Hydroxynitrile lyases: Functions and properties

Plant hydroxynitrile lyases (Hnl) have attracted the attention of bioorganic scientists for more than 90 years. However, the most important increase in knowledge of this class of enzymes has only arisen in the recent decade. The industrial application of these enzymes as biocatalysts for the synthesis of enantiomerically pure α-cyanohydrins may be responsible for the growing interest in this area.
The Hnls are involved in the catabolic degradation of cyanogenic glycosides, releasing HCN which serves as defense agent against herbivores and microbial attack, or as a nitrogen source. Hydroxynitrile lyases from various plant families appear to represent a new example of enzymes that originated from the convergent evolution of different precursor proteins. The enzymes have been classified into non-FAD- and FAD-containing proteins. FAD-containing enzymes have been isolated exclusively from the Rosaceae, whereas the FAD-independent Hnls, which are more heterogenous in structure, have been characterized from various plant families (Poaceae, Euphorbiaceae, Linaceae, Olacaceae. Filitaceae). The aim of this review is to present a general survey of the natural function and localization of this class of enzymes and a comprehensive summary of the biochemical and genetic data of the isolated proteins.     

Evaluation of the Hydroxynitrile Lyase Activity in Cell Cultures of Capulin （Prunus serotina）

Enzymatic preparations obtained from young plants and cell cultures of capulin were screened for hydroxynitrile lyase activity. The threeweek old plants, grown under sterile conditions, were used to establish a solid cell culture. Crude preparations obtained from this plant material were evaluated for the transformation of benzaldehyde to the corresponding cyanohydrin (mandelonitrile). The results show that the crude material from roots, stalks, and leaves of young plants and calli of roots, stalks, internodes and petioles biocatalyzed the addition of hydrogen cyanide (HCN) to benzaldehyde with a modest to excellent enantioselectivity.     

Hydroxynitrile Lyases from Prunus Seeds in the Preparation of Cyanohydrins

The hydroxynitrile lyase (HNL) activity of nine defatted Prunus seeds was compared for catalyzing the addition of HCN to aromatic, heteroaromatic and α,β-unsaturated aldehydes. Although the conversion and enantiomeric excess (ee) of the corresponding cyanohydrins were both influenced by the HNL source and the chemical structure of the aldehyde, Prunus HNLs were all suitable for the enantioselective preparation of cyanohydrins.     

Hydroxynitrile Lyase Catalysis in Ionic Liquid-containing Systems

The cleavage of mandelonitrile catalysed by hydroxynitrile lyases (HNL) from Prunus amygdalus (PaHNL) and Manihot esculenta (MeHNL) proceeded more rapidly in monophasic aqueous media containing 1-propyl-3-methylimidazolium tetrafluoroborate [C₄MIm][BF₄] than in media containing acetonitrile or THF. Both HNLs were much more thermostable in [C₄MIm][BF₄] than in acetonitrile or THF. The addition of each of the four ionic liquids 1-butyl-, 1-pentyl- and 1-hexyl-3-methylimidazolium tetrafluoroborates at 2–6% (v/v in the aqueous phase) increased both the enzyme activity and the product e.e. in the PaHNL-catalysed transcyanation in an aqueous/DIPE biphasic system. However, MeHNL was inactivated by the ionic liquids, as indicated by the decreased reaction rate, substrate conversion and product e.e.     

Polysaccharide lyases

Abstract: Polysaccharide lyases are the products of various microorganisms, bacteriophage and some eukaryotes. All such enzymes cleave a hexose-1,4-α- or β-uronic acid sequence by β-elimination. They are in some examples, the only known type of enzymes degrading their polyanionic substrates. Although only a small number of these enzymes have been exhaustively studied, the pectin lyases of bacterial origin have proved to be of interesting crystal structure containing a parallel β-helix domain. Alginate and heparin lyases may yield products with biotechnological potential.     

Hydroxynitrile lyases from prunus seeds in the preparation of cyanohydrins

The hydroxynitrile lyase (HNL) activity of nine defatted Prunus seeds was compared for catalyzing the addition of HCN to aromatic, heteroaromatic and α,β-unsaturated aldehydes. Although the conversion and enantiomeric excess (ee) of the corresponding cyanohydrins were both influenced by the HNL source and the chemical structure of the aldehyde, Prunus HNLs were all suitable for the enantioselective preparation of cyanohydrins.     

