Improved Kinetic Resolution by Enzyme-Catalyzed Parallel Reactions

Competitive parallel reactions with opposite enantioselectivity are presented as a strategy to enhance the enantiomeric product purity in enzymatic kinetic resolution. Lipase-catalyzed simultaneous hydrolysis and amidation of racemic methy 12-chloropropionate led to significantly improved amide yield and enantiomeric excess. Process results can be controlled by changing the hydrolysis/amidation reaction rates through variation of the solvent and the initial amine concentration. This is described by a kinetic model.     

Synthesis of two persistent fluorinated tetrathiatriarylmethyl (TAM) radicals for biomedical EPR applications

Tetrathiatriarylmethyl radicals are attractive spin probes extensively used in biomedical magnetic resonance applications. We report a straightforward synthesis of two original tetrathiatriarylmethyl radicals incorporating, respectively, 15 and 45 fluorine atoms, and thus possessing a high affinity to fluorous media. F15T-03 and F45T-03 exhibit a single sharp EPR spectrum and their EPR line broadening is highly sensitive to molecular oxygen. These spin probes are specially designed for assessment of tumor oxygenation using perfluorocarbon formulations.     

Resolution of rac-ketoprofen esters by enzymatic reactions in organic media

Enzyme-catalyzed reactions in organic media of rac-ketoprofen esters with different nucleophiles such as alcohols, amines, and water have been studied. Among the parameters optimized are the enzyme, the activated substrate, and the solvent. With the enzymes used in this study the preferred substrate was the trifluoroethyl ester of rac-ketoprofen (rac- 2 ), whose (R)-enantiomer reacted preferentially. The enzyme of choice was the lipase M-AP-10 from Mucor miehei and best results were obtained with diisopropyl ether as solvent. Three different methods have been scaled-up for the resolution of 75–150 g of substrate: transesterification with 1-butanol (90% yield of (S)-ketoprofen, 88% ee), transesterification with 2-(2-pyridyl)ethanol (94% yield, 92% ee), and hydrolysis in wet organic solvent (93% yield, 97% ee). Despite the comparable chemical and optical yields obtained with these three methods, the use of 2-(2-pyridyl)ethanol and the hydrolysis allowed a much easier work-up and isolation of the desired (+)-(S)-ketoprofen. © 1993 Wiley-Liss, Inc.     

Aminolysis of 2-hydroxy esters catalyzed by Candida antarctica lipase

Candida antarctica lipase catalyzed the aminolysis of 2-hydroxy esters with amines in organic solvents to yield the corresponding 2-hydroxy amides. The reactions proceeded at 28–30 °C in dioxane for 6 h with 3 mM substrates with yields ranging between 45% (w/w) (for branched substrates) to 88% (w/w) (for linear substrates). Although the reaction was not enantioselective, because of its simplicity it represents an alternative method for the synthesis of functionalised amides.     

Lipase-catalyzed transformations using poly(ethylene glycol) as solvent

Abstract

Candida antarctica lipase catalyzes a number of elementary reactions like alcoholysis, ammoniolysis and aminolysis in poly(ethylene glycol) (PEG) media. Reaction rates were comparable to or better than those observed in conventional organic reaction media and ionic liquids. It is envisaged that PEGs could have added benefits for performing biotransformations with highly polar substrates, which are sparingly soluble in common organic solvents.     

Enzymatic resolution of racemic amines in a continuous reactor in organic solvents

An enzymatic process has been developed for the continuous production of the pharmaceutically important intermediate (R)-1-aminoindan and of the chiral resolving agent (R)-1-(1-naphthyl)ethylamine. The process consists of the subtilisin catalyzed stereoselective aminolysis of the racemic primary amine with an active ester in organic solvent. The competing nonenzymatic reaction has been suppressed by appropriate choice of solvent and reactant's concentration and by minimizing the time of contact between the amine and the active ester. Subtilisin was immobilized on glass beads and the reaction carried out in a continuous-flow column bioreactor. By using a 450-mL column bioreactor containing 5.7 g of subtilisin immobilized on 570 g of glass beads, 1.6 kg of racemic 1-(1-naphthyl)ethylamine was resolved after 320 h of continuous operation with only a slight loss of the enzymatic activity. During the whole process, the optical purity of the chiral amine eluting from the column was higher than 90%. A facile procedure was developed for separating the unreacted (R)-amine from the (S)-amide and for the recycling of the solvent 3-methyl-3-pentanol and the active ester 2,2,2-trifluoroethyl butyrate. (c) 1992 John Wiley & Sons, Inc.     

