Enzymatic synthesis of cefazolin using immobilized recombinant cephalosporin-acid synthetase as the biocatalyst.

A method for the synthesis of ß-lactam antibiotic cefazolin (CEZ) by enzymatic acylation of 7-amino-3-(5-methyl-l,3,4-thiadiazol-2-yl)thiomethyl-3-cephem-4-carboxylic acid (TDA) using immobilized cephalosporin-acid synthetase (IECASA) from recombinant E. coli strain VKPM B-12316 has been developed. A stepwise pH gradient designed on the basis of investigations on the solubility of components was applied for synthesis. This helped in avoiding the precipitation of TDA in the reaction when its initial concentration was high (150-200 mM). Thus, under optimal conditions a high yield of CEZ (relative to TDA) of 92-95% was obtained. Where the final reaction mixture contained 65-85 mg/mL of CEZ, 4-5 mg/mL of unreacted TDA, and 40-60 mg/mL of the by-product, 1(H)-tetrazolylacetic acid (TzAA). Testing of optimized CEZ synthesis using IECASA in a batch reactor has proved sufficiently high operational stability of the biocatalyst, with its residual activity after the 25th cycle accounting for about 83 ± 2% of its starting value. The half-inactivation period of IECASA was estimated as 85 cycles of CEZ synthesis.

[Cephalosporin-Acid Synthetase of Escherichia coli Strain VKPM B-10182: Genomic Context, Gene Identification, Producer Strain Production].

An enzyme of cephalosporin-acid synthetase produced by the E. coli strain VKPM B-10182 has specificity for the synthesis of ß-lactam antibiotics of the cephalosporin acids class (cefazolin, cefalotin, cefezole etc.). A comparison of the previously determined genomic sequence of E. coli VKPM B-10182 with a genome of the parent E. coli strain ATCC 9637 was performed. Multiple mutations indicating the long selection history of the strain were detected, including mutations in the genes of RNase and ß-lactamases that could enhance the level of enzyme synthesis and reduce the degree of degradation of the synthesized cephalosporin acids. The CASA gene--a direct homolog of the penicillin G-acylase gene--was identified by bioinformatics methods. The homology of the gene was confirmed by gene cloning and the expression and determination of its enzymatic activity in the reaction of cefazolin synthesis. The CASA gene was isolated and cloned into the original expression vector, resulting in an effective E. coli BL2l(DE3) pMD0107 strain producing CASA.

[Recombinant cephalosporin-acid synthesase: optimisation of expression in E.coli cells, immobilisation and application for biocatalytic cefazolin synthesis].

Cephalosporin acid synthetase (CASA) is responsible for specific to synthesis of cephalosporin-acids, its expression in Escherichia coli cells is accompanied by accumulation of unprocessed insoluble precursor. In order to optimize conditions of recombinant CASA production we have studied the effects of several parameters of strain cultivation, including growth media composition, temperature, and inoculation dose. Also plasmids for production of CASA variants with the signal sequence of Erwinia carotovora L-asparaginase (ansCASA) and "leaderless" CASA were created in search of more efficient expression constructs. Removal of the N-terminal secretion signal sequence reduced the production of functionally active CASA more than 10-fold and inhibited strain growth. Insertion of the L-asparaginase signal sequence increased the specific enzyme activity in the resultant recombinant strain. The ansCASA producing strain was used to develop the method of immobilization of the recombinant enzyme on an epoxy-activated macroporous acrylic support. The resultant biocatalyst performed effective synthesis of cefazolin from 3-[(5-methyl-1,3,4-thiadiazol-2-il)-thiomethyl]-7- aminocephalosporanic acid (MMTD-7-ACA) and methyl ester of 1(H)-tetrazolilacetic acid (МETzAA), under mild conditions a transformation level of MMTD-7-ACA to cefazolin of 95% is reached.

[Enzymatic Synthesis of Acidic ß-Lactams (Review)].

The currently known methods of enzymatic ß-lactam synthesis, as well as the enzymes and heterogeneous biocatalysts used for this purpose, are presented, and the published reports on advances in the field of enzymatic synthesis of selected antibiotics belonging to the groups of acidic penicillins and acidic cephalosporins are summarized in the present review. The key conditions and parameters of biocatalytic processes, such as the biocatalyst form, concentration of the precursor compounds, solvent type, pH, temperature, etc. are analyzed and compared, and guidelines for further optimization of ß-lactam synthesis are given. The present review may be of use for a wide range of readers, as well as to enzymology and biotechnology experts.

3D Structure Modeling of Alpha-Amino Acid Ester Hydrolase from Xanthomonas rubrilineans.

Alpha-amino acid ester hydrolase (EC 3.1.1.43, AEH) is a promising biocatalyst for the production of semi-synthetic ß-lactam antibiotics, penicillins and cephalosporins. The AEH gene from Xanthomonas rubrilineans (XrAEH) was recently cloned in this laboratory. The three-dimensional structure of XrAEH was simulated using the homology modeling method for rational design experiments. The analysis of the active site was performed, and its structure was specified. The key amino acid residues in the active site - the catalytic triad (Ser175, His341 and Asp308), oxyanion hole (Tyr83 and Tyr176), and carboxylate cluster (carboxylate groups of Asp209, Glu310 and Asp311) - were identified. It was shown that the optimal configuration of residues in the active site occurs with a negative net charge -1 in the carboxylate cluster. Docking of different substrates in the AEH active site was carried out, which allowed us to obtain structures of XrAEH complexes with the ampicillin, amoxicillin, cephalexin, D-phenylglycine, and 4-hydroxy-D-phenylglycine methyl ester. Modeling of XrAEH enzyme complexes with various substrates was used to show the structures for whose synthesis this enzyme will show the highest efficiency.

Ionization constants and solubility of compounds involved in enzymatic synthesis of aminopenicillins and aminocephalosporins.

The article deals with experimental determination of ionization constants and solubility for the compounds (target products, initial ß-lactams, acylating agents and by-products) involved in enzymatic synthesis of some therapeutically used aminopenicillins and aminocephalosporins, namely ampicillin, amoxicillin, cephalexin, cephadroxil, cephaloglycin, cefaclor, cefprozil, cefatrizine. Methodology of investigations and the evaluation of experimental data for the determination of ionization constants and solubility of the different type electrolytes are presented. Applications of the methods based on acid-base potentiometric titration and on determination of solubility-pH dependence of assayed substances are discussed. The original data on ionization constants and solubility of amoxicillin, cefprozil, cefatrizine, cephadroxil and initial ß-lactams for production of cefaclor, cefprozil and cefatrizine, as well as solubility of by-product D-(-)-p-hydroxyphenylglycine are presented. Experimentally determined parameters and constants available in the literature for all abovementioned aminopenicillins and aminocephalosporins are collected. These data might be used for choice of the conditions of both processes: the enzymatic synthesis and the isolation of the product from reaction mixture.