Improving the industrial production of 6-APA: enzymatic hydrolysis of penicillin G in the presence of organic solvents

The hydrolysis of penicillin G in the presence of an organic solvent, used with the purpose of extracting it from the culture medium, may greatly simplify the industrial preparation of 6-APA. However, under these conditions, PGA immobilized onto Eupergit displays very low stability (half-life of 5 h in butanone-saturated water) and a significant degree of inhibition by the organic solvent (30%). The negative effect of the organic solvent strongly depended on the type of solvent utilized: water saturated with butanone (around 28% v/v) had a much more pronounced negative effect than that of methylisobutyl ketone (MIBK) (solubility in water was only 2%). These problems were sorted out by using a new penicillin G acylase derivative designed to work in the presence of organic solvents (with each enzyme molecule surrounded by an hydrophilic artificial environment) and a suitable organic solvent (MIBK). Using such solvent, this derivative kept its activity unaltered for 1 week at 32 degrees C. Moreover, the enzyme activity was hardly inhibited by the presence of the organic solvent. In this way, the new enzyme derivative thus prepared enables simplification of the industrial hydrolysis of penicillin G.     

Ribosomal DNA variation in the grasshopper, Dichroplus elongatus.

We report an RFLP analysis of ribosomal DNA variation in natural populations of the grasshopper, Dichroplus elongatus, previously analyzed for mitochondrial DNA variation. DNA samples were digested with five restriction enzymes, BamHI, EcoRI, HindIII, PstI, and XbaI. BamHI was the only enzyme that showed no variation. The remaining enzymes showed fragment size variation at both intra- and interpopulation levels. Stepwise regression analysis revealed that the average number of length variants per individual is significantly associated with altitude. Moreover, the same analysis indicated that the frequency of some restriction variants exhibits a significant regression on both geographic and climatic variables. The intra- and interpopulation variability of rDNA was analysed by Lynch's and Hedrick's similarity indices using presence or absence of a fragment and band intensities, respectively. The corresponding neighbour-joining (N-J) trees based on Lynch's and Hedrick's genetic distances resulted in similar topologies. However, these trees were not in agreement with the N-J dendrogram obtained from mtDNA data previously reported by Clemente et al. (2000). The disagreement between mtDNA and rDNA phenograms along with the observed correlation between rDNA variability and geographical and climatic variables suggest some form of selection, besides genetic drift and migration, is involved in the pattern of rDNA variation.     

Semi-rational engineering of an amino acid racemase that is stabilized in aqueous/organic solvent mixtures

Enzymes are industrially applied under increasingly diverse environmental conditions that are dictated by the efforts to optimize overall process efficiency. Engineering the operational stability of biocatalysts to enhance their half-lives under the desired process conditions is a widely applied strategy to reduce costs. Here, we present a simple method to enhance enzyme stability in the presence of monophasic aqueous/organic solvent mixtures based on the concept of strengthening the enzyme's surface hydrogen-bond network by exchanging surface-located amino acid residues for arginine. Suitable residues are identified from sequence comparisons with homologous enzymes from thermophilic organisms and combined using a shuffling approach to obtain an enzyme variant with increased stability in monophasic aqueous/organic solvent mixtures. With this approach, we increase the stability of the broad-spectrum amino acid racemase of Pseudomonas putida DSM 3263 eightfold in mixtures with 40% methanol and sixfold in mixtures with 30% acetonitrile.     

