Progress in One-pot Bioconversion of Cephalosporin C to 7-Aminocephalosporanic Acid.

BACKGROUND: Cephalosporins are the most widely used semisynthetic antibiotics, which acted on bacterial cell wall (peptidoglycan) synthesis. The key intermediate for fabricating about twothirds of cephalosporins in clinical use is 7-aminocephalosporanic acid (7-ACA), which is derived from chemical or enzymatic deacylation of the natural antibiotic cephalosporin C (CPC). The chemical deacylation process has been replaced by the enzymatic deacylation process because the chemical process required harsh conditions and released toxic waste. METHODS: A two-step enzymatic process that utilized D-amino acid oxidase (DAAO) and 7-ß-(4carboxybutanamido)-cephalosporanic acid acylase (GLA) for two successive reactions has been applied for the conversion of CPC to 7-ACA in an industrial scale. RESULTS: To simplify the process and lower costs, the one-pot enzymatic processes were developed by the application of the mono-enzymatic process (application of cephalosporin C acylase or the variants of GLA), di-enzymatic process (simultaneous action of DAAO and GLA) or the tri-enzymatic process (simultaneous action of DAAO, GLA and catalase) for direct conversion of CPC to 7-ACA. CONCLUSION: Here, we mainly focused on the description of these one-pot enzymatic processes and emphasized on the preparation of the involved biocatalysts.

Transition state analogue imprinted polymers as artificial amidases for amino acid p-nitroanilides: morphological effects of polymer network on catalytic efficiency.

The morphology of the polymer network - porous/less porous - plays predominant role in the amidase activities of the polymer catalysts in the hydrolytic reactions of amino acid p-nitroanilides. Polymers with the imprints of stable phosphonate analogue of the intermediate of hydrolytic reactions were synthesized as enzyme mimics. Molecular imprinting was carried out in thermodynamically stable porogen dimethyl sulphoxide and unstable porogen chloroform, to investigate the morphological effects of polymers on catalytic amidolysis. It was found that the medium of polymerization has vital influence in the amidase activities of the enzyme mimics. The morphological studies of the polymer catalysts were carried out by scanning electron microscopy and Bruner-Emmett-Teller analysis. The morphology of the polymer catalysts and their amidase activities are found to be dependent on the composition of reaction medium. The polymer catalyst prepared in dimethyl sulphoxide is observed to be efficient in 1:9 acetonitrile (ACN)-Tris HCl buffer and that prepared in chloroform is noticed to be stereo specifically and shape-selectively effective in 9:1 ACN-Tris HCl buffer. The solvent memory effect in catalytic amidolysis was investigated using the polymer prepared in acetonitrile.

Synthesis and Preliminary PET Imaging Studies of a FAAH Radiotracer ([¹¹C]MPPO) Based on α-Ketoheterocyclic Scaffold.

Fatty acid amide hydrolase (FAAH) is one of the principle enzymes for metabolizing endogenous cannabinoid neurotransmitters such as anandamide, and thus regulates endocannabinoid (eCB) signaling. Selective pharmacological blockade of FAAH has emerged as a potential therapy to discern the endogenous functions of anandamide-mediated eCB pathways in anxiety, pain, and addiction. Quantification of FAAH in the living brain by positron emission tomography (PET) would help our understanding of the endocannabinoid system in these conditions. While most FAAH radiotracers operate by an irreversible ("suicide") binding mechanism, a FAAH tracer with reversibility would facilitate quantitative analysis. We have identified and radiolabeled a reversible FAAH inhibitor, 7-(2-[(11)C]methoxyphenyl)-1-(5-(pyridin-2-yl)oxazol-2-yl)heptan-1-one ([(11)C]MPPO) in 13% radiochemical yield (nondecay corrected) with >99% radiochemical purity and 2 Ci/µmol (74 GBq/µmol) specific activity. The tracer showed moderate brain uptake (0.8 SUV) with heterogeneous brain distribution. However, blocking studies with a potent FAAH inhibitor URB597 demonstrated a low to modest specificity to the target. Measurement of lipophilicity, metabolite, and efflux pathway analysis were also performed to study the pharmacokinetic profile of [(11)C]MPPO. In all, we reported an efficient radiolabeling and preliminary evaluation of the first-in-class FAAH inhibitor [(11)C]MPPO with α-ketoheterocyclic scaffold.

Structure-activity relationship of novel and known inhibitors of human dimethylarginine dimethylaminohydrolase-1: alkenyl-amidines as new leads.

Recent studies demonstrated that inhibition of dimethylarginine dimethylaminohydrolase (DDAH) activity could be a new strategy to indirectly affect nitric oxide (NO) formation by elevating N(omega)-methylated L-arginine (NMMA, ADMA) levels. This approach is an alternate strategy for the treatment of diseases associated with increased NO-concentrations. To date, three classes of potent inhibitors are known: (1) pentafluorophenyl sulfonates (IC(50)=16-58 microM, PaDDAH), which are also inhibitors for the arginine deiminase; (2) the most potent inhibitors are based on indolylthiobarbituric acid (IC(50)=2-17 microM, PaDDAH), which were identified by virtual modelling; and (3) L-arginine analogs, whose best representative is N(omega)-(2-methoxyethyl)-L-arginine (IC(50)=22 microM, rat DDAH). Based on these known structures, we aimed to develop inhibitors for the human DDAH-1 with improved potency and better relative selectivity for DDAH-1 over NOS. Particularly, the binding pocket of the guanidine-moiety was investigated by screening differently substituted guanidines, amidines and isothioureas in order to collect information on possible binding modes in the active site. All substances were tested in a plate-reader format and HPLC assay and several potent inhibitors were identified with K(i)-values varying from 2 to 36 microM, with N(5)-(1-iminobut-3-enyl)-L-ornithine (L-VNIO) being the most potent inhibitor of the human DDAH-1 so far described. Besides these potent inhibitors alternate substrates for hDDAH-1 were identified as well.

