Microbial hydroxylation of imidacloprid for the synthesis of highly insecticidal olefin imidacloprid

Microorganisms that bring about the aerobic transformation of imidacloprid (IMI) were isolated and screened, and the microbial regio- and stereoselective hydroxylation of IMI was studied. Some bacteria and fungi transformed IMI to 5-hydroxyl IMI. Bacterium Stenotrophomonas maltophilia CGMCC 1.1788 resting cells transformed IMI into R-5-hydroxyl IMI at the highest conversion rate. The enzyme catalyzed the stereoselective hydroxylation at position C12 of IMI in the imidazolidine ring. Under acidic conditions, 5-hydroxyl IMI was converted into olefin IMI in high molar conversion yield. The olefin IMI exhibited about 19 and 2.2 times more insecticidal efficacy than IMI against horsebean aphid imago and nymph, respectively, and about 1.4 times more active than IMI against brown planthopper imago. The transformation rate of IMI by resting cells of S. maltophilia CGMCC 1.1788 was promoted significantly by some carbohydrates and organic acids. The reaction medium with 5% sucrose resulted in 8.3 times greater biotransformation yield as compared with that without sucrose.     

Hydroxylation of thiacloprid by bacterium Stenotrophomonas maltophilia CGMCC1.1788

Chloropyridinyl neonicotinoid insecticides play a major role in crop protection and flea control on cats and dogs. Imidacloprid, thiacloprid and acetamiprid have in common the 6-chloro-3-pyridinylmethyl group but differ in the nitroguanidine or cyanoamidine substituent on an acyclic or cyclic moiety. Our previous study found that Stenotrophomonas maltophilia CGMCC 1.1788 could hydroxylate imidacloprid to 5-hydroxy imidacloprid, and 5-hydroxy imidacloprid was easily converted to 10–19 times higher insecticidal olefin imidacloprid against aphid or whitefly. Acetamiprid could be transformed by S. maltophilia to form N-demethylation product(IM 2-1). In this paper, we examined S. maltophilia CGMCC 1.1788’s ability of transformation of thiacloprid. S. maltophilia CGMCC 1.1788 can hydroxylate thiacloprid to 4-hydroxy thiacloprid characterized by HPLC-MS/MS and NMR analysis, however 4-hydroxy thiacloprid could not be converted to olefin thiacloprid under acid conditions like imidacloprid, whereas oxidized and decyonated simultaneously to form 4-ketone thiacloprid imine in alkaline solution. Bioassays indicated that 4-hydroxy thiacloprid had 156 times lower insecticidal activity than thiacloprid, and the ketone-imine derivative almost had no toxicity towards aphid. Though both imidacloprid and thiacloprid are hydroxylated by S. maltophilia CGMCC 1.1788 at the same carbon atom position, however the structural difference between in imidacloprid and thiacloprid, originate the entire discrepancy in bioefficacy of metabolite and its further degrading pathway. These results explain that why thiacloprid is classified as not relevant grade for soil and seed applications, whereas imidacloprid is recommended and acetamiprid is limited.     

N-demethylation of neonicotinoid insecticide acetamiprid by bacterium <Emphasis Type="Italic">Stenotrophomonas </Emphasis><Emphasis Type="Italic">maltophilia</Emphasis> CGMCC 1.1788

Our previous study found that Stenotrophomonas maltophilia CGMCC 1.1788 could hydroxylate imidacloprid (IMI) to 5-hydroxy IMI. Here we first report that S. maltophilia CGMCC 1.1788 can demethylate acetamiprid (AAP) to form IM 2-1 that was characterized by HPLC-MS/MS and NMR. IM 2-1 retained only 10.5% contact activity and 13.1% oral activity of AAP against horsebean aphid. Time course of biotransformation under existing of sucrose revealed that 58.9% of AAP disappeared, but only 16.7% of reduced AAP was transformed to IM 2-1, after 8 days. Both demethylation and degradation of AAP contribute to the weak bioefficacy of AAP in soil application. The differences in metabolism and detoxification pathways between AAP and IMI are probably originated from the structural differences of these insecticides.     