Thermolysin and alpha-chymotrypsin mediated synthesis of tripeptides containing proline

The tripeptides Z-Pro-Leu-Gly-OEt, Z-Pro-Leu-Gly-NH2 and Z-Pro-Leu-Gly-OBzl were synthesized by thermolysin and alpha-chymotrypsin catalysis. The optimum conditions for the couplings between Z-Pro-OH and H-Leu-OEt or H-Leu-Gly-OEt catalysed by thermolysin were determined by a systematic study involving analysis of pH effect, ammonium sulfate concentration, reaction time, enzyme concentration, and relative proportion of the carboxyl and amine components. The best yield obtained for Z-Pro-Leu-OEt was 77% and for Z-Pro-Leu-Gly-OEt, 100%. Z-Pro-Leu-OEt was coupled to H-Gly-OEt, H-Gly-NH2 and H-Gly-OBzl. The best conditions to obtain Z-Pro-Leu-Gly-OEt and Z-Pro-Leu-Gly-NH2 were determined by the study of some factors that affect the reaction yield, such as organic solvent presence, substrate ratio and aqueous and organic solvent ratio. The yield obtained under optimum synthesis conditions was 55% for Z-Pro-Leu-Gly-OEt and 61% for Z-Pro-Leu-Gly-NH2. Z-Pro-Leu-Gly-OBzl was synthesized with 42% yield.     

Restriction map of virulence plasmid in Yersinia enterocolitica O:3

Restriction map of the 72-kb virulence plasmid isolated from Yersinia enterocolitica O:3 was generated using EcoRI, BamHI, HindIII, and XbaI restriction enzymes. The mapping was done after cloning all of the 13 BamHI fragments of the plasmid in Escherichia coli. In addition, the restriction enzyme analysis revealed two types of virulence plasmids (types I and II) in Y. enterocolitica O:3. No functional differences between the strains bearing type I or type II plasmid were observed.     

Physical crosslinking of lipase from Rhizomucor miehei immobilized on octyl agarose via coating with ionic polymers: Avoiding enzyme release from the support

Lipase from Rhizomucor miehei (RML) was immobilized on octyl-agarose (OC) at different loadings. Using low enzyme loadings (1/7 of the maximum loading), the incubation of the enzyme with polyethylenimine (PEI) increased the resistance to enzyme desorption in the presence of Triton X-100. However, more than 10% of the enzyme activity could be released from the OC-RML-PEI. The same treatment using fully loaded biocatalyst reduced the enzyme desorption to less than 5%. Further treatment with dextran sulfate (DS) of the PEI treaded immobilized enzyme fully avoids the enzyme desorption even in presence of a Triton X-100 concentration higher than that required for the complete enzyme release from OC-RML. This treatment produced a high stabilization of OC-RML in thermal or organic solvent inactivations, reducing the enzyme release under these drastic conditions. Nevertheless, the support could be recovered by incubation under adequate conditions, and reused in several adsorption/desorption cycles. Thus, the strategy permitted to avoid enzyme desorption, very likely by physical intermolecular crosslinking improving enzyme stability, while still maintaining the reversibility of the immobilization.     

Purification and properties of hog liver 4-hydroxyphenylpyruvate dioxygenase

The purification of hog liver 4-hydroxyphenylpyruvate dioxygenase (EC 1.13.11.27), and the determination of some of its characteristics, are reported. The enzyme was purified 330-fold in 22% yield from an acetone powder extract by ammonium sulfate fractionation, chromatography twice using sulfopropyl Sephadex under carefully controlled pH conditions (once at pH 5.36 and a second time with a pH gradient from 5.25 to 5.80), and a final chromatography on DEAE-cellulose. The purified enzyme was found to be homogeneous by several standard criteria, but activity measurements indicated that a small amount (less than 5%) of a carboxylesterase (EC 3.1.1.1) isoenzyme is present as a minor impurity. On long-term storage at ?20 °C the enzyme forms polymers but this can be reversed with thiols. The molecular weight of the freshly prepared or depolymerized enzyme was estimated to be 89,000 ± 2000 by equilibrium ultracentrifugation, and 50,000 to 54,000 by gel filtration. Sodium dodecyl sulfate-gel electrophoresis experiments, performed in the presence and absence of mercaptoethanol, indicate that the enzyme is composed of two nonidentical subunits with similar molecular weights (44,000 ± 2000). The enzyme gives a typical protein ultraviolet absorption spectrum with no noticeable peaks above 300 nm, it has no detectable carbohydrate content, and it contains 0.9 atom iron and 0.4 atom copper/89,000 daltons. Added iron and copper salts activate the enzyme to some extent but by less than a factor of 2. The enzymatic reaction has a large temperature coefficient (the rate increases ca. fivefold for each 10 °C rise) and is markedly stimulated (up to sixfold) by the presence of some organic solvents in concentrations up to 10% of the medium. These results suggest that a protein conformation change, possibly aided by binding of the organic solvent, is involved in the rate-determining step of the reaction. The similarities and differences of this 4-hydroxyphenylpyruvate dioxygenase to those from other sources, and to prolyl hydroxylase, are discussed.     

