Seeing molecules: A method using laser‐induced photopolymerization was developed to generate highly selective fiber optic sensors in a few seconds that are based on molecularly imprinted polymer (MIP) microtips. The fluorescence detection signal was enhanced using gold nanoparticles. The sensor also detects nonfluorescent analytes when a fluorescent signaling monomer is incorporated into the MIP.
Abstract:The catalytic properties of penicillin G acylase (PGA) from Escherichia coli in kinetically controlled synthesis of β-lactam antibiotics are negatively affected upon immobilization on hydrophobic acrylic carriers. Two strategies have been here pursued to improve the synthetic performance of PGA immobilized on epoxy-activated acrylic carriers. First, an aldehyde-based spacer was inserted on the carrier surface by glutaraldehyde activation (immobilization yield = 50%). The resulting 3-fold higher synthesis/hydrolysis ratio (vs/vh 1 = 9.7 ± 0.7 and 10.9 ± 0.7 for Eupergit ® C and Sepabeads ® EC-EP, respectively) with respect to the unmodified support (vs/vh 1 = 3.3 ± 0.4) was ascribed to a facilitated diffusion of substrates and products as a result of the increased distance between the enzyme and the carrier surface. A second series of catalysts was prepared by direct immobilization of PGA on epoxy-activated acrylic carriers (Eupergit ® C), followed by quenching of oxiranes not involved in the binding with the protein with different nucleophiles (amino acids, amines, amino alcohols, thiols and amino thiols). In most cases, this derivatization increased the synthesis/hydrolysis ratio with respect to the non derivatized carrier. Particularly, post-immobilization treatment with cysteine resulted in about 2.5-fold higher vs/vh 1 compared to the untreated biocatalyst, although the
OPEN ACCESSMolecules 2013, 18 14350 immobilization yield decreased from 70% (untreated Eupergit ® C) to 20%. Glutaraldehydeand cysteine-treated Eupergit ® C catalyzed the synthesis of cefazolin in 88% (±0.9) and 87% (±1.6) conversion, respectively, whereas untreated Eupergit ® C afforded this antibiotic in 79% (±1.2) conversion.
An innovative approach to determine the orientation of penicillin G acylase (PGA) from Escherichia coli covalently immobilized onto solid supports has been developed. This method is based on tryptic digestion of immobilized PGA followed by HPLC-MS analysis of the released peptides which are supposed to be only those exposed toward the reaction medium and not directly bound to the solid support. To this purpose, PGA was immobilized on Eupergit C (acrylic hydrophobic resin) and glyoxyl-agarose (hydrophilic resin) functionalized with epoxy and aldehyde groups, respectively, both involving the Lys residues of the protein. The peptide maps obtained were analyzed to derive the orientation of immobilized PGA, as the position of the detected Lys gave indication concerning the accessibility of the different areas of the protein. The results indicate that PGA immobilization on both supports involves mainly Lys located near the binding pocket (70%). Some differences in the enzyme orientation on the two supports can be deduced by the presence of different unbound Lys residues in the released peptides, specific to each support (Lys 117alpha for PGA-Eupergit C; Lys 163alpha and Lys 165alpha for PGA-glyoxyl-agarose). These results have been correlated with the data obtained in the kinetically controlled synthesis and indicate that the orientation of PGA on both supports is partially unfavorable, driving the active site near the support surface. This type of orientation of the enzyme enhances the effect of the nature of the support and of the binding chemistry on the catalytic properties. The information obtained indicated the most suitable support and activation strategy to design an immobilized acylase with good synthetic properties for preparative processes. The glyoxyl-Eupergit C support with enhanced porosity synergically combines the mechanical stability and synthetic performances of immobilized PGA and was successfully used in the synthesis of several cephalosporins.
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