Different utilizable substrates have different effects on cometabolic fate of imidacloprid in Stenotrophomonas maltophilia

Imidacloprid, the largest selling insecticide in the world, is more stable in soil, and its environmental residue and effects are attracting people's close attention. One of imidacloprid metabolism pathways was degraded to CO₂ through olefin imidacloprid pathway. Here, we report that sucrose as a utilizable substrate enhanced the cometabolism of imidacloprid by Stenotrophomonas maltophilia CGMCC 1.1788 to produce 5-hydroxy imidacloprid, whereas when succinate was used as a utilizable substrate, 5-hydroxy imidacloprid from imidacloprid was transformed to olefin imidacloprid, and the latter was further degraded. The hydroxylation of imidacloprid required NAD(P)H, whereas the dehydration of 5-hydroxy imidacloprid to form olefin imidacloprid required succinate rather than NAD(P)H. NADPH greatly favored the hydroxylation of imidacloprid more than NADH, and NADPH inhibited the dehydration of 5-hydroxy imidacloprid to olefin imidacloprid, but NADH did not. Therefore, sucrose may be metabolized through hexose monophosphate pathway to produce mainly NADPH which participated in the hydroxylation of imidacloprid to 5-hydroxy imidacloprid and meanwhile inhibited the dehydration of 5-hydroxy imidacloprid to olefin imidacloprid, whereas succinate may be metabolized mainly through the tricarboxylic acid cycle to produce NADH which was involved in hydroxylation of imidacloprid to 5-hydroxy imidacloprid but did not inhibit the dehydration of 5-hydroxy imidacloprid to olefin imidacloprid. Our results have a significant meaning in further understanding the influence of different utilizable substrates on the cometabolic pathways and the fate of environmental imidacloprid.     

A Combined Hydroxylation of 3‐Cyanopyridine to 3‐Cyano‐6‐hydroxypyridine and 6‐Hydroxynicotinic Acid by Resting Cells of Comamonas testosteroni JA1 Grown on Nicotinic Acid

A strain of Comamonas testosteroni JA1 known for its capacity to hydroxylate 3‐cyanopyridine to 3‐cyano‐6‐hydroxypyridine was found to be also capable to hydroxylate nicotinic acid at a higher rate. In the course of the induced cultivation the forming 6‐hydroxynicotinic acid was degraded either slightly, in the presence of nicotinic acid in the medium, or faster, in the absence of nicotinic acid. In a combined process of hydroxylation of nicotinic acid by growing culture and hydroxylation of 3‐cyanopyridine by resting cells of Comamonas testosteroni JA1, not only an additional amount of 50.38 g of solid 6‐hydroxynicotinic acid was produced from 1 L of cultivation broth with a 99.97 % molar conversion yield, but also the yield of 3‐cyano‐6‐hydroxypyridine produced was more than doubled. This can be compared to that of the resting cells from the induced cultivation broth where within 8 h an amount of 5.77 g of solid 3‐cyano‐6‐hydroxypyridine was produced by resting cells from 1 L of the cultivation broth. This also was superior to 4.39 g/L of cultivation broth of resting cells reported in the literature.     

恶臭假单胞菌NA-1菌体培养转化和静息细胞转化联合工艺生产6-羟基烟酸研究

现有微生物羟基化烟酸采用的是静息细胞转化工艺。但研究揭示,恶臭假单胞菌NA-1(Pseudomonas putidaNA-1)在培养过程中不降解发酵液中由诱导剂烟酸转化形成的6-羟基烟酸,这是由于烟酸的存在抑制了羟基烟酸降解酶的作用,而不是因为细胞停止生长不利用羟基烟酸的缘故。因而尝试利用菌体诱导培养过程进行烟酸转化生产,建立了一种新的生产工艺,即菌体培养转化和静息细胞转化联合工艺。该工艺在恶臭假单胞菌NA-1培养过程中持续补充烟酸以维持1%(W/V)浓度,使烟酸被生长细胞转化为羟基化烟酸并在发酵液中线性积累,而不被进一步降解;培养转化结束后,发酵液中的静息细胞依然拥有很高的羟基化酶活力,能够再次用于转化反应。该联合转化工艺与传统的静息细胞转化工艺相比,不仅节约了诱导剂烟酸,而且6-羟基烟酸的产量提高了65%。     

Advances in the bioconversion mechanism of lovastatin to wuxistatin by Amycolatopsis sp. CGMCC 1149

