Ondřej Kaplan

Fungal nitrilases as biocatalysts: Recent developments.

Of the numerous putative fungal nitrilases available from protein databases only a few enzymes were purified and characterized. The purified nitrilases from Fusarium solani, Fusarium oxysporum f. sp. melonis and Aspergillus niger share a preference for (hetero)aromatic nitriles, temperature optima between 40 and 50 degrees C and pH optima in the slightly alkaline region. On the other hand, they differ in their chemoselectivity, i.e. their tendency to produce amides as by-products. The production of fungal nitrilases is increased by up to three orders of magnitude on the addition of 2-cyanopyridine to the culture media. The whole-cell and subcellular biocatalysts were immobilized by various methods (LentiKats(R); adsorption on hydrophobic or ion exchange resins; cross-linked enzyme aggregates). Operational stability was examined using continuous stirred membrane bioreactors. Fungal nitrilases appear promising for biocatalytic applications and biodegradation of nitrile environmental contaminants.

Hyperinduction of nitrilases in filamentous fungi.

Abstract2-Cyanopyridine proved to act as a powerful nitrilase inducer in Aspergillusniger K10, Fusarium solani O1, Fusarium oxysporum CCF 1414, Fusarium oxysporum CCF 483 and Penicillium multicolor CCF 2244. Valeronitrile also enhanced the nitrilase activity in most of the strains. The highest nitrilase activities were produced by fungi cultivated in a Czapek-Dox medium with both 2-cyanopyridine and valeronitrile. The specific nitrilase activities of these cultures were two to three orders of magnitude higher than those of cultures grown on other nitriles such as 3-cyanopyridine or 4-cyanopyridine.

Immobilization of fungal nitrilase and bacterial amidase – two enzymes working in accord

A nitrilase from Aspergillus niger and an amidase from Rhodococcus erythropolis co-immobilized on a 1-mL Butyl Sepharose column were used for the hydrolysis of 4-cyanopyridine into isonicotinic acid. The former enzyme converted the nitrile into the acid:amide mixture (molar ratio ca. 3:1), while the latter enzyme hydrolyzed the amide by-product. Therefore, the ratio of amide in the total product decreased to about 5%. Sodium sulfate was used as a component of the elution buffer, as the commonly used ammonium sulfate (0.8 M) acted as an amidase inhibitor. The hydrolysis of 4-cyanopyridine by a nitrilase from F. solani gave isonicotinic acid and isonicotinamide at a molar ratio of about 98:2. When using this enzyme and the amidase immobilized on two columns operated in tandem, the percentage of isonicotinamide in total product decreased to <0.2%.

Heterologous expression, purification and characterization of nitrilase from Aspergillus niger K10

BackgroundNitrilases attract increasing attention due to their utility in the mild hydrolysis of nitriles. According to activity and gene screening, filamentous fungi are a rich source of nitrilases distinct in evolution from their widely examined bacterial counterparts. However, fungal nitrilases have been less explored than the bacterial ones. Nitrilases are typically heterogeneous in their quaternary structures, forming short spirals and extended filaments, these features making their structural studies difficult.ResultsA nitrilase gene was amplified by PCR from the cDNA library of Aspergillus niger K10. The PCR product was ligated into expression vectors pET-30(+) and pRSET B to construct plasmids pOK101 and pOK102, respectively. The recombinant nitrilase (Nit-ANigRec) expressed in Escherichia coli BL21-Gold(DE3)(pOK101/pTf16) was purified with an about 2-fold increase in specific activity and 35% yield. The apparent subunit size was 42.7 kDa, which is approx. 4 kDa higher than that of the enzyme isolated from the native organism (Nit-ANigWT), indicating post-translational cleavage in the enzymes native environment. Mass spectrometry analysis showed that a C-terminal peptide (Val327 - Asn356) was present in Nit-ANigRec but missing in Nit-ANigWT and Asp298-Val313 peptide was shortened to Asp298-Arg310 in Nit-ANigWT. The latter enzyme was thus truncated by 46 amino acids. Enzymes Nit-ANigRec and Nit-ANigWT differed in substrate specificity, acid/amide ratio, reaction optima and stability. Refolded recombinant enzyme stored for one month at 4°C was fractionated by gel filtration, and fractions were examined by electron microscopy. The late fractions were further analyzed by analytical centrifugation and dynamic light scattering, and shown to consist of a rather homogeneous protein species composed of 12-16 subunits. This hypothesis was consistent with electron microscopy and our modelling of the multimeric nitrilase, which supports an arrangement of dimers into helical segments as a plausible structural solution.ConclusionsThe nitrilase from Aspergillus niger K10 is highly homologous (≥86%) with proteins deduced from gene sequencing in Aspergillus and Penicillium genera. As the first of these proteins, it was shown to exhibit nitrilase activity towards organic nitriles. The comparison of the Nit-ANigRec and Nit-ANigWT suggested that the catalytic properties of nitrilases may be changed due to missing posttranslational cleavage of the former enzyme. Nit-ANigRec exhibits a lower tendency to form filaments and, moreover, the sample homogeneity can be further improved by in vitro protein refolding. The homogeneous protein species consisting of short spirals is expected to be more suitable for structural studies.

