Oxidative functionalization of a halimane diterpenoid achieved by fungal transformation

Regio and stereoselective activation of sp³ CH bonds remain one of the major advantages of biocatalysis over traditional chemocatalytic methods. Herein, we describe the oxy-functionalization of halimane diterpenoid 1 by whole cells of three filamentous fungi, aiming to obtain derivatives with desirable biological properties. After incubating 1 with Fusarium oxysporum, Myrothecium verrucaria, and Rhinocladiella similis at different concentrations and incubation times, four known (3, 5, 6, and 7) and three new (2, 4, and 8) halimane derivatives were obtained and characterized. F. oxysporum catalyzed the hydroxylation of positions C-2 (2) and C-7 (4), while R. similis simultaneously mediated the 2-oxo-functionalization and the hydration of 13,14-(CC)double bond belonging to an α,β-unsaturated carbonyl system (8). Compounds 1–7 were non-cytotoxic against HCT-116 and MCF-7 cancer cell lines at tested concentrations. However, substrate 1 displayed moderate reduction ability against biofilm produced by Staphylococcus epidermidis ATCC35984 (84% at 1.6 mM), and this effect was retained to some extent by derivatives 4 and 7. These results emphasize the prominent potential of filamentous fungi associated with the microbiota of medicinal plants as versatile catalysts for singularly useful reactions through their complex enzymatic machinery, as well as the high susceptibility of halimane-diterpenoid substrates.     

固定化真菌漆酶降解氯苯嘧啶醇农药

在葡萄糖培养基中,栓菌420(Trametes sp.420)经6mmol/L邻甲苯胺诱导,漆酶活力达到4535U/L(愈创木酚法)。用弱阴离子交换层析可分离得到纯化漆酶。以壳聚糖为载体,戊二醛为交联剂对漆酶进行固定化,30g壳聚糖与30U漆酶混合,酶活回收率高达69%。在酸性条件下,固定化漆酶对农药氯苯嘧啶醇具有良好的降解作用。     

Towards semisynthetic natural compounds with a biaryl axis: Oxidative phenol coupling in Aspergillus niger

Regio- and stereoselective phenol coupling is difficult to achieve using synthetic strategies. However, in nature, cytochrome P450 enzyme-mediated routes are employed to achieve complete axial stereo- and regiocontrol in the biosynthesis of compounds with potent bioactivity. Here, we report a synthetic biology approach whereby the bicoumarin metabolic pathway in Aspergillus niger was specifically tailored towards the formation of new coupling products. This strategy represents a manipulation of the bicoumarin pathway in A. niger via interchange of the phenol-coupling biocatalyst and could be applied to other components of the pathway to access a variety of atropisomeric natural product derivatives.     

Enzymatic coupling of phenol vapors onto chitosan.

Phenols are important industrial chemicals, and because they can be volatile, also appear as air pollutants. We examined the potential of tyrosinase to react with the volatile phenol p-cresol. Three lines of evidence support the conclusion that volatile phenols react with tyrosinase and are coupled (i.e., chemisorbed) onto chitosan films. First, phenol-trapping studies indicated that p-cresol can be removed from vapors if the vapors are contacted with tyrosinase-coated chitosan films. Second, the ultraviolet absorbance of tyrosinase-coated chitosan films changes dramatically when they are contacted with cresol-containing vapors, whereas control films are unaffected by contacting with cresol vapors. Third, pressure measurements indicate that tyrosinase-coated chitosan films only react with cresol vapors if the oxygen cosubstrate is present. Additional studies demonstrate the potential of tyrosinase-coated chitosan films/membranes for the detection and removal of phenol vapors.     

Reaction of fungal amine oxidase with beta-bromoethylamine.

beta-Br-ethylamine is both a substrate and an irreversible inhibitor of amine oxidase from Aspergillus niger. The enzyme catalyzes the nonoxidative elimination of HBr from beta-Br-ethylamine to form acetaldehyde. beta-Br-ethylamine meets several criteria for an irreversible substrate analog or suicide inhibitor. 1) It inactivates the oxidized enzyme, but not the reduced enzyme. 2) The Michaelis constant for beta-Br-ethylamine in the elimination reaction showed a similar magnitude to that of the related constant found when the haloamine acted as an inhibitor. 3) The enzyme was protected from the inactivation by the co-existence of the substrate. 4) Inactivation with beta-Br-[14C]ethylamine resulted in the incorporation of radioactivity corresponding to 1 mol of the label/mol of the monomeric unit of the enzyme and a decrease of 1 mol of the -SH group. 5) Inactivation was accompanied by the formation of a new absorption peak at 320 nm which was bleached by addition of NaBH4.     

