A New N-Acyl Derivative of (S)-Cysteine for Quantitative Determination of Enantiomers of Amino Compounds by HPLC with a Precolumn Modification with o-Phthalaldehyde

N-Phenylacetyl-(R)-phenylglycyl-(S)-cysteine (NPPC) was used for the determination of enantiomers of primary amines by rpHPLC with a precolumn modification with o-phthalaldehyde. NPPC was compared with the classic SH reagent N-acetyl-(S)-cysteine (NAC) in the analysis of stereomers of nonfunctionalized amines and amino alcohols. After the NAC-modification, the resulting diastereomeric isoindoles were difficult to separate by HPLC, and satisfactory resolution was achieved only for some aliphatic amino alcohols. The use of NPPC improved the chromatographic analysis of stereomeric amino alcohols and, in addition, allowed the enantiomeric analysis of the nonfunctionalized amines. Similarity between the side radicals of the amino component and the thiol reagent favored the diastereomer separation. This method was used for determination of the absolute concentration of individual enantiomers of amines in the course of stereoselective enzymatic reactions. The optically active NPPC was prepared with a high yield by a chemoenzymatic synthesis based on a regioselective acylation of the (S)-cysteine amino group in aqueous medium by the action of penicillin acylase.     

Enzymatic racemization of alcohols and amines: An approach for bi-enzymatic dynamic kinetic resolution

Racemization is the key step to turn a kinetic resolution (KR), which suffers from the well-known drawback of being limited to a maximum yield of 50% with high enantiopurity, into a dynamic kinetic resolution (DKR) process. Enzyme-based racemization of enantiopure alcohols and amines has gained significant interest in recent years. This review covers recent advances in enzyme-based racemization approaches and their potential applications in bi-enzymatic DKR.     

Stereochemical analysis of chiral amines,diamines, and amino alcohols: Practical chiroptical sensing based on dynamic covalent chemistry

Practical chiroptical sensing with a small group of commercially available aromatic aldehydes is demonstrated. Schiff base formation between the electron-deficient 2,4-dinitrobenzaldehyde probe and either primary amines, diamines, or amino alcohols proceeds smoothly in chloroform at room temperature and is completed in the presence of molecular sieves within 2.5 hours. The substrate binding coincides with a distinct circular dichroism signal induction at approximately 330 nm, which can be correlated to the absolute configuration and enantiomeric composition of the analyte. The usefulness of this sensing method is highlighted with the successful sensing of 18 aliphatic and aromatic amines and amino alcohols and five examples showing quantitative %ee determination with good accuracy.     

Enantiopure O‐Ethyl Phenylphosphonothioic Acid: A Solvating Agent for the Determination of Enantiomeric Excesses

An improved method, which is highly reproducible, was developed for the enantioseparation of racemic O‐ethyl phenylphosphonothioic acid ( 1a ) with brucine by introducing seeding to a supersaturated solution of the diastereomeric salt mixture. The present method gave both diastereomeric salts in high yields with a diastereomeric ratio of >99.5:0.5 upon choosing the crystallization solvent (MeOH for the ( (R)-1a salt and MeOH/H₂O for the ( (S)-1a salt). The enantiopure acid (R)-1a , (S)-1a showed a good chirality recognition ability for not only strong bases, such as amines and amino alcohols, but also weakly basic alcohols and was applicable as a solvating agent to the ¹H NMR determination of the enantiomeric excess of chiral amines, amino alcohols, and alcohols, including aliphatic substrates. Chirality 26:614–619, 2014. © 2014 Wiley Periodicals, Inc.     

Tantalum pentachloride as a coupling agent for stereohindered amide bond formation

We have previously reported that tantalum carboxylates show high reactivity toward primary amines to give primary amides. We report herein that tantalum pentachloride, in contrast with the behavior of standard coupling reagents, mediates the couplings of secondary amines and the couplings of very hindered carboxylates. Such coupling reactions are particularly difficult to achieve, when using chiral carboxylates (including N-protected amino acids), without a significant degree of accompanying racemization. Racemization levels with the present systems are found to be very low in comparison with those obtained using a standard amide/peptide coupling system (DCC/HOBt).     

Dynamic kinetic resolutions and asymmetric transformations by enzymes coupled with metal catalysis

The combination of enzyme and metal catalysis is described as a useful method for the synthesis of optically active compounds. A key feature of this new methodology is the use of metal catalysts for the in situ racemization of enzymatically unreactive enantiomers in the enzymatic resolution of racemic substrates. So far, two combinations - lipase-ruthenium and lipase-palladium - have been developed for the efficient dynamic kinetic resolution of alcohols and amines. The use of these combinations has also been extended to catalysis of the asymmetric transformation of ketones, their enol acetates, and ketoximes. In most cases, enzyme-metal combination catalysis has provided good yields and high optical purities.     