Wuxistatin, a novel statin and more potent than lovastatin, was converted from lovastatin by Amycolatopsis sp. (CGMCC 1149). Product I, an intermediate product, was found in the fermentation broth, and the structure analysis showed that product I had an additional hydroxyl group at the methyl group attached to C3 compared to lovastatin, which indicates that product I is one isomer of wuxistatin. Isotope tracing experiment proved that hydroxyl group of wuxistatin was provided by product I and the reaction from product I to wuxistatin was an intramolecular transfer. Hydroxylation reaction established in a cell-free system could be inhibited by CO and enhanced by ATP, Fe²⁺, and ascorbic acid, which were consistent with the presumption that the hydroxylase was an induced cytochrome P450. Study on proteomics of Amycolatopsis sp. CGMCC 1149 suggested that three identified proteins, including integral membrane protein, Fe-S oxidoreductase, and GTP-binding protein YchF, were induced by lovastatin and required during hydroxylation reaction. In conclusion, bioconversion mechanism of wuxistatin by Amycolatopsis sp. CGMCC 1149 was proposed: lovastatin is firstly hydroxylated to product I by a hydroxylase, namely cytochrome P450, and then product I is rearranged to wuxistatin by isomerases.     

Induction of P450 genes in Nilaparvata lugens and Sogatella furcifera by two neonicotinoid insecticides

Nilaparvata lugens and Sogatella furcifera are two primary planthoppers on rice throughout Asian countries and areas. Neonicotinoid insecticides, such as imidacloprid (IMI), have been extensively used to control rice planthoppers and IMI resistance consequently occurred with an important mechanism from the over‐expression of P450 genes. The induction of P450 genes by IMI may increase the ability to metabolize this insecticide in planthoppers and increase the resistance risk. In this study, the induction of P450 genes was compared in S. furcifera treated with IMI and nitromethyleneimidazole (NMI), in two planthopper species by IMI lethal dose that kills 85% of the population (LD₈₅), and in N. lugens among three IMI doses (LD₁₅, LD₅₀ and LD₈₅). When IMI and NMI at the LD₈₅ dose were applied to S. furcifera, the expression changes in most P450 genes were similar, including the up‐regulation of nine genes and down‐regulation of three genes. In terms of the expression changes in 12 homologous P450 genes between N. lugens and S. furcifera treated with IMI at the LD₈₅ dose, 10 genes had very similar patterns, such as up‐regulation in seven genes, down‐regulation in one gene and no significant changes in two genes. When three different IMI doses were applied to N. lugens, the changes in P450 gene expression were much different, such as up‐regulation in four genes at all doses and dose‐dependent regulation of the other nine genes. For example, CYP6AY1 could be induced by all IMI doses, while CYP6ER1 was only up‐regulated by the LD₅₀ dose, although both genes were reported important in IMI resistance. In conclusion, P450 genes in two planthopper species showed similar regulation patterns in responding to IMI, and the two neonicotinoid insecticides had similar effects on P450 gene expression, although the regulation was often dose‐dependent.     

Reductive degradation of pyrazine-2-carboxylate by a newly isolated <Emphasis Type="Italic">Stenotrophomonas</Emphasis> sp. HCU1

A bacterium growing on pyrazine-2-carboxylate broth was isolated, purified and identified as a strain of Stenotrophomonas sp. based on polyphasic taxonomic analyses and designated as strain HCU1. 16S rRNA gene sequence of strain HCU1 showed 98.7% sequence similarity with the type strain of Stenotrophomonas maltophilia belonging to Gammaproteobacteria. Growth of strain HCU1 was demonstrated when pyrazine-2-carboxylate was used as a sole source of nitrogen. Ring reduction of pyrazine-2-carboxylate was shown as increase in absorbance at 268 nm and the reduced product was confirmed as 1,2,5,6-tetrahydropyrazine-2-carboxylate, while a ring opened product, 2-amino-2-hydroxy-3-(methylamino) propanoic acid (with a loss in carbon atom), indicated a reductive degradation of pyrazine-2-carboxylate by strain HCU1.     

Production of water-soluble yellow pigments via high glucose stress fermentation of Monascus ruber CGMCC 10910

Monascus pigments are secondary metabolites of Monascus species and are mainly composed of yellow pigments, orange pigments and red pigments. In this study, a larger proportion of Monascus yellow pigments could be obtained through the selection of the carbon source. Hydrophilic yellow pigments can be largely produced extracellularly by Monascus ruber CGMCC 10910 under conditions of high glucose fermentation with low oxidoreduction potential (ORP). However, keeping high glucose levels later in the culture causes translation or a reduction of yellow pigment. We presume that the mechanism behind this phenomenon may be attributed to the redox level of the culture broth and the high glucose stress reaction of M. ruber CGMCC 10910 during high glucose fermentation. These yellow pigments were produced via high glucose bio-fermentation without citrinin. Therefore, these pigments can act as natural pigments for applications as food additives.