A Comparative Study of Nitrilases Identified by Genome Mining

Escherichia coli strains expressing different nitrilases transformed nitriles or KCN. Six nitrilases (from Aspergillus niger (2), A. oryzae, Neurospora crassa, Arthroderma benhamiae, and Nectria haematococca) were arylacetonitrilases, two enzymes (from A. niger and Penicillium chrysogenum) were cyanide hydratases and the others (from P. chrysogenum, P. marneffei, Gibberella moniliformis, Meyerozyma guilliermondi, Rhodococcus rhodochrous, and R. ruber) preferred (hetero)aromatic nitriles as substrates. Promising nitrilases for the transformation of industrially important substrates were found: the nitrilase from R. ruber for 3-cyanopyridine, 4-cyanopyridine and bromoxynil, the nitrilases from N. crassa and A. niger for (R,S)-mandelonitrile, and the cyanide hydratase from A. niger for KCN and 2-cyanopyridine.

Bringing nitrilase sequences from databases to life: the search for novel substrate specificities with a focus on dinitriles.

The aim of this study was to discover new nitrilases with useful activities, especially towards dinitriles that are precursors of high-value cyano acids. Genes coding for putative nitrilases of different origins (fungal, plant, or bacterial) with moderate similarities to known nitrilases were selected by mining the GenBank database, synthesized artificially and expressed in Escherichia coli. The enzymes were purified, examined for their substrate specificities, and classified into subtypes (aromatic nitrilase, arylacetonitrilase, aliphatic nitrilase, cyanide hydratase) which were largely in accordance with those predicted from bioinformatic analysis. The catalytic potential of the nitrilases for dinitriles was examined with cyanophenyl acetonitriles, phenylenediacetonitriles, and fumaronitrile. The nitrilase activities and selectivities for dinitriles and the reaction products (cyano acid, cyano amide, diacid) depended on the enzyme subtype. At a preparative scale, all the examined dinitriles were hydrolyzed into cyano acids and fumaronitrile was converted to cyano amide using E. coli cells producing arylacetonitrilases and an aromatic nitrilase, respectively.

Catabolism of Nitriles in Rhodococcus

The enzymes of nitrile catabolism in Rhodococcus include nitrilases and nitrile hydratases/amidase systems. According to their cofactor, nitrile hydratases are classified into Fe-type and Co-type subfamilies, which are typically produced by Rhodococcus erythropolis and Rhodococcus rhodochrous, respectively. The latter species is also the typical source of nitrilases, most of which strongly prefer aromatic substrates. The organization of the nitrilase, nitrile hydratase, amidase and relevant regulatory genes, and mechanisms of their expression control are shown. The unique structural and physico-chemical properties of these enzymes (subunit aggregation; Fe-type nitrile hydratase photoreactivity) are described. The overview of nitrile-converting enzyme applications emphasizes their use in the biodegradation of aliphatic nitriles and benzonitrile herbicides. The significant potential of these enzymes as biocatalysts for the production of bulk and fine chemicals is also presented. The suitability of different preparation methods for whole cells and enzymes is discussed. Finally, analytical methods for monitoring nitrile biotransformations are summarized.