Deciphering the molecular structure of cryptolepain in organic solvents

Solvent composition plays a major role in stabilizing/destabilizing the forces that are responsible for the native structure of a protein. Often, the solvent composition drives the protein into non-native conformations. Elucidation of such non-native structures provides valuable information about the molecular structure of the protein, which is unavailable otherwise. Inclusion of methanol (non-fluorinated alcohol) or TFE (fluorinated alcohol) in the solvent composition drove cryptolepain, a serine protease and an all-β-protein, into a non-native structure with an enhanced β-sheet or induction of α-helix. These solvents did not much affect cryptolepain under neutral conditions, even at higher concentrations, but the effects were predominant at lower pH, when the protein molecule is under stress. The organic solvent-induced state is partially unfolded with similar characteristics to the molten globule state seen with protein under a variety of conditions. Chemical- or temperature-induced unfolding of cryptolepain in the presence of organic solvent is distinctly different from that in the absence of organic solvent. Such different unfolding provided evidence of two structural variants in the molecular structure of the protein as well as the differential stabilization/destabilization of such structural variants and their sequential unfolding.     

Simian adenovirus genome. II. Identification of specific fragments of viral DNA possessing transforming activity

The antigenic variant of simian adenovirus 7 (SA7) DNA was cleaved by restriction endonucleases EcoRI, XbaI, BamHI, SalI. The resulted digests of viral DNA were tested for transforming activity using the "calcium" technique. It was shown that BamHI. XbaI and SalI digests transformed primary baby rat kidney cells as well as native viral DNA. The transforming activity of separated BamHI and SalI fragments was tested also. The viral DNA fragments with transforming activity (BamHI-B and SalI-B) were localised on the left of the physical map of the viral genome. It was also shown that fragment-transformed cell lines were able to form colonies in 0.33% agarose medium.     

Identification and characterization of a new replication region in the Neisseria gonorrhoeae beta-lactamase plasmid pFA3.

The 7.1-kilobase-pair (kbp) plasmid pFA3 specifies TEM beta-lactamase production in Neisseria gonorrhoeae. We studied the minimal region required for replication of this plasmid in Escherichia coli by constructing a set of nested deletions of the 3.4-kbp PstI-HindIII fragment. The smallest fragment capable of maintenance in E. coli when ligated to a streptomycin-spectinomycin resistance cassette was 2.0 kbp in size and was different from another autonomously replicating fragment of pFA3 reported by K. H. Yeung and J. Dillon (Plasmid 20:232-240, 1988). The fragment contained single BamHI and XbaI sites and specified a 39-K protein. Fragments subcloned from the minimal region or constructed by deletion from the 3' or 5' ends were not capable of autonomous replication. Mutants constructed by end filling and religating DNA cleaved at the BamHI or XbaI sites were not capable of autonomous replication and no longer produced the 39K protein. These results suggest that replication is dependent on the 39K protein. DNA sequence analysis of the region showed an A-T-rich region followed by four 22-bp direct repeats followed by an open reading frame encoding a 39K basic protein.     

Map of restriction sites on bacteriophage T4 cytosine-containing DNA for endonucleases bamHI, BglII, KpnI, PvuI, SalI, and XbaI.