     

Degradation of 4-nitrophenol by the lignin-degrading basidiomycete <Emphasis Type="Italic">Phanerochaete chrysosporium</Emphasis>

The fungal metabolism of 4-nitrophenol (4-NP) was investigated using the lignin-degrading basidiomycete, Phanerochaete chrysosporium. Despite its phenolic feature, 4-NP was not oxidized by extracellular ligninolytic peroxidases. However, 4-NP was converted to 1,2-dimethoxy-4-nitrobenzene via intermediate formation of 4-nitroanisole by the fungus only under ligninolytic conditions. The metabolism proceeded via hydroxylation of the aromatic ring and methylation of phenolic hydroxyl groups. Although the involvement of nitroreductase in the metabolism of 2,4-dinitrotoluene by many aerobic and anaerobic microorganisms including P. chrysosporium has been reported, no formation of 4-aminophenol was observed during 4-NP metabolism. The formation of 1,2-dimethoxy-4-nitrobenzene was effectively inhibited by exogenously added piperonyl butoxide, a cytochrome P450 inhibitor, suggesting that cytochrome P450 is involved in the hydroxylation reaction. Thus, P. chrysosporium seems to utilize hydroxylation and methylation reactions to produce a more susceptible structure for an oxidative metabolic system.     

Engineering of recombinant E. coli cells co‐expressing P450pyrTM monooxygenase and glucose dehydrogenase for highly regio‐ and stereoselective hydroxylation of alicycles with cofactor recycling

E. coli (P450pyrTM‐GDH) with dual plasmids, pETDuet containing P450pyr triple mutant I83H/M305Q/A77S (P450pyrTM) and ferredoxin reductase (FdR) genes and pRSFDuet containing glucose dehydrogenase (GDH) and ferredoxin (Fdx) genes, was engineered to show a high activity (12.7 U g^?1 cdw) for the biohydroxylation of N‐benzylpyrrolidine 1 and a GDH activity of 106 U g^?1 protein. The E. coli cells were used as efficient biocatalysts for highly regio‐ and stereoselective hydroxylation of alicyclic substrates at non‐activated carbon atom with enhanced productivity via intracellular recycling of NAD(P)H. Hydroxylation of N‐benzylpyrrolidine 1 with resting cells in the presence of glucose showed excellent regio‐ and stereoselectivity, giving (S)‐N‐benzyl‐3‐hydroxypyrrolidine 2 in 98% ee as the sole product in 9.8 mM. The productivity is much higher than that of the same biohydroxylation using E. coli (P450pyrTM)b without expressing GDH. E. coli (P450pyrTM‐GDH) was found to be highly regio‐ and stereoselective for the hydroxylation of N‐benzylpyrrolidin‐2‐one 3 , improving the regioselectivity from 90% of the wild‐type P450pyr to 100% and giving (S)‐N‐benzyl‐4‐hydroxylpyrrolidin‐2‐one 4 in 99% ee as the sole product. A high activity of 15.5 U g^?1 cdw was achieved and (S)‐ 4 was obtained in 19.4 mM. E. coli (P450pyrTM‐GDH) was also found to be highly regio‐ and stereoselective for the hydroxylation of N‐benzylpiperidin‐2‐one 5 , increasing the ee of the product (S)‐N‐benzyl‐4‐hydroxy‐piperidin‐2‐one 6 to 94% from 33% of the wild‐type P450pyr. A high activity of 15.8 U g^?1 cdw was obtained and (S)‐ 6 was produced in 3.3 mM as the sole product. E. coli (P450pyrTM‐GDH) represents the most productive system known thus far for P450‐catalyzed hydroxylations with cofactor recycling, and the hydroxylations with E. coli (P450pyrTM‐GDH) provide with simple and useful syntheses of (S)‐ 2 , (S)‐ 4 , and (S)‐ 6 that are valuable pharmaceutical intermediates and difficult to prepare. Biotechnol. Bioeng. 2013; 110: 363–373. © 2012 Wiley Periodicals, Inc.     