Structure-based design of a FAAH variant that discriminates between the N-acyl ethanolamine and taurine families of signaling lipids.

Fatty acid amide hydrolase (FAAH) inactivates a large and diverse class of endogenous signaling lipids termed fatty acid amides. Representative fatty acid amides include the N-acyl ethanolamines (NAEs) anandamide, which serves as an endogenous ligand for cannabinoid receptors, and N-oleoyl and N-palmitoyl ethanolamine, which produce satiety and anti-inflammatory effects, respectively. Global metabolite profiling studies of FAAH (-/-) mice have recently identified a second class of endogenous FAAH substrates: the N-acyl taurines (NATs). To determine the metabolic and signaling functions performed by NAEs and NATs in vivo, a FAAH variant that discriminates between these two substrate classes would be of value. Here, we report the structure-guided design of a point mutant in the active site of FAAH that selectively disrupts interactions with NATs. This glycine-to-aspartate (G268D) mutant was found to exhibit wild-type kinetic parameters with NAEs, but more than a 100-fold reduction in activity with NATs attributable to combined effects on Km and kcat values. These in vitro properties were also observed in living cells, where WT-FAAH and the G268D mutant displayed equivalent hydrolytic activity with NAEs, but the latter enzyme was severely impaired in its ability to catabolize NATs. The G268D FAAH mutant may thus serve as a valuable research tool to illuminate the unique roles played by the NAE and NAT classes of signaling lipids in vivo.

Construction of artificial cyclic amide amidohydrolases using molecular imprinting technique.

A general molecular imprinting approach is proposed to synthesize artificial enzymes to mimic the family of cyclic amide amidohydrolases which share similar active site and catalytic mechanism. The artificial enzymes were constructed by co-polymerizing 4(5)-vinylimidazole-Co2+-methacrylic acid clusters with divinylbenzene micro-spheres in the presence of corresponding substrates. The artificial enzymes mimicked creatininase and hydantoinase by showing specific affinity towards the corresponding substrates in buffer. The artificial hydantoinase also showed specific affinity towards corresponding substrate in organic solvent, and catalyzed the hydrolysis of hydantoin.

Rational design of an L-histidine-derived minimal artificial acylase for the kinetic resolution of racemic alcohols.

This communication describes the rational design of an l-histidine-derived minimal artificial acylase. Our new artificial acylase, tert-butyldiphenylsilyl ether of N-(2,4,6-triisopropylbenzenesulfonyl)-pi(Me)-l-histidinol, is a simple and small molecule (molecular weight = 660) that contains only one chiral carbon center that originates from natural l-histidine. The kinetic acylation of racemic secondary alcohols induced by this compound showed an S (kfast/kslow) value of up to 93. A reusable polystyrene-bound artificial acylase was also developed to examine its practical usability.

Site-selective glycosylation of subtilisin Bacillus lentus causes dramatic increases in esterase activity.

Using site directed mutagenesis combined with chemical modification, we have developed a general and versatile method for the glycosylation of proteins which is virtually unlimited in the scope of proteins and glycans that may be conjugated and in which the site of glycosylation and the nature of the introduced glycan can be carefully controlled. We have demonstrated the applicability of this method through the synthesis of a library of 48 glycosylated forms of the serine protease subtilisin Bacillus lentus (SBL) as single, pure species. As part of our ongoing program to tailor the activity of SBL for use in peptide synthesis, we have screened these enzymes for activity against the esterase substrate succinyl-Ala-Ala-Pro-Phe-S-benzyl. Gratifyingly, 22 enzymes displayed greater than wild type (WT) activity. Glycosylation at positions 62, in the S2 pocket, resulted in five glycosylated forms of SBL that were 1.3- to 1.9-fold more active than WT. At position 217, in the S1' pocket, all glycosylations increased kcat/KM up to a remarkable 8.4-fold greater than WT for the glucosylated enzyme L217C-S-beta-Glc(Ac)3. Furthermore, the ratio of amidase to esterase activity, (kcat/KM)esterase/(kcat/KM)amidase (E/A), is increased relative to wild type for all 48 glycosylated forms of SBL. Again, the most dramatic changes are observed at positions 62 and 217 and L217C-S-beta-Glc(Ac)3 has an E/A that is 17.2-fold greater than WT. The tailored specificity and high activity of this glycoform can be rationalized by molecular modeling analysis, which suggests that the carbohydrate moiety occupies the S1' leaving group pocket and enhances the rate of deacylation of the acyl-enzyme intermediate. These glycosylated enzymes are ideal candidates for use as catalysts in peptide synthesis as they have greatly increased (kcat,KM)esterase and severely reduced (kcat/KM)amidase and will favor the formation of the amide bond over hydrolysis.