A complete map of the cleavage sites of restriction endonucleases BamHI, BglII, KpnI, PvuI, SalI, and XbaI was determined for the cytosine-containing DNA of a bacteriophage T4 alc mutant. The 56 sequence-specific sites were assigned map coordinates based on a least-squares analysis of measured fragment lengths. Altogether, the lengths of 118 fragments from single and double enzyme digestions were measured by electrophoresis of the fragments in agarose gels. DNA fragments of known sequence or DNA fragments calibrated with fragments of known sequence were used as standards. The greatest deviation between an experimentally measured fragment length and its computed map coordinates was 3.0%; the average deviation was 0.8%. The total length of the wild-type T4 genome was calculated to be 166,200 base pairs.     

New versatile cloning and sequencing vectors based on bacteriophage M13

A new pair of cloning and sequencing vectors based on bacteriophage M13mp7 has been developed. These vectors (M13tg130 and M13tg131) contain, in addition to the EcoRI, BamHI, HindIII, SmaI, SalI and PstI sites present in other vectors [cf., M13mp8 and M13mp9, Messing and Vieira, Gene 19 (1982) 269-276], unique restriction recognition sequences for the enzymes EcoRV, KpnI, SphI, SstI and XbaI. A restriction site for the enzyme BglII has been incorporated into the polylinker region of one of the vector pair to permit rapid discrimination between the two vectors.     

Prevention of interfacial inactivation of enzymes by coating the enzyme surface with dextran-aldehyde

Interactions between soluble enzymes and interfaces of organic solvent drops or gas bubbles have a very negative effect on the operational stability of the soluble enzymes. In this study, the formation of a hydrophilic shell around the enzyme has been attempted using dextran-aldehyde which would prevent the interaction between enzyme and hydrophobic interfaces with minimal modification of the enzyme surface. After optimizing the size of the dextran (that was found to play a critical role), three different enzymes (glucose oxidase, d-amino acid oxidase, and trypsin) have been conjugated with dextran-aldehyde and their stability towards organic-aqueous and air-liquid interfaces has been evaluated. The treatment itself proved to be very low-cost in terms of activity and was highly stabilizing for the three enzymes assayed. The conjugated preparation of the three assayed enzymes remained fully active in the presence of air-liquid interfaces for at least 10h. However, the unmodified enzymes lost more than 50% of activity within the first hour of the experiments except for trypsin which kept 38% activity after 12h while the trypsin dextran-aldehyde conjugate maintained 100% enzyme activity. Similar results were achieved in the presence of stirred organic solvent-aqueous buffer biphasic system, although in this case some activity was lost by the action of the soluble portion of the organic solvent. In fact, this treatment seems to be also effective to improve the resistance to the action of organic solvent.     

Effect of organic solvents on the activity and stability of halophilic alcohol dehydrogenase (ADH2) from Haloferax volcanii

The effect of various organic solvents on the catalytic activity, stability and substrate specificity of alchohol dehydrogenase from Haloferax volcanii (HvADH2) was evaluated. The HvADH2 showed remarkable stability and catalysed the reaction in aqueous?Corganic medium containing dimethyl sulfoxide (DMSO) and methanol (MeOH). Tetrahydrofuran and acetonitrile were also investigated and adversely affected the stability of the enzyme. High concentration of salt, essential to maintain the enzymatic activity and structural integrity of the halophilic enzyme under standard conditions may be partially replaced by DMSO and MeOH. The presence of organic solvents did not induce gross changes in substrate specificity. DMSO offered a protective effect for the stability of the enzyme at nonoptimal pHs such as 6 and 10. Salt and solvent effects on the HvADH2 conformation and folding were examined through fluorescence spectroscopy. The fluorescence findings were consistent with the activity and stability results and corroborated the denaturing properties of some solvents. The intrinsic tolerance of this enzyme to organic solvent makes it highly attractive to industry.     

