Thioethyl-, Vinyl-, Ethyl Octanoate Esters and Octanoic Acid as Acyl Donors in Lipase Catalysed Acyl Transfer Reactions

S-Ethyl thiooctanoate, vinyl octanoate, ethyl octanoate and octanoic acid were studied as acyl donors in a lipase catalysed acyl transfer reaction with 2-octanol as acyl acceptor. The reaction conditions had a pronounced effect on the equilibrium displacement and the apparent enantioselectivity. The thioethyl and vinyl esters proved to be efficient acyl donors under atmospheric pressure and 39 d`C, affording a high apparent enantiomeric ratio. Under these reaction conditions the apparent enantioselectivity seemed to be enhanced by water, which was present in the reaction system and caused the production of octanoic acid, by hydrolysis of me acyl enzyme.     

Structural aspects of acylated plant pigments: stabilization of flavonoid glucosides and interpretation of their functions

The enzymatic synthesis of acylated isoquercitrins was accomplished by the lipase-catalyzed transesterification with carboxylic acid vinyl esters as acyl donors in an organic solvent. The introduction of an acyl group into isoquercitrin improved its thermostability and light-resistivity. In particular, isoquercitrin p-coumarate was the most stable of all the acylated isoquercitrins tested.     

Regio-selective acylation of biologically important iridoid glycosides by Candida antarctica lipase

Lipase catalyzed regio-selective acylation of five iridoid glycosides viz., picroside I&II, catalpol, agnuside and negundoside in the presence of various acyl donors such as vinyl acetate and p-nitrophenyl alkanoates was studied. The regio-selectivity of enzymatic acylation and yields were found to vary amongst different substrates. Monoacylated products were isolated with all the substrates under scrutiny indicating high regio-selective nature of such transformations. A series of acyl esters of picroside-I, picroside-II, catalpol, agnuside and negundoside have been synthesized by this enzymatic trans-esterification methodology.     

Novel and Highly Efficient Regioselective Route to Helicid Esters by Lipozyme TLL

Highly regioselective acylation of helicid with fatty acid vinyl esters catalyzed by the lipase from Thermomyces lanuginosus has been successfully performed for the first time. For the enzymatic caproylation of helicid, under the optimal conditions, initial reaction rate was 33.2 mM/h, and substrate conversion and regioselectivity were greater than 99%. In addition, the acyl recognition of the enzyme in the regioselective acylation of helicid was investigated. The results showed that although 6’-O-acyl derivatives of helicid were exclusively obtained with all the tested acyl donors, the enzymatic reaction rate varied widely with different acyl donors, presumably owing to their different interactions with the active site of the lipase. It is also interesting that the different configuration of only one hydroxyl group at C-3 in helicid couldn’t affect the lipase-catalyzed esterification and helicid has the same regioselectivity as that of D-glucose and arbutin.     

A lipase‐catalyzed process for green synthesis of temsirolimus

Temsirolimus is an intravenous drug for the treatment of renal cell carcinoma that can be prepared using enol acyl donors, which is not favorable in process development. An improved enzymatic process to prepare temsirolimus has been developed employing lipase‐catalyzed regioselective acylation of rapamycin with environmentally friendly acyl donors. After screening of common commercial lipases and none‐enol acyl donors, it was found that p‐nitrophenyl 2,2,5‐trimethyl‐1,3‐dioxane‐5‐carboxylate reacted as efficient acyl donor when catalyzed by immobilized Thermomyces lanuginose lipase. By optimizing the process conditions (i.e., reaction temperature, solvents, and additives), the reaction time was significantly shortened while the reaction conversion reached 95.4% in methyl tert‐butyl ether after 48 h at 50°C using the new acyl donors. This work demonstrated a cost‐effective, efficient, and scalable process to synthesize temsirolimus.     

Esterification of streptol — a cyclitol derivative — by Candida rugosa lipase: influence of the acyl donor on regioselectivity

The influence of the nature of acyl donors on the regioselectivity of Candida rugosa lipase for the esterification of streptol — a cyclitol derivative — was investigated. Excellent regioselectivity for the formation of 3,7-disubstituted derivatives was observed for vinyl butyrate (100% 3,7-derivative, 68% yield) and vinyl propionate (100% 3,7-derivative, 46% yield) as acyl donors. In contrast, for vinyl methacrylate as acyl donor, a mixture of 71% 3,7-derivative and 29% 1,7-derivative was obtained. Varying the chain length, a certain dependency of regioselectivity on the acyl donor was observed, however, no logical correlation satisfying all cases was found. Mono-substituted streptol derivatives were obtained by employing Novozym 243.     

