Veselá Alicja B, Křenková Alena, Martínková Ludmila
Laboratory of Biotransformation, Academy of Sciences of the Czech Republic, Vídeňská 1083, 142 20, Prague, Czech Republic,
Mol Biotechnol. 2015 May;57(5):466-74. doi: 10.1007/s12033-015-9840-y.
The application of arylacetonitrilases from filamentous fungi to the hydrolysis of high concentrations of (R,S)-mandelonitrile (100-500 mM) was demonstrated for the first time. Escherichia coli strains expressing the corresponding genes were used as whole-cell catalysts. Nitrilases from Aspergillus niger, Neurospora crassa, Nectria haematococca, and Arthroderma benhamiae (enzymes NitAn, NitNc, NitNh, and NitAb, respectively) exhibited different degrees of enantio- and chemoselectivity (amide formation). Their enantio- and chemoselectivity was increased by increasing pH (from 8 to 9-10) and adding 4-10% (v/v) toluene as the cosolvent. NitAn and NitNc were able to convert an up to 500 mM substrate in batch mode. NitAn formed a very low amount of the by-product, amide (<1% of the total product). This enzyme produced up to >70 g/L of (R)-mandelic acid (e.e. 94.5-95.6%) in batch or fed-batch mode. Its volumetric productivities were the highest in batch mode [571 ± 32 g/(L d)] and its catalyst productivities in fed-batch mode (39.9 ± 2.5 g/g of dcw). NitAb hydrolyzed both enantiomers of 100 mM (R,S)-mandelonitrile at pH 5.0 and is therefore promising for the enantioretentive transformation of (S)-mandelonitrile. Sequence analysis suggested that fungal arylacetonitrilases with similar properties (enantioselectivity, chemoselectivity) were clustered together.
首次证明了丝状真菌来源的芳基乙腈酶可用于水解高浓度(100 - 500 mM)的(R,S)-扁桃腈。表达相应基因的大肠杆菌菌株用作全细胞催化剂。黑曲霉、粗糙脉孢菌、血红色镰孢菌和贝氏节皮菌的腈水解酶(分别为酶NitAn、NitNc、NitNh和NitAb)表现出不同程度的对映选择性和化学选择性(酰胺形成)。通过将pH从8提高到9 - 10并添加4 - 10%(v/v)甲苯作为助溶剂,它们的对映选择性和化学选择性得到了提高。NitAn和NitNc能够在分批模式下转化高达500 mM的底物。NitAn形成的副产物酰胺量非常低(<总产物的1%)。该酶在分批或补料分批模式下可产生高达>70 g/L的(R)-扁桃酸(对映体过量值为94.5 - 95.6%)。其体积产率在分批模式下最高[571 ± 32 g/(L·d)],在补料分批模式下其催化剂产率为(39.9 ± 2.5 g/g干细胞重量)。NitAb在pH 5.0时可水解100 mM(R,S)-扁桃腈的两种对映体,因此有望用于(S)-扁桃腈的对映体保留转化。序列分析表明,具有相似性质(对映选择性、化学选择性)的真菌芳基乙腈酶聚集在一起。