Purification and characterization of solvent stable,alkaline protease from Bacillus firmus CAS 7 by microbial conversion of marine wastes and molecular mechanism underlying solvent stability

A marine bacterium Bacillus firmus CAS 7 produced protease in the medium supplemented with 3:1 shrimp and crab shell powder at 55 °C and was purified with the specific activity of 473.4 U/mg. The purified protease was highly stable up to 70 °C, pH 11.0 and 30% NaCl. The protease purified was quite stable in the presence of anionic and non-ionic surfactants and organic solvents. The molecular dynamics simulation confirmed that the competition between organic solvent and water for the enzyme surface was comparatively higher in water–miscible organic solvent which is responsible for organic solvent stability. The purified protease from B. firmus CAS 7 could be greatly useful to develop industrial processes performed under harsh conditions or with denaturants and organic solvents. The protease production by microbial conversion of marine wastes suggested its potential utilization to generate high value-added products.     

Simian adenovirus 20 genome. I. DNA mapping using restriction enconucleases BamHI, EcoRi, XbaI, HindIII

The effect of specific restriction endonuclease on the simian adenovirus SV20 DNA was studied. It was shown that endonucleases SalI, XbaI, EcoRI, BamHI, HindIII cleaved the viral DNA into 3, 4, 5, 5, 8 specific fragments respectively. The sequence of fragments (physical map) was determined and found to be B-C-A for enzyme SalI, C-D-B-A--for enzyme Xbal, E-A-C-D-B--for enzyme EcoRI, B-E-C-A-D--for enzyme BamHI and B-E-A-C-(GH)-D-F--for enzyme HindIII. The G-C content of specific fragments was studied. The "right"-"left" orientation of the physical map of the simian adenovirus 20 DNA based on the G-C content was made in respect with the nomenclature of human adenoviruses.     

Reactivation of covalently immobilized lipase from Thermomyces lanuginosus

Lipase from Thermomyces lanuginosus (TLL) immobilized on cyanogen bromide agarose (CNBr) may be fully inactivated when incubated in saturated solutions of guanidine. When this inactivated enzyme is re-incubated in aqueous medium, 20% of the activity may be recovered for several cycles. However, if the activity was determined in the presence of a detergent (CTAB, an activator of this enzyme), 100% of the initial activity in the presence of detergent was recovered. The enzyme was also inactivated in the presence of organic solvents and at high temperatures. Inactivations were more rapid when the activity was determined in absence of detergent. In both cases, some activity could be recovered just by incubation under mild conditions, and this increase was higher if the activity measurements were performed in the presence of CTAB. These results suggested that the opening of the lipase could be a critical step in the inactivation or reactivation of immobilized TLL. In inactivations in the presence of solvents, 100% of activity could be recovered during several cycles, while in thermal inactivations, the recovered activity decreased in each inactivation–reactivation cycle. The incubation of the enzyme inactivated by temperature in guanidine improved the results, but still 100% could not be achieved during several cycles even measured in the presence of CTAB.Thus, the simple incubation of the partially or fully inactivated enzyme under mild conditions permitted to recover some activity (enhancing the half life of the biocatalysts), even in thermal inactivations.     

Effects of organic solvents on the enzyme activity of Trypanosoma cruzi glyceraldehyde-3-phosphate dehydrogenase in calorimetric assays