Engineering of substrate mimetics as novel-type substrates for glutamic acid-specific endopeptidases: design, synthesis, and application

This account reports on the development and function of novel substrate mimetics as artificial substrates for Glu-specific endopeptidases. Firstly, in an empirical way, various aliphatic and aromatic analogs of the already established carboxymethyl thioester-substrate mimetics were designed from simple structure-function relationship studies. The specificity of the newly developed substrates for Staphylococcus aureus V8 protease-catalyzed reactions have been examined by steady-state hydrolysis kinetic studies. Additionally, these studies were expanded to the use of the equally Glu-specific endopeptidase from Bacillus licheniformis (BL-GSE) which can easily be purified from alcalase in high yields. Finally, the novel substrate mimetics were used as acyl donor components in BL-GSE- and V8 protease-catalyzed model acyl transfer reactions. The results clarify the newly developed substrate mimetics as efficient acyl donors as well as BL-GSE as an attractive alternative to V8 protease for enzymatic peptide synthesis.     

酰基供体结构对褶皱念珠茵脂肪酶（CRL）催化芳香仲醇动力学拆分立体选择性的影响

研究仲醇的酶催化动力学拆分机制,发现酰基供体的结构是影响酶催化动力学拆分选择性的一个重要因素。通过实验发现了一类用于仲醇动力学拆分（KR）的优秀酰基供体——长链有机酸的对氯苯酚酯,并将这种酰基供体成功用于褶皱念珠菌脂肪酶（CRL）催化的仲醇动力学拆分过程。在1-苯乙醇的动力学拆分（KR）过程中,随着对氯苯酚有机酸酯供体中酰基部分碳原子数的增加,产物的对映体过量值（e．e.p值）也在不断地提高。当碳原子数≥5,转化率达到50％时,产物的叫．。值仍能保持大于99％。这样的规律也适用于其他的仲醇拆分过程,当选择对氯苯酚戊酸酯作为酰基供体用于其他仲醇的动力学拆分过程时,可以实现仲醇的高效拆分,反应6h转化率达到50％,产物的对映体过量值e．e．p为100％。     

A novel and efficient enzymatic method for the production of peptides from unprotected starting materials

We report herein the development of a novel and efficient enzymatic method for the production of oligopeptides. This newly discovered method is a simple, cost-effective process, using unprotected amino acids as substrates in an aqueous solution and producing peptides in high yield. The target of our initial screen was l-alanyl-L-glutamine, a dipeptide of significant industrial interest by virtue of its widespread use in infusion therapy. By means of the screening of microorganisms that can catalyze the peptide-forming reaction producing l-alanyl-L-glutamine from L-alanine methylester (acyl donor) and L-glutamine (nucleophile), we discovered that Empedobacter brevis ATCC 14234 produced l-alanyl-L-glutamine most efficiently. The newly found enzyme purified from E. brevis ATCC 14234 facilitates significantly high production yields of l-alanyl-L-glutamine from L-alanine methylester and L-glutamine in an aqueous solution--more than 80% yield based on L-alanine methylester. In addition, this enzyme has wide substrate specificity--both for acyl donors and nucleophiles--and can catalyze peptide-forming reactions not only to produce various dipeptides from the corresponding amino acid esters and amino acids but also to produce various oligopeptides from the corresponding amino acid esters and peptides.     

In vitro enzymatic synthesis of baccatin III with novel and cheap acetyl donors by the recombinant taxoid 10β-O-acetyl transferase

Despite the importance of baccatin III as a precursor to paclitaxel, a widely used chemotherapeutic agent, efficient enzymatic synthesis methods are lacking. Therefore, in this study, the recombinant taxoid 10β-O-acetyl transferase was prepared to produce baccatin III in vitro. The recombinant enzyme could use vinyl acetate, butyl acetate, sec-butyl acetate, isobutyl acetate, amyl acetate, and isoamyl acetate as novel and cheap alternative acetyl group donors to replace the expensive acetyl CoA for the enzymatic synthesis of baccatin III. A molecular docking study further confirmed that these acetyl donors could reasonably bind to the enzyme molecule. Using the aqueous two-phase bio-catalytic reaction system, hexane and ethyl acetate could increase the yield of product baccatin III by 2.8% and 1.1% respectively. This approach using novel and cheap acetyl donors is promising for the enzymatic synthesis of baccatin III for the future industrial production of paclitaxel.     