A colorimetric chiral sensor based on chiral crown ether for the recognition of the two enantiomers of primary amino alcohols and amines

A new colorimetric chiral sensor material consisting of three different functional sites such as chromophore (2,4-dinitrophenylazophenol dye), binding site (crown ether), and chiral barrier (3,3'-diphenyl-1,1'-binaphthyl group) was prepared and applied to the recognition of the two enantiomers of primary amino alcohols and amines. Among five primary amino alcohols and two primary amines tested, the two enantiomers of phenylalaninol show the highest difference in the absorption maximum wavelength (Δλ(max)=43.5 nm) and in the association constants (K(S)/K(R)=2.51) upon complexation with the colorimetric chiral sensor material and, consequently, the two enantiomers of phenylalaninol were clearly distinguished from each other by the color difference.     

Inversion of chiral α-methylbenzylamine

More effective use of optical resolution processes can be obtained by increasing the overall yields after development of methods for inversion of the chiral centre of the unwanted isomer. The configuration of some optically active amines can be inverted in a three-step synthesis via the N,N-ditosylimides and a subsequent nucleophilic substitution by the azide ion. The azide product is reduced by hydrogenolysis. Low stereoselectivity caused by racemization to some extent was at first observed for the inversion of the benzylic substrate, (S)-α-methylbenzylamine ( 5a ). However, modified reaction conditions allowed increased stereoselectivity, a more rapid and almost complete inversion of this substate as well. © 1994 Wiley-Liss, Inc.     

Practical synthesis of novel phosphonopeptides containing AibP

Practical and convenient method for the synthesis of novel phosphonopeptides 8a–h and 10a–f incorporating the quaternary α‐aminophosphonate 6 is reported. The target compounds were prepared in moderate to good yield based on the preparation of the quaternary α‐aminophosphonate 6 followed by the formation of the α‐bromoamide 7 and subsequent nucleophilic substitution reaction with several amines or by peptide bond formation with several amino acids and with the quaternary α‐aminophosphonate 6 , using isobutyl chloroformate as activating agent under racemization‐free condition.     

Enhancing cofactor recycling in the bioconversion of racemic alcohols to chiral amines with alcohol dehydrogenase and amine dehydrogenase by coupling cells and cell-free system

Alcohol dehydrogenase (ADH) and amine dehydrogenase (AmDH)-catalyzed one-pot cascade conversion of an alcohol to an amine provides a simple preparation of chiral amines. To enhance the cofactor recycling in this reaction, we report a new concept of coupling whole-cells with the cell-free system to enable separated intracellular and extracellular cofactor regeneration and recycling. This was demonstrated by the respective biotransformation of racemic 4-phenyl-2-butanol 1a and 1-phenyl-2-propanol 1b to (R)-4-phenylbutan-2-amine 3a and (R)-1-phenylpropan-2-amine 3b . Escherichia coli cells expressing S-enantioselective CpsADH, R-enantioselective PfODH, and NADH oxidase (NOX) was developed to oxidize racemic alcohols 1a–b to ketones 2a–b with full conversion via intracellular NAD⁺ recycling. AmDH and glucose dehydrogenase (GDH) were used to convert ketones 2a–b to amines (R)- 3a–b with 89–94% conversion and 891–943 times recycling of NADH. Combining the cells and enzymes for the cascade transformation of racemic alcohols 1a–b gave 70% and 48% conversion to the amines (R)- 3a and (R)-3 b in 99% ee, with a total turnover number (TTN) of 350 and 240 for NADH recycling, respectively. Improved results were obtained by using the E. coli cells with immobilized AmDH and GDH: (R)- 3a was produced in 99% ee with 71–84% conversion and a TTN of 1410-1260 for NADH recycling, the highest value so far for the ADH–AmDH-catalyzed cascade conversion of alcohols to amines. The concept might be generally applicable to this type of reactions.     

Mode of action of straight chain hydrocarbons on primary chemoreceptors of the blowfly, Phormia regina

The fundamental actions of straight-chain hydrocarbons on the three known primary chemoreceptor cell types of the blowfly, Phormia regina, were studied in quantitative terms. Lower alcohols and long-chain amines act in two stages: first a reversible inhibition, and then injury, of the salt, water, and sugar receptors in the labellar sensilla. The primary effects on salt and water receptors resemble hydrocarbon narcosis of nerve. Effects on sugar receptors, when analyzed kinetically, superficially resemble competitive inhibition. Other evidence, however, indicates that a non-specific effect on sugar receptor sites is more likely. The electrophysiological results from labellar chemoreceptors indicate that the previously reported hydrocarbon behavioral rejection thresholds are best explained by the inhibition of the sugar receptors. This conclusion is strengthened by further electrophysiological and behavioral tests on tarsal chemoreceptors.     

