到4.6U/g干细胞。作为全细胞催化剂,表面展示的Lip2具备良好的催化特征,其最适温度为40°C,最适pH为8.0,同时还具备良好的有机溶剂稳定性。     

Periplasmic expression of a Saccharophagus cellodextrinase enables E. coli to ferment cellodextrin

Metabolic engineering has been successful in generating highly efficient Escherichia coli catalysts for production of biofuels and other useful products. However, most of these engineered biocatalysts are only effective when glucose is used as the starting substrate. Strategies to overcome this limitation in the past almost exclusively relied on extracellular secretion or surface display of a β-glucosidase. We show here, for the first time, a periplasmic expression of a Sacchrophagus degradans cellodextrinase (Ced3A) as a successful strategy to enable E. coli to use cellodextrin. The engineered strain was able to grow with cellodextrin as sole carbon source. Additionally, we show that penetration of cellodextrin into periplasmic space was enhanced by using a mutant with leaky outer membrane. Furthermore, we demonstrate that the catalyst can efficiently ferment cellodextrin to lactic acid with about 80 % yield. The ability of a biocatalyst to use cellodextrin should make it useful in consolidated bioprocessing of cellulose.     

Cell surface display of lipase in Pseudomonas putida KT2442 using OprF as an anchoring motif and its biocatalytic applications

We developed a new cell surface display system in Pseudomonas putida KT2442 using OprF, an outer membrane protein of Pseudomonas aeruginosa, as an anchoring motif in a C-terminal deletion-fusion strategy. The Pseudomonas fluorescens SIK W1 lipase gene was fused to two different C-terminal truncated OprF genes, and the fusion genes were cloned into the broad-host-range plasmid pBBR1MCS2 to make pMO164PL and pMO188PL. Plasmid pMO188PL allowed better display of lipase and thus was chosen for further study. The display of lipase on the surface of P. putida KT2442 was confirmed by Western blot analysis, immunofluorescence microscopy, and measurement of whole-cell lipase activity. The whole-cell lipase activity of recombinant P. putida KT2442 harboring pMO188PL was more than fivefold higher than that of recombinant Escherichia coli displaying lipase in the same manner. Cell surface-displayed lipase exhibited the highest activity at 47 degrees C and pH 9.0, and the whole-cell lipase activity was greater than 90% of the initial activity in organic solvents at 47 degrees C for 1 week. In a biocatalytic application, enantioselective resolution of 1-phenyl ethanol was carried out in an organic solvent. (R)-Phenyl ethyl acetate was successfully produced with 41.9% conversion and an enantiomeric excess of more than 99% in a 36-h reaction. These results suggest that the OprF anchor can be used for efficient display of proteins in P. putida KT2442 and consequently for various biocatalytic applications.     

Autodisplay of an archaeal γ-lactamase on the cell surface of Escherichia coli using Xcc_Est as an anchoring scaffold and its application for preparation of the enantiopure antiviral drug intermediate (−) vince lactam

At present, autotransporter protein mediated surface display has opened a new dimension in the development of whole-cell biocatalysts. Here, we report the identification of a novel autotransporter Xcc_Est from Xanthomonas campestris pv campestris 8004 by bioinformatic analysis and application of Xcc_Est as an anchoring motif for surface display of γ-lactamase (Gla) from thermophilic archaeon Sulfolobus solfataricus P2 in Escherichia coli. The localization of γ-lactamase in the cell envelope was monitored by Western blot, activity assay and flow cytometry analysis. Either the full-length or truncated Xcc_Est could efficiently transport γ-lactamase to the cell surface. Compared with the free enzyme, the displayed γ-lactamase exhibited optimum temperature of 30 °C other than 90 °C, with a substantial decrease of 60 °C. Under the preparation system, the engineered E. coli with autodisplayed γ-lactamase converted 100 g racemic vince lactam to produce 49.2 g (?) vince lactam at 30 °C within 4 h. By using chiral HPLC, the ee value of the produced (?) vince lactam was determined to be 99.5 %. The whole-cell biocatalyst exhibited excellent stability under the operational conditions. Our results indicate that the E. coli with surface displayed γ-lactamase is an efficient and economical whole cell biocatalyst for preparing the antiviral drug intermediate (?) vince lactam at mild temperature, eliminating expensive energy cost performed at high temperature.     

Effect of pretreatment of hydrothermally processed rice straw with laccase-displaying yeast on ethanol fermentation

A gene encoding laccase I was identified and cloned from the white-rot fungus Trametes sp. Ha1. Laccase I contained 10 introns and an original secretion signal sequence. After laccase I without introns was prepared by overlapping polymerase chain reaction, it was inserted into expression vector pULD1 for yeast cell surface display. The oxidation activity of a laccase-I-displaying yeast as a whole-cell biocatalyst was examined with 2,2′-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid) (ABTS), and the constructed yeast showed a high oxidation activity. After the pretreatment of hydrothermally processed rice straw (HPRS) with laccase-I-displaying yeast with ABTS, fermentation was conducted with yeast codisplaying endoglucanase, cellobiohydrolase, and β-glucosidase with HPRS. Fermentation of HPRS treated with laccase-I-displaying yeast was performed with 1.21-fold higher activities than those of HPRS treated with control yeast. The results indicated that pretreatment with laccase-I-displaying yeast with ABTS was effective for direct fermentation of cellulosic materials by yeast codisplaying endoglucanase, cellobiohydrolase, and β-glucosidase.     