Enzyme catalyzed synthesis of some vinyl drug esters in organic medium

A series of vinyl drug esters was synthesized using acyclovir and chloramphenicol with different carbon chain length acyl donors by alkaline protease from Bacillus subtilis and Lipozyme respectively, in non-aqueous medium. The corresponding vinyl drug derivatives were confirmed by nuclear magnetic resonance and infrared spectrometry. The influences of different organic solvents, reaction time, temperature, and content of water on synthesis of vinyl chloramphenicol esters were studied.     

Effect of ultrasound on enzymatic acylation of konjac glucomannan

A comparative study was made of enzymatic acylation of konjac glucomannan with vinyl esters under ultrasonic irradiation and shaking in organic solvent tert-butanol. Among the 13 enzymes selected, Novozym 435 exhibited the highest acylation activity towards KGM whether under ultrasonic irradiation or shaking. The application of ultrasonic irradiation instead of shaking during the acylation led to improvement in the initial reaction rate, yield and degree of substitution of the modified KGM. Appropriate ultrasound power (100 W) and water activity (0.75) were found to accelerate enzymatic reaction. The acceleration effect of ultrasound on Novozym 435-catalyzed acylation decreased with an increase in the chain length of the acyl donors from C2 to C18. Moreover, the acylation of KGM in tert-butanol was proved to be a regioselective one, with C6-OH being acylated. Compared with shaking, ultrasound did not change regioselectivity of Novozym 435 in the acylation.     

Donor specificity and regioselectivity in Lipolase mediated acylations of methyl α-d-glucopyranoside by vinyl esters of phenolic acids and their analogues

Methyl α-d-glucopyranoside as a model acceptor was acylated by several phenolic and non-phenolic vinyl esters using immobilised Lipolase. Donor specificity and regioselectivity of reaction were investigated. Conversion and rate of acylation by structurally varied donors indicates that the synthetic reactivity of Lipolase corresponds to the hydrolytic activity of feruloyl esterase type A. Lipolase exhibited remarkable regioselectivity for primary position of methyl α-d-glucopyranoside. The acylation occurred exclusively at 6-O primary position when vinyl esters of phenolic acids (hydroxybenzoates, hydroxyphenylalkanoates and hydroxycinnamates) served as acyl donors (5–77%). In addition to the major 6-O-acyl products (52–79%), 2,6-di-O-acylated derivatives were isolated from reaction mixtures (2–13%) when non-phenolic donors were used (vinyl esters of fully methoxylated derivatives of phenolic acids, along with vinyl benzoates, cinnamates or some heterocyclic analogues).     

Trypsin-catalysed synthesis of oligopeptide amides: comparison of catalytic efficiency among trypsins of different origin (bovine, Streptomyces griseus and chum salmon).

A procedure has been developed for the synthesis of oligopeptide amide using inverse substrates as acyl donors with amino acid amide instead of p-nitroanilide as acyl acceptor and trypsins of different origin (bovine, Streptomyces griseus and chum salmon trypsins) as the catalyst. The effectiveness of this procedure was demonstrated by the synthesis of a pentapeptide, Boc-[Leu5]-enkephalin amide, as a model compound. The method was the first enzymatic method shown to be successful at each successive coupling step for the synthesis of the oligopeptide. Bovine and chum salmon trypsins were superior to Streptomyces griseus trypsin as the catalyst.     

Enzymatic synthesis of terpenyl esters by transesterification with fatty acid vinyl esters as acyl donors by Trichosporon fermentans lipase

Enzymatic synthesis of terpenyl esters by esterification or transesterification with fatty acid vinyl esters as acyl donors by celite-adsorbed lipase of Trichosporon fermentans was investigated. In direct esterification of geraniol, the lipase showed high reactivity toward fatty acids with carbon chains longer than C-8, but little reactivity toward fatty acids with shorter chains. With fatty acid vinyl esters as acyl donors, the lipase catalysed the synthesis of geranyl and citronellyl esters with carbon chains shorter than C-6 in with yields of >90% molar conversion. Time course, effects of added water, temperature and substrate concentration were studied for the synthesis of geranyl acetate. Molar conversion yield reached 97.5% after 5 h incubation at 30–40°C with the addition of 3% water. In this reaction, no inhibition by substrates such as geraniol and vinyl acetate was observed.     