The role of hydrophobicity and electronic factors in regulating alcohol inhibition of cytochrome P-450-mediated aniline hydroxylation

The role of hydrophobicity and electronic factors in regulating alcohol inhibition of cytochrome P-450-mediated aniline p-hydroxylation has been investigated by the formulation of quantitative structure-activity relationships. The activity of linear primary alcohols and unhindered linear secondary alcohols shows a linear dependence on log P, where P is the octanol-water partition coefficient. Hindered primary and secondary alcohols are less active than this relationship predicts. An equation describing the activity of both hindered and unhindered primary and secondary alcohols shows that alcohol inhibition of aniline hydroxylation is regulated by hydrophobicity and steric effects. No role for electronic factors can be discerned. Similarities are found between alcohol inhibition and the binding of alkyl amines to cytochrome P-450, suggesting that alcohols may bind to the amine binding site.     

SCOPE AND LIMITATIONS OF THE USE OF NICOTINOPROTEIN ALCOHOL DEHYDROGENASE FOR THE COENZYME-FREE PRODUCTION OF ENANTIOPURE FINE-CHEMICALS

Nicotinoprotein alcohol dehydrogenases are enzymes that contain non-dissociable NAD(P)(H) in the active site. The suitability of a nicotinoprotein alcohol dehydrogenase as coenzyme-independent alternative to classic alcohol dehydrogenases for enantioselective synthetic applications was studied. To this end the NADH-containing nicotinoprotein, np-ADH, from Rhodococcus erythropolis DSM 1069 was used as a model enzyme in different types of conversion: asymmetric synthesis, kinetic resolution and racemization. The enzyme was found to catalyze the asymmetric reduction of ketones using cheap reductants, such as ethanol, with high stereoselectivity, but the reaction was too slow to obtain good yields. Kinetic resolutions of racemic alcohols failed due to dismutation of the aldehyde that was used as cosubstrate. Racemization of a secondary alcohol via the corresponding ketone could not be achieved, which was due to an unidentified side reaction. This evaluation shows that, for developing biotransformations of industrial interest using nicotinoprotein alcohol dehydrogenases, the attention should be focused on enzymes with a higher reactivity towards prochiral ketones and secondary alcohols.     

A new N-acyl derivative of (S)-cysteine for quantitative determination of enantiomers of amino compounds by HPLC method with a precolumn modification with o-phthalaldehyde

N-Phenylacetyl-(R)-phenylglycyl-(S)-cysteine (NPPC) was used for the determination of enantiomers of primary amines by rpHPLC with a precolumn modification with o-phthalaldehyde. NPPC was compared with the classic SH reagent N-acetyl-(S)-cysteine (NAC) in the analysis of stereomers of nonfunctionalized amines and amino alcohols. After the NAC modification, the resulting diastereomeric isoindoles were difficult to separate by HPLC, and satisfactory resolution was achieved only for some aliphatic amino alcohols. The use of NPPC improved the chromatographic analysis of stereomeric amino alcohols and, in addition, allowed the enantiomeric analysis of the nonfunctionalized amines. Similarity between the side radicals of the amino component and the thiol reagent favored the diastereomer separation. This method was used for determination of the absolute concentration of individual enantiomers of amines in the course of stereoselective enzymatic reactions. The optically active NPPC was prepared with a high yield by a chemoenzymatic synthesis based on a regioselective acylation of the (S)-cysteine amino group in aqueous medium by the action of penicillin acylase. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2004, vol. 30, no. 5; see also http: // www.maik.ru.     

Racemization in the Coupling Reaction,Pro-Val+Pro,with the Activated Ester Methods

The degree of racemization in the several activated ester methods of the peptide synthesis was measured in using the critical racemization test, Pro-Val+Pro, with help of gas chromatography. The results were compared with that in the coupling reaction, Leu-Phe+Val, in which no racemization had been reported in the corresponding reaction conditions by F. Weygand et al., when the activated dipeptide esters had been prepared from Z-Leu+Phe-activated esters. The significantly higher racemization was observed in the methods of N-hydroxypiperidine ester and thiophenyl ester, even when the activated dipeptide esters were prepared from Z-Pro+Val-activated esters. On the other hand, almost no racemization was observed in the N-hydroxysuccinimide ester and p-nitrophenyl ester methods. A great extent of the racemization was detected when the activated dipeptide esters were prepared directly from Z-Pro-Val-OH.     