Active esters in solid-phase peptide synthesis

Incorporation of single amino acid residues into peptide chains built on insoluble polymeric supports a priori appeared promising: the use of isolated, well defined (and potentially commercially available) reactive intermediates were expected to reduce the extent of undesired side reactions. In spite of these expectations active esters were only infrequently used in solid-phase peptide synthesis, mainly because the reaction rates achieved with them were insufficient for rapid chain-lengthening that became possible with automated instruments. In recent years, however, a certain revival of the active ester principle can be noted. This is the consequence of two factors: the application of highly reactive esters and the discovery of efficient catalysts of the ester-aminolysis reaction. The mechanism of catalysis and its exploitation for further improvements are also discussed.     

Mechanism of Carboxypeptidase Y Catalyzed Hydrolysis and Aminolysis Reactions

The reaction mechanism of carboxypeptidase Y catalyzed reactions is investigated. Presteady state and steady state kinetic measurements are performed on the hydrolysis and aminolysis of an ester and an amide substrate. It is found that deacylation is the rate determining step in hydrolysis of the ester, pivalic acid 4-nitrophenol and acylation in that of the amide, succinyl-L-alanyl-L-alalyl-L-propyl-L-phenylalanine 4-nitroanilide.

The kinetic effects observed in the presence of a nucleophile, L-valine amide, where aminolysis occurs in parallel to the hydrolysis reaction are analysed in details. The results are described satisfactorily by a reaction scheme which involves the binding of the added nucleophile, (i) to the free enzyme, resulting in a simple competitive effect, and (ii) to the acyl-enzyme with the formation of a complex between the enzyme and the aminolysis product, the dissociation of which is rate determining. That scheme can account for both increases and decreases of kinetic parameter values as a function of the nucleophile concentration. There is no indication of binding of the nucleophile to the enzyme-substrate complex before acylation takes place.     

酰氯法合成甘氨酰-甘氨酰-缬氨酸三肽的实验研究

多肽的合成方法很多 ,传统的方法有混合酸酐法、活泼酯法和偶联试剂法 ,本文采用酰氯法 ,以L -缬氨酸为原料 ,经过酰化、氨解形成二肽 ,二肽再经过酰化、氨解最终形成三肽。通过对三肽样品的红外、核磁及高效液相等的鉴定说明该方法实验步骤简单 ,原料易得 ,收率很高 ,很适合于工业化生产 ,目前国内尚无文献报道     

C-Terminal Protein Characterization by Mass Spectrometry: Isolation of C-Terminal Fragments from Cyanogen Bromide-Cleaved Protein

A sample preparation method for protein C-terminal peptide isolation from cyanogen bromide (CNBr) digests has been developed. In this strategy, the analyte was reduced and carboxyamidomethylated, followed by CNBr cleavage in a one-pot reaction scheme. The digest was then adsorbed on ZipTip_C18 pipette tips for conjugation of the homoserine lactone-terminated peptides with 2,2′-dithiobis (ethylamine) dihydrochloride, followed by reductive release of 2-aminoethanethiol from the derivatives. The thiol-functionalized internal and N-terminal peptides were scavenged on activated thiol sepharose, leaving the C-terminal peptide in the flow-through fraction. The use of reversed-phase supports as a venue for peptide derivatization enabled facile optimization of the individual reaction steps for throughput and completeness of reaction. Reagents were replaced directly on the support, allowing the reactions to proceed at minimal sample loss. By this sequence of solid-phase reactions, the C-terminal peptide could be recognized uniquely in mass spectra of unfractionated digests by its unaltered mass signature. The use of the sample preparation method was demonstrated with low-level amounts of a whole, intact model protein. The C-terminal fragments were retrieved selectively and efficiently from the affinity support. The use of covalent chromatography for C-terminal peptide purification enabled recovery of the depleted material for further chemical and/or enzymatic manipulation. The sample preparation method provides for robustness and simplicity of operation and is anticipated to be expanded to gel-separated proteins and in a scaled-up format to high-throughput protein profiling in complex biological mixtures.