Enzymatic synthesis of terpenyl esters by transesterification with fatty acid vinyl esters as acyl donors by Trichosporon fermentans lipase

Enzymatic synthesis of terpenyl esters by esterification or transesterification with fatty acid vinyl esters as acyl donors by celite-adsorbed lipase of Trichosporon fermentans was investigated. In direct esterification of geraniol, the lipase showed high reactivity toward fatty acids with carbon chains longer than C-8, but little reactivity toward fatty acids with shorter chains. With fatty acid vinyl esters as acyl donors, the lipase catalysed the synthesis of geranyl and citronellyl esters with carbon chains shorter than C-6 in with yields of >90% molar conversion. Time course, effects of added water, temperature and substrate concentration were studied for the synthesis of geranyl acetate. Molar conversion yield reached 97.5% after 5 h incubation at 30–40°C with the addition of 3% water. In this reaction, no inhibition by substrates such as geraniol and vinyl acetate was observed.     

Reaction design for evaluation of the substrate range of hydrolases

Biocatalytic acylation reactions involving 24 alcohols, 8 acyl donors and 6 hydrolases were analysed using an original method. The reaction outcome was determined by semi-automated semi-automated solid-phase microextraction and GC/MS (SPME-GC/MS) allowing rapid evaluation of the success rate of each enzyme. Using Candida antarctica Lipase B (CALB), in 36% of the cases (46 reactions) quantitative conversion of the starting alcohol was observed, with an average isolated yield of 96%. The platform was then used to screen other enzymes with the CALB non-reacting substrates, allowing the design and optimisation of some efficient enzymatic reactions. Modification of the odour profile of rose essential oils by enzymatic treatment was also carried out.     

Resolution of 2-phenoxy-1-propanols through the enantioselective acylation mediated by Achromobacter sp. lipase as biocatalyst

Enantioselective acylation employing vinyl alkanoates as acyl donors was exploited for the resolution of 2-(substituted phenoxy)-1-propanols carrying different substituents on the benzene ring using Achromobacter sp. lipase. These primary alcohols with an oxygen atom at the stereocenter, were resolved with moderate to good enantioselectivity, based on the enantiomeric ratio E (up to 27), through acylation with vinyl butanoate in diisopropyl ether, after the examination of potential factors affecting the reaction such as organic solvents and acyl donors. Using this procedure, enantiomerically enriched (R)-2-(4-chlorophenoxy)-1-propanol was prepared in 97% e.e. and 33% yield in a gram-scale reaction.     

Reaction design for evaluation of the substrate range of hydrolases

Biocatalytic acylation reactions involving 24 alcohols, 8 acyl donors and 6 hydrolases were analysed using an original method. The reaction outcome was determined by semi-automated semi-automated solid-phase microextraction and GC/MS (SPME-GC/MS) allowing rapid evaluation of the success rate of each enzyme. Using Candida antarctica Lipase B (CALB), in 36% of the cases (46 reactions) quantitative conversion of the starting alcohol was observed, with an average isolated yield of 96%. The platform was then used to screen other enzymes with the CALB non-reacting substrates, allowing the design and optimisation of some efficient enzymatic reactions. Modification of the odour profile of rose essential oils by enzymatic treatment was also carried out.     

Resolution of 2-phenoxy-1-propanols through the enantioselective acylation mediated by Achromobacter sp. lipase as biocatalyst

Enantioselective acylation employing vinyl alkanoates as acyl donors was exploited for the resolution of 2-(substituted phenoxy)-1-propanols carrying different substituents on the benzene ring using Achromobacter sp. lipase. These primary alcohols with an oxygen atom at the stereocenter, were resolved with moderate to good enantioselectivity, based on the enantiomeric ratio E (up to 27), through acylation with vinyl butanoate in diisopropyl ether, after the examination of potential factors affecting the reaction such as organic solvents and acyl donors. Using this procedure, enantiomerically enriched (R)-2-(4-chlorophenoxy)-1-propanol was prepared in 97% e.e. and 33% yield in a gram-scale reaction.