Penicillin amidase

About: Penicillin amidase is a research topic. Over the lifetime, 576 publications have been published within this topic receiving 15563 citations. The topic is also known as: penicillin amidohydrolase & ampicillin acylase.

Stability enhancement of Escherichia coli penicillin G acylase by glycosylation with yeast mannan

Abstract: Penicillin G acylase (PGA) from Escherichia coli was cross-linked with mannan dialdehydes. Conjugates were prepared with molecular masses varying from 140 to 580 kDa and containing from 18 to 50% (w/w) saccharides, the values depending on the reaction conditions (mannan/enzyme ratio), and by using mannans with different degrees of oxidation and weightaverage molecular mass (M| w). The pH- and thermostability of all preparations of glycosylated enzyme were improved remarkably, whereby the influence of the character of the linked mannan dialdehyde, its content, as well as the molecular mass of prepared glycoconjugates, on the stability of PGA, was evaluated. PGA glycosylated with the most oxidized mannan up to an Mw of 490 kDa, containing 41% (w/w) saccharides, and retaining 90% of its original catalytic activity, showed the highest stability. The half-life of this PGA preparation increased significantly: 13-fold at pH 3, 7-fold at pH 10, and 3.5-fold at pH 8 (all at 37 ∞C), compared with the native enzyme. At higher temperatures (50 ∞C) even more significant stabilization was evident, a 16-fold increase in half-life, from 18 min to 289 min, at pH 8, being measured.

An efficient immobilizing technique of penicillin acylase with combining mesocellular silica foams support and p-benzoquinone cross linker.

Abstract: To improve the performance of covalently immobilized penicillin acylase (PA), the immobilization was carried out in mesocellular silica foams (MCFs) using p-benzoquinone as cross linker. The characterizations of the immobilized enzyme were studied carefully. The results showed that the relative activity of the immobilized PA was increased to 145% of that of free enzyme. The activity was 3.7 folds of that of PA on the silica nanoparticles. The enzyme in MCFs presented a turnover equal to that of free enzyme. It was also found that the optimum pH of the immobilized PA shifted to pH 7.5 and the optimum reaction temperature rose from 45 to 50 °C. Furthermore, the stability of PA was ameliorated greatly after immobilization. Fourier transform infrared spectroscopy showed no major secondary structural change for PA confined in MCFs. The proposed covalent immobilizing technique would rank among the potential strategies for efficient immobilization of PA.

Structure-Based Prediction of Modifications in Glutarylamidase to Allow Single-Step Enzymatic Production of 7-Aminocephalosporanic Acid from Cephalosporin C.

Abstract: Glutarylamidase is an important enzyme employed in the commercial production of 7-aminocephalosporanic acid, a starting compound in the synthesis of cephalosporin antibiotics. 7-aminocephalosporanic acid is obtained from cephalosporin C, a natural antibiotic, either chemically or by a two-step enzymatic process utilizing the enzymes D-amino acid oxidase and glutarylamidase. We have investigated possibilities for redesigning glutarylamidase for the production of 7-aminocephalosporanic acid from cephalosporin C in a single enzymatic step. These studies are based on the structures of glutarylamidase, which we have solved with bound phosphate and ethylene glycol to 2.5 A resolution and with bound glycerol to 2.4 A. The phosphate binds near the catalytic serine in a way that mimics the hemiacetal that develops during catalysis, while the glycerol occupies the side-chain binding pocket. Our structures show that the enzyme is not only structurally similar to penicillin G acylase but also employs essentially the same mechanism in which the α-amino group of the catalytic serine acts as a base. A subtle difference is the presence of two catalytic dyads, His B23/Glu B455 and His B23/Ser B1, that are not seen in penicillin G acylase. In contrast to classical serine proteases, the central histidine of these dyads interacts indirectly with the Oγ through a hydrogen bond relay network involving the α-amino group of the serine and a bound water molecule. A plausible model of the enzyme–substrate complex is proposed that leads to the prediction of mutants of glutarylamidase that should enable the enzyme to deacylate cephalosporin C into 7-aminocephalosporanic acid.