Summer drought decreases soil fungal diversity and associated phenol oxidase activity in upland Calluna heathland soil

Natural moisture limitation during summer drought can constitute a stress for microbial communities in soil. Given globally predicted increases in drought frequency, there is an urgent need for a greater understanding of the effects of drought events on soil microbial processes. Using a long-term field-scale drought manipulation experiment at Clocaenog, Wales, UK, we analysed fungal community dynamics, using internal transcribed spacer-denaturing gradient gel electrophoresis (DGGE), over a 1-year period in the 6th year of drought manipulation. Ambient seasonality was found to be the dominant factor driving variation in fungal community dynamics. The summer drought manipulation resulted in a significant decline in the abundance of dominant fungal species, both independently of, and in interaction with, this seasonal variation. Furthermore, soil moisture was significantly correlated with the changes in fungal diversity over the drought manipulation period. While the relationship between species diversity and functional diversity remains equivocal, phenol oxidase activity was decreased by the summer drought conditions and there was a significant correlation with the decline of DGGE band richness among the most dominant fungal species during the drought season. Climatically driven events such as droughts may have significant implications for fungal community diversity and therefore, have the potential to interfere with crucial ecosystem processes, such as organic matter decomposition.     

Enzymological characterization of EpoA,a laccase-like phenol oxidase produced by Streptomyces griseus

Laccase is an enzyme that catalyzes the oxidation of phenolic compounds by coupling the reduction of oxygen to water. While many laccases have been identified in plant and fungal species, enzymes of prokaryotic origin are poorly known. Here we report the enzymological characterization of EpoA, a laccase-like extracytoplasmic phenol oxidase produced by Streptomyces griseus. EpoA was expressed and purified with an Escherichia coli host-vector system as a recombinant protein fused with a C-terminal histidine-tag (rEpoA). Physicochemical analyses showed that rEpoA comprises a stable homotrimer containing all three types of copper (types 1-3). Various known laccase substrates were oxidized by rEpoA, while neither syringaldazine nor guaiacol served as substrates. Among the substrates examined, rEpoA most effectively oxidized N,N-dimethyl-p-phenylenediamine sulphate with a Km value of 0.42 mM. Several metal chelators caused marked inhibition of rEpoA activity, implying the presence of a metal center essential for the oxidase activity. The pH and temperature optima of rEpoA were 6.5 and 40 degrees C, respectively. The enzyme retained 40% activity after preincubation at 70 degrees C for 60 min. EpoA-like activities were detected in cell extracts of 8/40 environmental actinomycetes strains, which suggests that similar oxidases are widely distributed among this group of bacteria.     

N-acetyl-6-hydroxytryptophan oxidase, a developmentally controlled phenol oxidase from Aspergillus nidulans

We have purified a specific phenol oxidase which is produced during conidiophore development in the fungus Aspergillus nidulans. Two active forms (A and B) have molecular masses of 50 and 48 kDa respectively; they have identical N-termini (24 residues). We have analysed the metal ion content of the B form; it is unusual in consisting of one zinc and two copper atoms per molecule. A temperature-sensitive mutant (ivoB192) produces a thermolabile enzyme, implying that ivoB is the structural locus. The natural substrate of the enzyme is N-acetyl-6-hydroxytryptophan, but it can be assayed colorimetrically or polarographically using hydroquinone monomethyl ether (HME) as substrate. It will also oxidize p-cresol, but not tyrosine, 3,4-dihydroxyphenylalanine or o-methoxyphenol. Colour development with HME substrate is strongly enhanced by high ammonium ion concentrations. Activity against HME is inhibited by 2,3-dihydroxynaphthalene, phenylhydrazine, diethyl dithiocarbamate and 8-hydroxyquinolene.     

Determination of binary pesticide mixtures by an acetylcholinesterase-choline oxidase biosensor

In this study, acetylcholinesterase (AChE) and choline oxidase (ChO) were co-immobilized on poly(2-hydroxyethyl methacrylate) (pHEMA) membranes to construct a biosensor for the detection of anti-cholinesterase compounds. pHEMA membranes were prepared with the addition of SnCl(4) to achieve the desired porosity. Immobilization of the enzymes was done by surface attachment via epichlorohydrin (Epi) and Cibacron Blue F3G-A (CB) activation. Enzyme immobilized membrane was used in the detection of anti-cholinesterase activity of aldicarb (AS), carbofuran (CF) and carbaryl (CL), as well as two mixtures, (AS+CF) and (AS+CL). The total anti-cholinesterase activity of binary pesticide mixtures was found to be lower than the sum of the individual inhibition values.     