Transformation of Acetobacter polyoxogenes with Plasmid DNA by Electroporation

Acetobacter polyoxogenes was transformed with plasmid DNA by electroporation. The following points were essential for transformation: (i) dilution of the culture broth with cold water and air bubbling of the culture broth for transformation at discharging from a jar fermentor, and (ii) selection of transformants by liquid cultivation. For shortening of the lag time in cultivation for selection of transformants, the following treatments were useful: (i) addition of sucrose to the cell suspension during transformation and to the broth for cultivation, and (ii) addition of 1 mm MgCl₂ to a mixture of cells and DNA during electroporation.     

Microbial Transformation of 14‐Anhydrodigoxigenin by Alternaria alternata

The microbial transformation of 14‐anhydrodigoxigenin ( 1 ) by Alternaria alternata CGMCC 3.577 led to the production of seven new metabolites, 2 – 8 . Their structures were determined by extensive spectroscopic (CD, IR, 1D‐ and 2D‐NMR, and HR‐ESI‐MS) data analyses. The reactions in the bioprocess exhibited diversity, including specific oxidation, hydroxylation, reduction, epoxidation, and dehydration. In addition, a hypothetical biocatalytic pathway is proposed.     

Novel metabolic pathway for salicylate biodegradation via phenol in yeast <Emphasis Type="Italic">Trichosporon moniliiforme</Emphasis>

A novel metabolic pathway was found in the yeast Trichosporon moniliiforme WU-0401 for salicylate degradation via phenol as the key intermediate. When 20 mM salicylate was used as the sole carbon source for the growth of strain WU-0401, phenol was detected as a distinct metabolite in the culture broth. Analysis of the products derived from salicylate or phenol through reactions with resting cells and a cell-free extract of strain WU-0401 indicated that salicylate is initially decarboxylated to phenol and then oxidized to catechol, followed by aromatic ring cleavage to form cis-cis muconate.     

Identification and characterization of <Emphasis Type="Italic">gerPI</Emphasis> and <Emphasis Type="Italic">gerPII</Emphasis> involved in epoxidation and hydroxylation of dihydrochalcolactone in <Emphasis Type="Italic">Streptomyces</Emphasis> species KCTC 0041BP

The macrolide antibiotics are biosynthesized by initial assembly of a macrolactone ring, followed by a series of post-polyketide (PKS) modifications. In general, the additional hydroxyl or epoxy groups are installed by cytochrome P450 enzymes, improving the bioactivity profile through structural diversification of natural products. The biosynthetic gene cluster for the 16-membered macrolide antibiotic dihydrochalcomycin (DHC) has been cloned from Streptomyces sp. KCTC 0041BP. Three cytochrome P450 genes are found in the DHC biosynthetic gene (ger) cluster. Two P450 enzymes were characterized from this cluster. Disruption of gerPI accumulated predominantly 12,13-de-epoxydihydrochalcomycin while disruption of gerPII accumulated 8-dehydroxy-12,13-de-epoxydihydrochalcomycin; DHC production was abolished in both cases. The results suggest that GerPII P450 catalyzes hydroxylation at the C₈ position followed by an epoxidation reaction catalyzed by GerPI P450 at the C₁₂–C₁₃ position.     

Induction and functional role of cytochromes P450 in the filamentous fungi Mortierella alpina ATCC 8979 and Cunninghamella blakesleeana DSM 1906 during hydroxylation of cycloalkylbenzoxazoles

The occurrence and regulation of cytochrome P450 (P450) in Mortierella alpina and Cunninghamella blakesleeana have been studied to elucidate the enzymatic basis by which 2-cyclopentyl-1,3-benzoxazole is hydroxylated to 3-(benz-1,3-oxazol-2-yl)cyclopentan-1-ol by these organisms. The occurrence of P450 in M. alpina was first been shown after induction with n-hexane. An assay protocol was developed with n-hexane-induced cells and adapted to the handling of fungal mycelia. This allowed the direct spectral determination of P450 in non-fractionated whole-cell suspensions, and an investigation of its regulation. Small amounts of P450 have been detected in early-stationary-phase cells in the absence of exogenous inducers. Addition of 2-cyclopentyl-1,3-benzoxazole or n-hexane resulted in a significant induction of P450. Induction by n-hexane occurs in all phases of growth but decreases rapidly during the stationary phase. The rate of 2-cyclopentyl-1,3-benzoxazole hydroxylation correlated with the content of substrate-induced P450 but not with the level of n-hexane-induced P450. Hydroxylation rates were significantly diminished in the presence of typical P450 inhibitors, the interaction of which with P450 was shown with isolated microsomes of M. alpina. It is concluded that a P450 enzyme is responsible for the hydroxylation of 2-cyclopentyl-1,3-benzoxazole, but that multiple forms of P450 forms occur. Similarly, a dependence on P450 is shown by spectral as well as by inhibition studies for the hydroxylation of this substrate by C. blakesleeana. Received: 18 August 1998 / Received revision: 23 November 1998 / Accepted: 29 November 1998     