Use of lipases in the resolution of racemic ibuprofen

Summary Resolution of (R,S)-ibuprofen enantiomers by esterification in different organic solvents was studied using Candida cylindracea lipase. This enzyme preparation had high enantiospecificity for S(+)-ibuprofen in the esterification reaction of a racemic ibuprofen with primary alcohols. The esterification yields of secondary alcohols were much lower than those of primary alcohols. Esterification with tertiary alcohols was not observed. The synthesis of esters was profoundly affected by the amount of water in the reaction mixture. C. cylindracea lipase was active only in very hydrophobic solvents. The esterification activity of the lipase was reduced significantly by addition of water. The R- and S-enantiomers of ibuprofen were determined without derivatization by HPLC using a chiral column.     

Evaluation of acid‐labile S‐protecting groups to prevent Cys racemization in Fmoc solid‐phase peptide synthesis

Phosphonium and uronium salt‐based reagents enable efficient and effective coupling reactions and are indispensable in peptide chemistry, especially in machine‐assisted SPPS. However, after the activating and coupling steps with these reagents in the presence of tertiary amines, Fmoc derivatives of Cys are known to be considerably racemized during their incorporation. To avoid this side reaction, a coupling method mediated by phosphonium/uronium reagents with a weaker base, such as 2,4,6‐trimethylpyridine, than the ordinarily used DIEA or that by carbodiimide has been recommended. However, these methods are appreciably inferior to the standard protocol applied for SPPS, that is, a 1 min preactivation procedure of coupling with phosphonium or uronium reagents/DIEA in DMF, in terms of coupling efficiency, and also the former method cannot reduce racemization of Cys(Trt) to an acceptable level (<1.0%) even when the preactivation procedure is omitted. Here, the 4,4′‐dimethoxydiphenylmethyl and 4‐methoxybenzyloxymethyl groups were demonstrated to be acid‐labile S‐protecting groups that can suppress racemization of Cys to an acceptable level (<1.0%) when the respective Fmoc derivatives are incorporated via the standard SPPS protocol of phosphonium or uronium reagents with the aid of DIEA in DMF. Furthermore, these protecting groups significantly reduced the rate of racemization compared to the Trt group even in the case of microwave‐assisted SPPS performed at a high temperature. © 2013 The Authors. European Peptide Society published by John Wiley & Sons, Ltd.     

Effect of amines as activators on the alcohol-oxidizing activity of pyrroloquinoline quinone-dependent quinoprotein alcohol dehydrogenase

Pyrroloquinoline quinone-dependent quinoprotein alcohol dehydrogenases (PQQ-ADH) require ammonia or primary amines as activators in in vitro assays with artificial electron acceptors. We found that PQQ-ADH from Pseudomonas putida KT2440 (PpADH) was activated by various primary amines, di-methylamine, and tri-methylamine. The alcohol oxidation activity of PpADH was strongly enhanced and the affinity for substrates was also improved by pentylamine as an activator.     

Chiral Amine Enantiomeric Excess Determination Using Self‐Assembled Octahedral Fe(II)‐Imine Complexes

A receptor assembly composed of iron(II) triflate and pyridine‐2,6‐dicarbaldehyde was used to determine the enantiomeric excess (ee) of alpha‐chiral primary amines using circular dichroism spectroscopy. The alpha chiral amines condense with the dialdehyde to form a diimine, which forms a 2:1 octahedral complex with iron(II). The ee values of unknown concentrations of alpha‐chiral amines were determined by constructing calibration curves for each amine and then measuring the ellipticity at 600 nm. This improves our previously reported assay for ee determination of chiral primary amines by further increasing the wavelength at which CD is measured and reducing the absolute error of the assay. Chirality 27:294–298, 2015. 2015 Wiley Periodicals, Inc.     

Low configurational stability of amfepramone and cathinone: Mechanism and kinetics of chiral inversion

The low configurational stability of two model compounds, the anorectic drug amfepramone and one of its basic metabolites, rac-cathinone, was examined for its mechanism and kinetics. Assuming a common intermediate for chiral inversion and deuteration, the rates of racemization were determined by the indirect method of proton–deuterium substitution monitored by ¹H-NMR. The rate of racemization increased linearily with increasing pD. At a pD of 7.4, the rate of racemization of both aminoketones was markedly dependent on buffer concentration, indicating a mechanism of general-base catalysis. The reactions were some five to six times faster in phosphate buffers than in hydroxylamine buffers of identical molarity. Amfepramone racemized about five times faster than the primary amine cathinone. One implication of these findings is that amfepramone and cathinone may be subject in vivo to chiral inversion catalyzed by numerous endogenous bases. As a result, it will be misleading to extrapolate rates of inversion expected in plasma from those measured in buffer solutions. © 1995 Wiley-Liss, Inc.