High-throughput in-field bioprospecting for cyanogenic plants and hydroxynitrile lyases

Abstract

Hydroxynitrile lyases (HNLs) are sought-after, stereo-selective biocatalysts used in the agrochemical, pharmaceutical and fine chemical industries to produce cyanohydrin enantiomers. There are several approaches for the discovery of HNLs, most of which are methodologically demanding and not suitable for high-throughput. Bioprospecting studies to date have also been constrained/limited to commercialised plants or botanical gardens, leaving a vast majority of plant species untested for HNL activity or cyanogenesis. To increase the rate of discovery of HCN liberating plants, we devised a Feigl-Anger microfuge tube that is portable and capable of high throughput detection of naturally cyanogenic plants. A workflow suitable for detecting plant candidates containing extractable, novel HNLs was subsequently applied. In this study, we screened over 600 plants for cyanogenic activity as well as the ability to degrade racemic mandelonitrile. We detected 33 plants able to degrade racemic mandelonitrile, of which, 25 were identified to the species level. Six of these plants were found to be naturally cyanogenic. Protein extracts from 5 of the naturally cyanogenic plants retained the ability to degrade racemic mandelonitrile pointing to five yet undescribed enzymes in the species Achyranthes aspera, Davallia trichomonoides, Morus mesozygia, Polypodium aureum “Mandaianum”, and Thelypteris confluens. In contrast, although Acalypha glabrata was found to be naturally cyanogenic, the protein extract did not break down racemic mandelonitrile. Here, we used racemic mandelonitrile as substrate and detected enzymes with mandelonitrile lyase activity, however, any cyanohydrin could be used as part of the approach taken here to detect novel HNLs specific to the substrate utilised.     

Hydroxynitrile lyase catalyzed cyanohydrin synthesis at high pH-values

The application of unusual high pH-values within enzymatic cyanohydrin synthesis has been investigated. Usually enzymatic cyanohydrin synthesis in two-phase systems requires low pH-values within the aqueous phase to suppress the non-enzymatic side reaction. In contrast, we investigated the usage of pH-values above pH 6 by using the highly enantioselective (S)-selective hydroxynitrile lyase from Manihot esculenta. With these unusual reaction conditions also the unfavorable substrate 3-phenoxy-benzaldehyde can be converted by the wild type enzyme with excellent conversion and enantiomeric excess yielding pure (S)-3-phenoxy-benzaldehyde cyanohydrin with an enantiomeric excess of 97%. Although the variant MeHNL–W128A shows a higher activity with respect to this reaction, the enantioselectivity was reduced (85% e.e.(S)). Additionally, a new continuous spectroscopic cyanohydrin assay monitoring the formation of 3-phenoxy-benzaldehyde cyanohydrin was developed. Dedicated to Prof. Dr. Christian Wandrey on the occasion of his 65th birthday.     

Crystallization and preliminary X-ray diffraction studies of mandelonitrile lyase from almonds

Single crystals of three different isoenzymes of (R)?(+) mandelonitrile lyase (hydroxynitrile lyase) from almonds (Prunus amygdalus) have been obtained by hanging drop vapor diffusion using polyethylene glycol 4000 and isopropanol as co-precipitants. The crystals belong to the monoclinic space group P2_l with unit cell parameters a = 69.9, b = 95.1, c = 95.6 Å, and β = 118.5°. A complete set of diffraction data has been collected to 2.6 Å resolution on native crystals of isoenzyme III. © 1994 Wiley-Liss, Inc.     

Crosslinked enzyme aggregates of hydroxynitrile lyase partially purified from Prunus dulcis seeds and its application for the synthesis of enantiopure cyanohydrins

Hydroxynitrile lyases are powerful catalysts in the synthesis of enantiopure cyanohydrins which are key synthons in the preparations of a variety of important chemicals. The response surface methodology including three‐factor and three‐level Box–Behnken design was applied to optimize immobilization of hydroxynitrile lyase purified partially from Prunus dulcis seeds as crosslinked enzyme aggregates (PdHNL‐CLEAs). The quadratic model was developed for predicting the response and its adequacy was validated with the analysis of variance test. The optimized immobilization parameters were initial glutaraldehyde concentration, ammonium sulfate saturation concentration, and crosslinking time, and the response was relative activity of PdHNL‐CLEA. The optimal conditions were determined as initial glutaraldehyde concentration of 25% w/v, ammonium sulfate saturation concentration of 43% w/v, and crosslinking time of 18 h. The preparations of PdHNL‐CLEA were examined for the synthesis of (R)‐mandelonitrile, (R)‐2‐chloromandelonitrile, (R)‐3,4‐dihydroxymandelonitrile, (R)‐2‐hydroxy‐4‐phenyl butyronitrile, (R)‐4‐bromomandelonitrile, (R)‐4‐fluoromandelonitrile, and (R)‐4‐nitromandelonitrile from their corresponding aldehydes and hydrocyanic acid. After 96‐h reaction time, the yield–enantiomeric excess values (%) were 100?99, 100?21, 100?99, 83?91, 100?99, 100?72, and 100?14%, respectively, for (R)‐mandelonitrile, (R)‐2‐chloromandelonitrile, (R)‐3,4‐dihydroxymandelonitrile, (R)‐2‐hydroxy‐4‐phenyl butyronitrile, (R)‐4‐bromomandelonitrile, (R)‐4‐fluoromandelonitrile, and (R)‐4‐nitromandelonitrile. The results show that PdHNL‐CLEA offers a promising potential for the preparation of enantiopure (R)‐mandelonitrile, (R)‐3,4‐dihydroxymandelonitrile, (R)‐2‐hydroxy‐4‐phenyl butyronitrile, and (R)‐4‐bromomandelonitrile with a high yield and enantiopurity. © 2014 American Institute of Chemical Engineers Biotechnol. Prog, 30:818–827, 2014     