Effects of some carbon and nitrogen sources on spore germination,production of biomass and antifungal metabolites by species of Trichoderma and Gliocladium virens antagonistic to Sclerotium cepivorum

Conidia of Trichoderma pseudokoningii (IMI 322662) and T. viride (IMI 322659) were incubated in 1% bacteriological peptone at 25° C for 20 h and more than 95% of the spores germinated. In the same medium, only 35% of the conidia of Gliocladium virens (G20) and T. viride (IMI 322663) germinated but when 1% glucose was added, germination was increased to 70%. In the presence of glucose as a carbon source, maximal biomass production of G. virens (G20) after seven days at 25°C was obtained with either potassium nitrate or L‐alanine as the nitrogen source, whereas the Trichoderma isolates needed an organic nitrogen source. With L‐alanine as a nitrogen source, glucose, galactose and sucrose were readily utilized for biomass production by all fungal isolates. Maltose utilization by G. virens (G20) and T. pseudokoningii was incomplete after 21 days incubation, whereas glucose utilization was complete by this time. G. virens, T. pseudokoningii and T. viride (IMI 322663) produced antifungal metabolites which were effective at reducing radial growth of Rhizoctonia solani, Botrytis cinerea as well as S. cepivorum. The metabolites produced by G. virens were very active against all three pathogens but the metabolites produced by T. pseudokoningii and T. viride (IMI 322663) were less active. T. viride (IMI 322659) was a very poor antifungal metabolite producer.     

Effect of Tween 80 on 9α-steroid hydroxylating activity and ultrastructural characteristics of <Emphasis Type="Italic">Rhodococcus</Emphasis> sp. cells

Studied is the effect of the non-ionic surfactant Tween 80 on the microbial transformation of 4-androstene-3,17-dione into its 9α-hydroxy-derivative by resting Rhodococcus sp. cells. The surfactant was applied in the cultivation medium as an additional source of carbon, in the transformation reaction medium as a mediator of the steroid substrate solubility or was used for permeabilization of the glucose grown Rhodococcus sp. cells. Special attention is paid to the fact that Tween 80 accelerates the 9α-steroid hydroxylation reaction carried out by glucose-grown cells. When the surfactant was applied as a supplementary source of carbon, the rate of the steroid hydroxylation reaction was significantly lower. In addition, the kinetics of the transformation process changed into a linear one thus indicating a very slow, if any, product degradation. The fatty acid profile, cell surface hydrophobicity as well as cell ultrastructure observed by scanning and transmission electron microscopy in the Tween 80- and glucose-grown Rhodococcus sp. cells are compared and related with their 9α-hydroxylating activity.     

An efficient way from naringenin to carthamidine and isocarthamidine by <Emphasis Type="Italic">Aspergillus niger</Emphasis>

Biotransformation of naringenin with Aspergillus niger CGMCC 3.4628 yielded two hydroxylation products which were identified unambiguously as 6-hydroxylnaringenin (carthamidin) and 8-hydroxylnaringenin (isocarthamidin) by ESI–MS and ¹H-NMR. Both products simultaneously arrived at high level after 48 h in the biotransformation process. The highest conversion efficiency of carthamidin was 0.38 mg/mg of naringenin and that of isocarthamidin was 0.43 mg/mg of naringenin. Antioxidant property assay using a thin layer chromatography-bioautographic-based DPPH scavenging method demonstrated that both hydroxylation metabolites exhibited much stronger activity than naringenin. The high efficiency and convenient procedure makes the biotransformation with A. niger described in current work a potential way to produce carthamidin and isocarthamidin.