Designing cross-linked lipase aggregates for optimum performance as biocatalysts

Cross-linked enzyme aggregates (CLEAs) are prepared by precipitation of an enzyme and then chemical cross-linking the precipitate. Three CLEAs of lipase with glutaraldehyde concentrations of 10 mM (CLEA A), 40 mM (CLEA B) and 60 mM (CLEA C) were prepared. Studies show that there is a trade-off between thermal stability vs transesterification/hydrolysis rate vs enantioselectivity. The initial rates for transesterification of β-citronellol for the uncross-linked enzyme and CLEAs A, B and C were 243, 167, 102 and 40 µmol mg^-1 h^-1, respectively. Their thermal stabilities in aqueous media, as reflected by their half-life values at 55°C, were 6, 9, 13 and 16 h, respectively. The enantioselectivity, E values (for kinetic resolution of β-citronellol by transesterification) were 19, 74, 11 and 6, respectively. These results show that CLEA C was the most thermostable; the uncross-linked enzyme was best at obtaining the highest transesterification rate; and CLEA A was best suited for the enantioselective synthesis. Scanning electron microscopy (SEM) showed that the morphology of CLEA was dependent upon the extent of cross-linking.     

Production of octadecylphospho-l-serine by phospholipase d

Octadecylphospho-l-serine (OPS), belonging to the family of alkylphosphate esters with anticancer activity, was synthesized by transesterification of octadecylphosphocholine using phospholipase d (PLD). With respect to the yield of product, PLD from cabbage proved to be superior to PLD from Streptomyces spp. Although the addition of n-hexane/2-octanol is advantageous to suppress the hydrolytic byproduct, a purely aqueous reaction medium was preferred because of better recovery of the product.     

Biocatalytic Approach for the Synthesis of Enantiopure Acebutolol as a β1‐Selective Blocker

A new chemoenzymatic route is reported to synthesize acebutolol, a selective β₁ adrenergic receptor blocking agent in enantiopure (R and S) forms. The enzymatic kinetic resolution strategy was used to synthesize enantiopure intermediates (R)‐ and (S)‐N‐(3‐acetyl‐4‐(3‐chloro‐2‐hydroxypropoxy)phenyl)butyramide from the corresponding racemic alcohols. The results showed that out of eleven commercially available lipase preparations, two enzyme preparations (Lipase A, Candida antarctica, CLEA [CAL CLEA] and Candida rugosa lipase, 62316 [CRL 62316]) act in enantioselective manner. Under optimized conditions the enantiomeric excess of both (R)‐ and (S)‐N‐(3‐acetyl‐4‐(3‐chloro‐2‐hydroxypropoxy)phenyl)butyramide were 99.9 and 96.8%, respectively. N‐alkylation of both the (R) and (S) intermediates with isopropylamine gave enantiomerically pure (R and S)‐ acebutolol with a yield 68 and 72%, respectively. This study suggests a high yielding, easy and environmentally green approach to synthesize enantiopure acebutolol. Chirality 27:382–391, 2015. © 2015 Wiley Periodicals, Inc.     

Factors screening to statistical experimental design of racemic atenolol kinetic resolution via transesterification reaction in organic solvent using free Pseudomonas fluorescens lipase

As the (R )‐enantiomer of racemic atenolol has no β‐blocking activity and no lack of side effects, switching from the racemate to the (S )‐atenolol is more favorable. Transesterification of racemic atenolol using free enzymes investigated as a resource to resolve the racemate via this method is limited. Screenings of enzyme, medium, and acetyl donor were conducted first to give Pseudomonas fluorescens lipase, tetrahydrofuran, and vinyl acetate. A statistical design of the experiment was then developed using Central Composite Design on some operational factors, which resulted in the conversions of 11.70–61.91% and substrate enantiomeric excess (ee ) of 7.31–100%. The quadratic models are acceptable with R² of 95.13% (conversion) and 89.63% (ee ). The predicted values match the observed values reasonably well. Temperature, agitation speed, and substrate molar ratio factor have low effects on conversion and ee , but enzyme loading affects the responses highly. The interaction of temperature–agitation speed and temperature–substrate molar ratio show significant effects on conversion, while temperature–agitation speed, temperature–substrate molar ratio, and agitation speed–substrate molar ratio affect ee highly. Optimum conditions for the use of Pseudomonas fluorescens lipase, tetrahydrofuran, and vinyl acetate were found at 45°C, 175 rpm, 2000 U, and 1:3.6 substrate molar ratio.     

