Immobilization of aldoxime dehydratases on metal affinity resins and use of the immobilized catalysts for the synthesis of nitriles important in fragrance industry.

Nitriles have a wide range of uses as building blocks, solvents, and alternative fuels, but also as intermediates and components of flavors and fragrances. The enzymatic synthesis of nitriles by aldoxime dehydratase (Oxd) is an emerging process with significant advantages over conventional approaches. Here we focus on the immobilization of His-tagged Oxds on metal affinity resins, an approach that has not been used previously for these enzymes. The potential of the immobilized Oxd was demonstrated for the synthesis of phenylacetonitrile (PAN) and E-cinnamonitrile, compounds applicable in the fragrance industry. A comparison of Talon and Ni-NTA resins showed that Ni-NTA with its higher binding capacity was more suitable for the immobilization of Oxd. Immobilized Oxds were prepared from purified enzymes (OxdFv from Fusarium vanettenii and OxdBr1 from Bradyrhizobium sp.) or the corresponding cell-free extracts. The immobilization of cell-free extracts reduced time and cost of the catalyst production. The immobilized OxdBr1 was superior in terms of recyclability (22 cycles) in the synthesis of PAN from 15 mM E/Z-phenylacetaldoxime at pH 7.0 and 30 °C (100% conversion, 61% isolated yield after product purification). The volumetric and catalyst productivity was 10.5 g/L/h and 48.3 g/g of immobilized protein, respectively.

Scanning aldoxime dehydratase sequence space and characterization of a new aldoxime dehydratase from Fusarium vanettenii.

The aim of this work was to map the sequence space of aldoxime dehydratases (Oxds) as enzymes with great potential for nitrile synthesis. Microbes contain an abundance of putative Oxds but fewer than ten Oxds were characterized in total and only two in fungi. In this work, we prepared and characterized a new Oxd (protein gb|EEU37245.1 named OxdFv) from Fusarium vanettenii 77-13-4. OxdFv is distant from the characterized Oxds with a maximum of 36% identity. Moreover, the canonical Oxd catalytic triad RSH is replaced by R141-E187-E303 in OxdFv. R141A and E187A mutants did not show significant activities, but mutant E303A showed a comparable activity as the wild-type enzyme. According to native mass spectrometry, OxdFv contained almost 1 mol of heme per 1 mol of protein, and was composed of approximately 88% monomer (41.8 kDa) and 12% dimer. A major advantage of this enzyme is its considerable activity under aerobic conditions (25.0 ± 4.3 U/mg for E,Z-phenylacetaldoxime at pH 9.0 and 55 °C). Addition of sodium dithionite (reducing agent) and Fe2+ was required for this activity. OxdFv favored (aryl)aliphatic aldoximes over aromatic aldoximes. Substrate docking in the homology model of OxdFv showed a similar substrate specificity. We conclude that OxdFv is the first characterized Oxd of the REE type.

Metabolism of Aldoximes and Nitriles in Plant-Associated Bacteria and Its Potential in Plant-Bacteria Interactions.

In plants, aldoximes per se act as defense compounds and are precursors of complex defense compounds such as cyanogenic glucosides and glucosinolates. Bacteria rarely produce aldoximes, but some are able to transform them by aldoxime dehydratase (Oxd), followed by nitrilase (NLase) or nitrile hydratase (NHase) catalyzed transformations. Oxds are often encoded together with NLases or NHases in a single operon, forming the aldoxime-nitrile pathway. Previous reviews have largely focused on the use of Oxds and NLases or NHases in organic synthesis. In contrast, the focus of this review is on the contribution of these enzymes to plant-bacteria interactions. Therefore, we summarize the substrate specificities of the enzymes for plant compounds. We also analyze the taxonomic and ecological distribution of the enzymes. In addition, we discuss their importance in selected plant symbionts. The data show that Oxds, NLases, and NHases are abundant in Actinobacteria and Proteobacteria. The enzymes seem to be important for breaking through plant defenses and utilizing oximes or nitriles as nutrients. They may also contribute, e.g., to the synthesis of the phytohormone indole-3-acetic acid. We conclude that the bacterial and plant metabolism of aldoximes and nitriles may interfere in several ways. However, further in vitro and in vivo studies are needed to better understand this underexplored aspect of plant-bacteria interactions.