Kinetics and specificity of alginate lyases

A purified preparation of the extracellular alginate lyase has been used to study kinetics and specificity towards purified, homopolymeric fragments of alginate. The enzyme preparation from Bacillus circulans 1351 degraded both block types, although with different efficiency, and thus appears to be nonspecific. Addition of calcium ions markedly enhanced the reaction rate for the polymannuronate block but had little or no effect on the reaction with polyguluronate. Michaelis-Menten kinetics are not obeyed in the absence of calcium ions and only for the polymannuronate in the presence of calciumThe study of progress curves in response to variation in substrate and enzyme concentrations strongly suggests that the abalone lyase is subject to a reversible product inhibition.     

A facile regio- and stereoselective synthesis of mannose octasaccharide of the N-glycan in human CD2 and mannose hexasaccharide antigenic factor 13b

A highly concise and effective synthesis of the mannose octasaccharide of the N-linked glycan in the adhesion domain of human CD2 was achieved via TMSOTf-promoted selective 6-glycosylation of a trisaccharide 4,6-diol acceptor with a pentasaccharide donor, followed by deprotection. The pentasaccharide was constructed by selective 3,6-diglycosylation of 1,2-O-ethylidene-beta-D-mannopyranose with 2-O-acetyl-3,4,6-tri-O-benzoyl-alpha-D-mannopyranosyl-(1-->2)-3,4,6-tri-O-benzoyl-alpha-D-mannopyranosyl trichloroacetimidate, while the trisaccharide was obtained by selective 3-O-glycosylation of allyl 4,6-O-benzylidene-alpha-D-mannopyranoside with the same disaccharide trichloroacetimidate, followed by debenzylidenation. The mannose hexasaccharide antigenic factor 13b was synthesized by condensation of a trisaccharide donor, 2-O-acetyl-3,4,6-tri-O-benzoyl-alpha-D-mannopyranosyl-(1-->2)-3,4,6-tri-O-benzoyl-alpha-D-mannopyranosyl-(1-->3)-4,6-di-O-acetyl-2-O-benzoyl-alpha-D-mannopyranosyl trichloroacetimidate, with a trisaccharide acceptor, methyl 3,4,6-tri-O-benzoyl-alpha-D-mannopyranosyl-(1-->2)-3,4,6-tri-O-benzoyl-alpha-D-mannopyranosyl-(1-->2)-3,4,6-tri-O-benzoyl-alpha-D-mannopyranoside, followed by deprotection.     

海藻工具酶——褐藻胶裂解酶研究进展

从海洋生物中筛选提取有价值的酶类,开发海洋多糖降解产物,已成为海洋生物资源开发的一个重要方面。因此,近年来对于海藻工具酶之一的褐藻胶裂解酶及其降解产物——褐藻寡糖的研究日益受到人们的普遍关注。从褐藻胶裂解酶的来源、分类、底物专一性、作用方式及结构与机理研究、酶活力测定和酶学性质等方面,结合本课题组的研究工作综述近十年来有关褐藻胶裂解酶的研究进展。     

Over-expression of hydroxynitrile lyase in transgenic cassava roots accelerates cyanogenesis and food detoxification

Cassava (Manihot esculenta, Crantz) roots are the primary source of calories for more than 500 million people, the majority of whom live in the developing countries of Africa. Cassava leaves and roots contain potentially toxic levels of cyanogenic glycosides. Consumption of residual cyanogens (linamarin or acetone cyanohydrin) in incompletely processed cassava roots can cause cyanide poisoning. Hydroxynitrile lyase (HNL), which catalyses the conversion of acetone cyanohydrin to cyanide, is expressed predominantly in the cell walls and laticifers of leaves. In contrast, roots have very low levels of HNL expression. We have over-expressed HNL in transgenic cassava plants under the control of a double 35S CaMV promoter. We show that HNL activity increased more than twofold in leaves and 13-fold in roots of transgenic plants relative to wild-type plants. Elevated HNL levels were correlated with substantially reduced acetone cyanohydrin levels and increased cyanide volatilization in processed or homogenized roots. Unlike acyanogenic cassava, transgenic plants over-expressing HNL in roots retain the herbivore deterrence of cyanogens while providing a safer food product.     