Modification of chiral dimethyl tartrate through transesterification: Immobilization on POSS and enantioselectivity reversal in sharpless asymmetric epoxidation

Modification of dimethyl tartrate has been investigated through transesterification with aminoalcohols to provide reactive functionalities for the covalent bonding of chiral tartrate to polyhedral oligomeric silsesquioxanes. The transesterification of dimethyl tartrate has been widely studied using different catalytic systems and reaction conditions. Through the proper selection of both the catalytic system and the reaction conditions, it is possible to achieve monosubstituted or bis‐substituted tartrate derivatives as sole products. All the intermediate chiral tartrate‐derived ligands were successfully used in the homogeneous enantioselective epoxidation of allylic alcohols providing moderate enantiomeric excess over the products. Attached amine groups have been used to support the modified tartrate ligands on to a haloaryl‐functionalized silsesquioxane moiety. This final chiral tartrate ligand displays reverse enantioselectivity in the asymmetric epoxidation of allylic alcohols with regard to the starting dimethyl tartrate ligand, both molecules having the same chiral sign. However, the POSS‐containing ligand can be easily recovered in almost quantitative yield and reused in asymmetric epoxidation reactions. In addition, recovered silsesquioxane‐pendant ligand, though displaying decreasing catalytic activity in recycling epoxidation tests, showed very stable enantioselective behavior. Chirality 2010. © 2009 Wiley‐Liss, Inc.     

Biodiesel production from rice bran by a two-step in-situ process

The production of fatty acid methyl esters (FAMEs) by a two-step in-situ transesterification from two kinds of rice bran was investigated in this study. The method included an in-situ acid-catalyzed esterification followed by an in-situ base-catalyzed transesterification. Free fatty acids (FFAs) level was reduced to less than 1% for both rice bran A (initial FFAs content = 3%) and rice bran B (initial FFAs content = 30%) in the first step under the following conditions: 10 g rice bran, methanol to rice bran ratio 15 mL/g, H₂SO₄ to rice bran mass ratio 0.18, 60 °C reaction temperature, 600 rpm stirring rate, 15 min reaction time. The organic phase of the first step product was collected and subjected to a second step reaction by adding 8 mL of 5 N NaOH solution and allowing to react for 60 and 30 min for rice bran A and rice bran B, respectively. FAMEs yields of 96.8% and 97.4% were obtained for rice bran A and rice bran B, respectively, after this two-step in-situ reaction.     

The RNA World and Its Evolution

This paper develops Belozersky’s early idea of the precedence of RNA in the origin of life on the Earth. Based on the current knowledge of the functional omnipotence of RNA, three new mechanisms are considered that could be critical for the origin and evolution of the ancient RNA world: (1) the reaction of spontaneous transesterification of polyribonucleotides in aqueous media, which has been recently discovered by A.B. Chetverin and colleagues and could result in elongation of short initial oligoribonucleotides and generate sequence variants for further selection; (2) compartmentation of functional RNA ensembles in the form of mixed molecular colonies on moist mineral surfaces, in the absence of membranes and other envelopes; and (3) systematic exponential enrichment of an RNA population with “ functionally the best” molecules due to alternating dissolution of the colonies upon flooding and formation of new colonies upon drying in ancient pools (“primordial natural SELEX”).__________Translated from Molekulyarnaya Biologiya, Vol. 39, No. 4, 2005, pp. 550–556.Original Russian Text Copyright © 2005 by Spirin.     

Chemoenzymatic synthesis of enantiopure 1,4-dihydropyridine derivatives

1,4-Dihydropyridines possess a broad range of biological activities, such as the ability to control the influx of calcium into cells, as well as neuroprotective, antineurodegenerative, cognition and memory enhancing, anti-inflammatory, antiviral and many other properties. Chirality plays an important role in the biological activity of 1,4-dihydropyridines. The chemoenzymatic synthesis of 1,4-dihydropyridine derivatives in enantiopure form as the key intermediates for the synthesis of enantiopure drugs and chiral analogues of symmetrical drugs has become an advantageous alternative to the other synthetic methods. Hydrolytic enzymes, as efficient chemo-, regio- and stereoselective biocatalysts have been successfully applied for the asymmetrisation or kinetic resolution of various 1,4-dihydropyridine derivatives. Several synthetic strategies to overcome the inactivity of hydrolytic enzymes towards 1,4-dihydropyridine carboxylic acids have been developed during the last decade, often based on the introduction of a spacer between an enzymatically labile group and the 1,4-DHP nucleus. Good to excellent enantioselectivities can be obtained by careful optimisation of the reaction temperature and the organic (co)solvent used in the enzymatic transformations.     

Peptide and ester synthesis in organic solvents catalyzed by seryl proteases linked to alumina

Trypsin and alpha-chymotrypsin were immobilized to alumina-phosphocolamine complex, activated by glutaraldehyde. The immobilized enzymes show a great stability toward organic solvents miscible or immiscible with water. In the presence of a low concentration of water, the immobilized enzymes catalyzed transesterification reactions as well as peptide synthesis. The synthesized peptides were stable toward the immobilized enzymes.     

纳米固体碱催化酯交换反应动力学

尿素为沉淀剂制备纳米Mg-Al水滑石,对其高温煅烧物进行X射线衍射、傅里叶变换红外光谱和扫描电子显微镜表征,以其煅烧物为催化剂催化制备生物柴油,并系统研究酯交换反应动力学。研究结果表明:纳米Mg-Al水滑石500℃煅烧6 h,水滑石特征衍射峰d(003)部分消失,柱撑阴离子碳酸根离子对称性降低,晶粒团聚成层状结构。纳米固体碱催化酯交换反应的表观反应级数为1.5,表观活化能Ea=25.92 kJ/mol,在最优条件下,生物柴油转化率高达95.4%。