Chemoenzymatic one-pot reaction from carboxylic acid to nitrile via oxime.

We report a new chemoenzymatic cascade starting with aldehyde synthesis by carboxylic acid reductase (CAR) followed by chemical in situ oxime formation. The final step to the nitrile is catalyzed by aldoxime dehydratase (Oxd). Full conversions of phenylacetic acid and hexanoic acid were achieved in a two-phase mode.

Identification of Rhodococcus erythropolis Promoters Controlled by Alternative Sigma Factors Using In Vivo and In Vitro Systems and Heterologous RNA Polymerase.

Rhodococcus erythropolis CCM2595 is a bacterial strain, which has been studied for its capability to degrade phenol and other toxic aromatic compounds. Its cell wall contains mycolic acids, which are also an attribute of other bacteria of the Mycolata group, such as Corynebacterium and Mycobacterium species. We suppose that many genes upregulated by phenol stress in R. erythropolis are controlled by the alternative sigma factors of RNA polymerase, which are active in response to the cell envelope or oxidative stress. We developed in vitro and in vivo assays to examine the connection between the stress sigma factors and genes activated by various extreme conditions, e.g., heat, cell surface, and oxidative stress. These assays are based on the procedures of such tests carried out in the related species, Corynebacterium glutamicum. We showed that the R. erythropolis CCM2595 genes frmB1 and frmB2, which encode S-formylglutathione hydrolases (named corynomycolyl transferases in C. glutamicum), are controlled by SigD, just like the homologous genes cmt1 and cmt2 in C. glutamicum. The new protocol of the in vivo and in vitro assays will enable us to classify R. erythropolis promoters according to their connection to sigma factors and to assign the genes to the corresponding sigma regulons. The complex stress responses, such as that induced by phenol, could, thus, be analyzed with respect to the gene regulation by sigma factors.

Overproduction and characterization of the first enzyme of a new aldoxime dehydratase family in Bradyrhizobium sp.

Almost 100 genes within the genus Bradyrhizobium are known to potentially encode aldoxime dehydratases (Oxds), but none of the corresponding proteins have been characterized yet. Aldoximes are natural substances involved in plant defense and auxin synthesis, and Oxds are components of enzymatic cascades enabling bacteria to transform, utilize and detoxify them. The aim of this work was to characterize a representative of the highly conserved Oxds in Bradyrhizobium spp. which include both plant symbionts and members of the soil communities. The selected oxd gene from Bradyrhizobium sp. LTSPM299 was expressed in Escherichia coli, and the corresponding gene product (OxdBr1; GenBank: WP_044589203) was obtained as an N-His6-tagged protein (monomer, 40.7 kDa) with 30-47% identity to Oxds characterized previously. OxdBr1 was most stable at pH ca. 7.0-8.0 and at up to 30 °C. As substrates, the enzyme acted on (aryl)aliphatic aldoximes such as E/Z-phenylacetaldoxime, E/Z-2-phenylpropionaldoxime, E/Z-3-phenylpropionaldoxime, E/Z-indole-3-acetaldoxime, E/Z-propionaldoxime, E/Z-butyraldoxime, E/Z-valeraldoxime and E/Z-isovaleraldoxime. Some of the reaction products of OxdBr1 are substrates of nitrilases occurring in the same genus. Regions upstream of the oxd gene contained genes encoding a putative aliphatic nitrilase and its transcriptional activator, indicating the participation of OxdBr1 in the metabolic route from aldoximes to carboxylic acids.