Surface display of transglucosidase on Escherichia coli by using the ice nucleation protein of Xanthomonas campestris and its application in glucosylation of hydroquinone

A surface anchoring motif using the ice nucleation protein (INP) of Xanthomonas campestris pv. campestris BCRC 12,846 for display of transglucosidase has been developed. The transglucosidase gene from Xanthomonas campestris pv. campestris BCRC 12,608 was fused to the truncated ina gene. This truncated INP consisting of N- and C-terminal domains (INPNC) was able to direct the expressed transglucosidase fusion protein to the cell surface of E. coli with apparent high enzymatic activity. The localization of the truncated INPNC-transglucosidase fusion protein was examined by Western blot analysis and immunofluorescence labeling, and by whole-cell enzyme activity in the glucosylation of hydroquinone. The glucosylation reaction was carried out at 40 degrees C for 1 h, which gave 23 g/L of alpha-arbutin, and the molar conversion based on the amount of hydroquinone reached 83%. The use of whole-cells of the wild type strain resulted in an alpha-arbutin concentration of 4 g/L and a molar conversion of 16% only under the same conditions. The results suggested that E. coli displaying transglucosidase using truncated INPNC as an anchoring motif can be employed as a whole-cell biocatalyst in glucosylation.     

Effects of acute and chronic methylphenidate administration on beta-endorphin, growth hormone, prolactin and cortisol in children with attention deficit disorder and hyperactivity

The effect of 5 mg/p.o. methylphenidate (MPH) challenge on beta-endorphin (beta-EP), growth hormone (GH), prolactin (Prl) and cortisol was investigated in 16 children suffering from attention deficit disorder with hyperactivity (ADDH) before and after 4 weeks MPH treatment. The study population consisted of 13 males and 3 females aged 6-11 years. All patients were drug free for at least 3 months prior to investigation. The severity of ADDH symptomatology and response to MPH chronic treatment was assessed using parent/teacher abbreviated Conners rating scale. Blood samples for beta-EP, cortisol, Prl and GH were drawn before initiation of treatment (basal pre-treatment level), 2 hours after MPH challenge, 4 weeks after MPH treatment (basal post-treatment level) and 2 hours after re-challenge with MPH. Chronic MPH treatment resulted in a decrease in basal Prl levels (5.5 +/- 2.8 vs 3.7 +/- 1.9 ng/ml; p less than 0.05). Pre-treatment challenge stimulates significantly both beta-EP (15.0 +/- 7.5 vs 12.5 +/- 5.3 pmol/l; p less than 0.05) and cortisol secretion (20.6 +/- 6.6 vs 12.6 +/- 5.8 micrograms/dl; p less than 0.05), and suppressed Prl secretion (4.0 +/- 1.5 vs 5.5 +/- 2.8 ng/ml; p less than 0.05). Re-challenge with MPH enhanced beta-EP levels (14.9 +/- 8.6 vs 10.6 +/- 5.0 pmol/l; p less than 0.05) but failed to affect cortisol, Prl and GH secretion. The acute and chronic neuroendocrine effects of MPH administration might be related to its dopaminergic and adrenergic agonistic activity. It might be that the stimulatory effect of single and repeated acute MPH administration on beta-EP release contributes to the beneficial effect of MPH treatment in ADDH children.     

The efficiency of recombinant Escherichia coli as biocatalyst for stereospecific epoxidation

Styrene is efficiently converted into (S)-styrene oxide by growing Escherichia coli expressing the styrene monooxygenase genes styAB of Pseudomonas sp. strain VLB120 in an organic/aqueous emulsion. Now, we investigated factors influencing the epoxidation activity of recombinant E. coli with the aim to improve the process in terms of product concentration and volumetric productivity. The catalytic activity of recombinant E. coli was not stable and decreased with reaction time. Kinetic analyses and the independence of the whole-cell activity on substrate and biocatalyst concentrations indicated that the maximal specific biocatalyst activity was not exploited under process conditions and that substrate mass transfer and enzyme inhibition did not limit bioconversion performance. Elevated styrene oxide concentrations, however, were shown to promote acetic acid formation, membrane permeabilization, and cell lysis, and to reduce growth rate and colony-forming activity. During biotransformations, when cell viability was additionally reduced by styAB overexpression, such effects coincided with decreasing specific epoxidation rates and metabolic activity. This clearly indicated that biocatalyst performance was reduced as a result of product toxicity. The results point to a product toxicity-induced biological energy shortage reducing the biocatalyst activity under process conditions. By reducing exposure time of the biocatalyst to the product and increasing biocatalyst concentrations, volumetric productivities were increased up to 1,800 micromol/min/liter aqueous phase (with an average of 8.4 g/L(aq) x h). This represents the highest productivity reported for oxygenase-based whole-cell biocatalysis involving toxic products.     

Preparation of a whole-cell biocatalyst of mutated <Emphasis Type="Italic">Candida antarctica</Emphasis> lipase B (mCALB) by a yeast molecular display system and its practical properties

To prepare a whole-cell biocatalyst of a stable lipase at a low price, mutated Candida antarctica lipase B (mCALB) constructed on the basis of the primary sequences of CALBs from C. antarctica CBS 6678 strain and from C. antarctica LF 058 strain was displayed on a yeast cell surface by α-agglutinin as the anchor protein for easy handling and stability of the enzyme. When mCALB was displayed on the yeast cell surface, it showed a preference for short chain fatty acids, an advantage for producing flavors; although when Rhizopus oryzae lipase (ROL) was displayed, the substrate specificity was for middle chain lengths. When the thermal stability of mCALB on the cell surface was compared with that of ROL on a cell surface, T _1/2, the temperature required to give a residual activity of 50% for heat treatment of 30 min, was 60°C for mCALB and 44°C for ROL indicating that mCALB displayed on cell surface has a higher thermal stability. Furthermore, the activity of the displayed mCALB against p-nitrophenyl butyrate was 25-fold higher than that of soluble CALB, as reported previously. These findings suggest that mCALB-displaying yeast is more practical for industrial use as the whole-cell biocatalyst.