Limited bacterial mineralization of fungal degradation intermediates from synthetic lignin.

The ability of selected bacterial strains and consortia to mineralize degradation intermediates produced by Phanerochaete chrysosporium from 14C-labeled synthetic lignins was studied. Three different molecular weight fractions of the intermediates were subjected to the action of the bacteria, which had been grown on a lignin-related dimeric compound. Two consortia isolated from wood being decayed naturally by a Ganoderma species of white rot fungus (the palo podrido system) mineralized 10 to 11% of the fraction with a molecular weight of approximately 500 but less than 4% of the higher- and lower-molecular-weight fractions. The consortia mineralized 5 to 9% of the original lignins. The ability of two pseudomonads isolated earlier from lignin-rich environments to mineralize the original lignins or fungus degradation products was much lower.     

Low temperature trapping method for cytochrome oxidase oxygen intermediates.

The trapping of intermediates in the cytochrome oxidase-oxygen reaction is made possible by a three-step procedure: 1) Oxygenation of the ferrous cytochrome oxidase-carbon monoxide compound at a temperature sufficiently low that no ligand exchange with oxygen occurs (?20 to ?30°C); 2) flash photolysis at a temperature sufficiently low that the subsequent reaction with oxygen can readily be measured with a multichannel spectrophotometer; 3) rapid cooling of the reaction in progress to a sufficiently low temperature that no further reaction takes place and detailed optical or electron paramagnetic resonance spectroscopy can be performed. Since the freezing point of the mitochondrial suspensions during oxygenation can be in the range of ?20°C, only nondeleterious concentrations of ethylene glycol are employed. The reaction kinetics are observed in the solid state in small-diameter circular tubes suitable for rapid trapping. Efficient optical coupling to the sample tube for transmission spectroscopy and efficient laser photolysis are similarly provided by fiber optics coupling. The method is suitable for studying in detail three compounds of cytochrome oxidase and oxygen formed in the temperature range from ?125°C upwards. In addition, the electron transfer processes of the respiratory chain are accurately delineated.     

Limited bacterial mineralization of fungal degradation intermediates from synthetic lignin.

The ability of selected bacterial strains and consortia to mineralize degradation intermediates produced by Phanerochaete chrysosporium from 14C-labeled synthetic lignins was studied. Three different molecular weight fractions of the intermediates were subjected to the action of the bacteria, which had been grown on a lignin-related dimeric compound. Two consortia isolated from wood being decayed naturally by a Ganoderma species of white rot fungus (the palo podrido system) mineralized 10 to 11% of the fraction with a molecular weight of approximately 500 but less than 4% of the higher- and lower-molecular-weight fractions. The consortia mineralized 5 to 9% of the original lignins. The ability of two pseudomonads isolated earlier from lignin-rich environments to mineralize the original lignins or fungus degradation products was much lower.     

Protonation states of the catalytic intermediates of cytochrome c oxidase.

Protonation changes accompanying conversion of oxidised (O state) cytochrome c oxidase to the 2-electron-reduced P state, and 3-electron-reduced F state at pH 8.0 have been measured. It was found that 2 and 3 protons, respectively, were taken up. The fourth proton required for the reduction of O2 to H2O must therefore be consumed in the remaining F----O portion of the catalytic cycle.     

Production of an aromatic aldehyde oxidase by Streptomyces viridosporus

Streptomyces viridosporus strain T7A, when grown in liquid media containing yeast extract and aromatic aldehydes, oxidized the aromatic aldehydes to the corresponding aromatic acids. Benzaldehyde, m-hydroxybenzaldehyde, p-hydroxybenzaldehyde, and protocatechualdehyde were catabolized further via the -ketoadipate and gentisate pathways. Dehydrodivanillin, isophthalaldehyde, salicylaldehyde, syringaldehyde, terephthalaldehyde, vanillin, and veratraldehyde were oxidized only as far as the corresponding aromatic acids. Phthalaldehyde and aliphatic aldehydes were not oxidized. The aromatic aldehyde oxidase, which was produced by cultures grown in either the presence or absence of aromatic aldehydes, was partially purified by ammonium sulfate precipitation and ion-exchange chromatography. It consumed molecular oxygen, oxidized aromatic aldehydes to aromatic acids, and produced hydrogen peroxide all in equimolar amounts.Paper no. 81515 of the Idaho Agricultural Experiment Station