Purification,Crystallization and Some Properties of Lipase from Geotrichum candidum Link

Lipase (EC 3.1.1.3) of Geotrichum candidum Link was purified by means of ammonium sulfate fractionation, DEAE-Sephadex column chromatography, gel-filtration on Sephadex G–100 and Sephadex G–200, and was finally crystallized in concentrated aqueous solution. It was confirmed that the crystallized preparation was homogeneous electrophoretically and ultracentrifugally.

It was estimated with the crystalline enzyme that the sedimentation constant (s₂₀, w) was 4.0, the isoelectric point was pH 4.33, and the molecular weight was 53,000~55,000. From the result of amino acid analysis, none of sulfur containing amino acid was detected in the enzyme. It was also recognized that the crystalline preparation contained about 7% of the carbohydrate and very small amount of lipid. It was characterized that the lipase was the most active at pH 5.6~7.0 on olive oil, at 40°C and was stable in the range of pH 4.2 to 9.8 at 30°C for 24 hr, and was stable below 55°C for 15 min.     

The characterization of mutant Bacillus subtilis adenylosuccinate lyases corresponding to severe human adenylosuccinate lyase deficiencies

Adenylosuccinate lyase is a homotetramer that catalyzes two discrete reactions in the de novo synthesis of purines: the cleavage of adenylosuccinate and succinylaminoimidazole carboxamide ribotide (SAICAR). Several point mutations in the gene encoding the enzyme have been implicated in human disease. Bacillus subtilis adenylosuccinate lyase was used as a model system in which mutations were constructed corresponding to those mutations associated with severe human adenylosuccinate lyase deficiency. Site-directed mutagenesis was utilized to construct amino acid substitutions in B. subtilis adenylosuccinate lyase; Met(10), Ile(123), and Thr(367) were replaced by Leu, Trp, and Arg, respectively, and the altered enzymes were expressed in Escherichia coli. These purified enzymes containing amino acid substitutions were found to have substantial catalytic activity and exhibit relatively small changes in their kinetic parameters. The major deviations from the wild-type-like behavior were observed upon biophysical characterization. All of these enzymes with amino acid replacements are associated with marked thermal instability. I123W adenylosuccinate lyase exhibits notable changes in the circular dichroism spectra, and a native gel electrophoresis pattern indicative of some protein aggregation. T367R also exhibits alterations at the quarternary level, as reflected in native gel electrophoresis. Experimental results, combined with homology modeling, suggest that the altered enzymes are primarily structurally impaired. The enzyme instability was found to be lessened by subunit complementation with the wild-type enzyme, under mild conditions; these studies may have implications for the in vivo behavior of adenylosuccinate lyase in heterozygous patients. Residues Met(10), Ile(123), and Thr(367) appear to be located in regions of the enzyme important for maintaining the structural integrity required for a stable, functional enzyme.     

A QM/MM study of the reaction mechanism of (R)‐hydroxynitrile lyases from Arabidopsis thaliana (AtHNL)

Hydroxynitrile lyases (HNLs) catalyze the conversion of chiral cyanohydrins to hydrocyanic acid (HCN) and aldehyde or ketone. Hydroxynitrile lyase from Arabidopsis thaliana (AtHNL) is the first R‐selective HNL enzyme containing an α/β‐hydrolases fold. In this article, the catalytic mechanism of AtHNL was theoretically studied by using QM/MM approach based on the recently obtained crystal structure in 2012. Two computational models were constructed, and two possible reaction pathways were considered. In Path A, the calculation results indicate that the proton transfer from the hydroxyl group of cyanohydrin occurs firstly, and then the cleavage of C1‐C2 bond and the rotation of the generated cyanide ion (CN^?) follow, afterwards, CN^? abstracts a proton from His236 via Ser81. The C1‐C2 bond cleavage and the protonation of CN^? correspond to comparable free energy barriers (12.1 vs. 12.2 kcal mol^?1), suggesting that both of the two processes contribute a lot to rate‐limiting. In Path B, the deprotonation of the hydroxyl group of cyanohydrin and the cleavage of C1‐C2 bond take place in a concerted manner, which corresponds to the highest free energy barrier of 13.2 kcal mol^?1. The free energy barriers of Path A and B are very similar and basically agree well with the experimental value of HbHNL, a similar enzyme of AtHNL. Therefore, both of the two pathways are possible. In the reaction, the catalytic triad (His236, Ser81, and Asp208) acts as the general acid/base, and the generated CN^? is stabilized by the hydroxyl group of Ser81 and the main‐chain NH‐groups of Ala13 and Phe82. Proteins 2015; 83:66–77. © 2014 Wiley Periodicals, Inc.