In drug discovery programs, dimethyl sulfoxide (DMSO) is a standard solvent widely used in biochemical assays. Despite the extensive use and study of enzymes in the presence of organic solvents, for some enzymes the effect of organic solvent is unknown. Macromolecular targets may be affected by the presence of different solvents in such a way that conformational changes perturb their active site structure accompanied by dramatic variations in activity when performing biochemical screenings. To address this issue, in this work we studied the effects of two organic solvents, DMSO and methanol (MeOH), in the isothermal titration calorimetry (ITC) kinetic assays for the catalyzed reaction of glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from Trypanosoma cruzi. The solvent effects on T. cruzi GAPDH had not yet been studied. This enzyme was shown here to be affected by the organic solvents content up to 5.0% for MeOH and up to 7.5% for DMSO. The results show that when GAPDH is assayed in the presence of DMSO (5%, v/v) using the ITC experiment, the enzyme exhibits approximately twofold higher activity than that of GAPDH with no cosolvent added. When MeOH (5%, v/v) is the cosolvent, the GAPDH activity is sixfold higher. The favorable effects of the organic solvents on the Michaelis-Menten enzyme-substrate complex formation ensure the consistency of the biological assays, structural integrity of the protein, and reproducibility over the measurement time. The reaction was also kinetically monitored by standard spectrophotometric assays to establish a behavioral performance of T. cruzi GAPDH when used for screening of potential inhibitors.     

Effect of the immobilization protocol on the properties of lipase B from Candida antarctica in organic media: Enantiospecifc production of atenolol acetate

In this work, we intend to check the effect of the immobilization protocol on the performance of lipase B from Candida antarctica (CalB) in organic medium. To this purpose, CalB has been immobilized on Eupergit C (EC) under different conditions and on EC partially modified with ethylenediamine (EDA), iminodiacetic acid (IDA) or metal chelate (IDA-Cu²⁺) and used for kinetic resolution of (R/S) 4-[2-hydroxy-3-[(1-methylethyl)amino]propoxy]benzeneacetamide (rac-atenolol). Enantiomeric resolution of atenolol was carried out by a transesterification reaction using vinyl acetate as acylant agent and an organic solvent as reaction medium. After a preliminary optimization of the reaction to obtain satisfactory yields, toluene was selected as the optimal solvent and the performances of the different CalB biocatalysts were compared. The R enantiomer was preferred in all cases but their performances were substantially different, with high differences in reaction rates, reaction yields in this kinetically controlled synthesis (EC-CalB gave a conversion of 76% while EC-IDA-Cu²⁺-CalB gave just a 27%), and enantiospecificities (EC-CalB gave an E value of 65 while EC-IDA-Cu²⁺-CalB gave a value of 13). Replacing toluene with hexane caused a decrease in enzyme activity, reaction yields and enantiospecificity of the reaction. It was remarkable that some preparations were much more sensitive to this solvent change than others. Considering that the activity decreased by less than 10% per reaction cycle, these differences are likely associated with the differences in the enzyme catalytic properties caused by the different immobilization protocols and not by inactivation of immobilized enzyme preparations during the reaction. These results confirmed that use of different immobilization protocols may be a powerful tool for altering enzyme properties when used in organic media.     

Enhancement of the organic solvent‐stability of the LST‐03 lipase by directed evolution

LST‐03 lipase from an organic solvent‐tolerant Pseudomonas aeruginosa LST‐03 has high stability and activity in the presence of various organic solvents. In this research, enhancement of organic solvent‐stability of LST‐03 lipase was attempted by directed evolution. The structural gene of the LST‐03 lipase was amplified by the error prone‐PCR method. Organic solvent‐stability of the mutated lipases was assayed by formation of a clear zone of agar which contained dimethyl sulfoxide (DMSO) and tri‐n‐butyrin and which overlaid a plate medium. And the organic solvent‐stability was also confirmed by measuring the half‐life of activity in the presence of DMSO. Four mutated enzymes were selected on the basis of their high organic solvent‐stability in the presence of DMSO. The organic solvent‐stabilities of mutated LST‐03 lipase in the presence of various organic solvents were measured and their mutated amino acid residues were identified. The half‐lives of the LST‐03‐R65 lipase in the presence of cyclohexane and n‐decane were about 9 to 11‐fold longer than those of the wild‐type lipase, respectively. Some substituted amino acid residues of mutated LST‐03 lipases have been located at the surface of the enzyme molecules, while some other amino acid residues have been changed from neutral to basic residues. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009