Erratum to: Purification and characterization of a nitrilase from Aspergillus niger K10

Erratumto:ApplMicrobiolBiotechnol(2006)73:567–575DOI 10.1007/s00253-006-0503-6The previous article reported on the biochemical characteriza-tion of a nitrilase purified from Aspergillus niger K10. Theamino acid sequence of this enzyme was recently analyzed bymassspectroscopywhichreveale dthattheN-terminalsequencereported in Fig. 3A (by KB) in the previous article was incor-rect. This N-terminal sequence (XAPVLKKYKAAXVNXE),which was highly homologous to those of a number of hypo-thetical proteins in genus Aspergillus (Aspergillus fumigatusAf29, Aspergillus oryzae, Aspergillus nidulans FGSC A4) didnot belong to the enzyme purified and characterized in theprevious article. Mass spectrum analyses of this enzyme wererecently performed as follows. Briefly, the peptides wereextracted after in gel digestion of the enzyme withtrypsin and analyzed by MALDI-ToF MS using BrukerBiflex IV (Bruker Daltonics, Germany). Alternatively,the peptides were analyzed by using UHPLC DionexUltimate3000 RSLC nano (Dionex, Germany) equippedwith a ESI-Q-ToF Maxis Impact (Bruker Daltonics,Germany) mass spectrometer. Spectra were interpreted us-ing Mascot software (Matrix Science, UK). These analyses(Fig. S1) suggested a 42.5-58.1 % sequence coverage ofthe enzyme with a putative nitrilase from Aspergilluskawachii IFO 4308 (gi|358373570) having N-terminalsequence MSHDGPKTIRVAAVQA (Fig. 1).The N-terminal amino acid sequence reported in theprevious article belonged to another enzyme encoded inthe same strain (gb|ABX75546). This enzyme was laterexpressed in E. coli, purified and characterized, and itssubstrate specificity was found to be different from that ofthe nitrilase purified in A. niger K10 (Kaplan et al. 2011).This was hypothesized to be caused by a misfolding or by aposttranslational modification (Kaplan et al. 2011) but thishypothesis has been corrected according to the new MSanalyses (Kaplan et al., Corrigendum to: Heterologous ex-pression, purification and characterization of nitrilase fromAspergillus niger K10 (BMC Biotechnol (2011) 11:2).BMC Biotechnol, submitted manuscript). The aforemen-tioned enzyme from A. nidulans FGSC A4 was later char-acterized as a cyanide hydratase (Basile et al. 2008). In

Expression control of nitrile hydratase and amidase genes in Rhodococcus erythropolis and substrate specificities of the enzymes

Bacterial amidases and nitrile hydratases can be used for the synthesis of various intermediates and products in the chemical and pharmaceutical industries and for the bioremediation of toxic pollutants. The aim of this study was to analyze the expression of the amidase and nitrile hydratase genes of Rhodococcus erythropolis and test the stereospecific nitrile hydratase and amidase activities on chiral cyanohydrins. The nucleotide sequences of the gene clusters containing the oxd (aldoxime dehydratase), ami (amidase), nha1, nha2 (subunits of the nitrile hydratase), nhr1, nhr2, nhr3 and nhr4 (putative regulatory proteins) genes of two R. erythropolis strains, A4 and CCM2595, were determined. All genes of both of the clusters are transcribed in the same direction. RT-PCR analysis, primer extension and promoter fusions with the gfp reporter gene showed that the ami, nha1 and nha2 genes of R. erythropolis A4 form an operon transcribed from the Pami promoter and an internal Pnha promoter. The activity of Pami was found to be weakly induced when the cells grew in the presence of acetonitrile, whereas the Pnha promoter was moderately induced by both the acetonitrile or acetamide used instead of the inorganic nitrogen source. However, R. erythropolis A4 cells showed no increase in amidase and nitrile hydratase activities in the presence of acetamide or acetonitrile in the medium. R. erythropolis A4 nitrile hydratase and amidase were found to be effective at hydrolysing cyanohydrins and 2-hydroxyamides, respectively.