Biotransformation of pseudolaric acid B by Chaetomium globosum

Pseudolaric acid B (1) is a natural product with potent antifungal activity. We discovered that pseudolaric acid B did not kill but only suppress the growth of the filamentous fungus Chaetomium globosum. It was proposed that pseudolaric acid B was converted to metabolites with decreased antifungal activities. In this study, a scaled-up biotransformation of pseudolaric acid B by C. globosum produced five metabolites, including three new compounds, pseudolaric acid I (2), pseudolaric acid B 18-oyl-alanine (4) and pseudolaric acid B 18-oyl-serine (6), together with two known compounds, pseudolaric acid F (3) and pseudolaric acid B 18-oyl-glycine (5). The structures were characterized by NMR and MS spectroscopy. The major biotransformation reaction was conjugation with amino acids. None of the metabolites showed inhibitory effects on the growth of Candida albicans. The results suggested that biotransformation might be a detoxification process for fungi to resist antifungal drugs.     

Screening and evaluation of fungal resources for loratadine metabolites

Loratadine is a selective inverse agonist of peripheral histamine H1-receptors. Microbial biotransformation gained a lot of attention for its ability to convert molecules to valuable medicinally active substances. The main objective of the present research was to investigate the ability of different fungi to biotransform the drug loratadine to its active metabolite desloratadine, because desloratadine is four times more potent, possess longer duration of action than loratadine and is effective at low doses. The screening studies were performed with selected fungi using their respective broth media and sterile incubation conditions. The drug and metabolites formed (if any) were extracted and analysed using HPLC analysis. Structural elucidation and confirmation of metabolites were by mass and proton NMR spectroscopy. Among the six fungi selected, Cunninghamella elegans, Cunninghamella echinulata and Aspergillus niger cultures showed extra peaks at 3.8, 3.6 and 4.1 min, respectively, in HPLC when compared with their controls, which indicated the formation of metabolites. The metabolites thus formed were isolated and their structures were confirmed as dihydroxy desloratadine, desethoxy loratadine and 3-hydroxy desloratadine by Cunninghamella elegans, Cunninghamella echinulata and Aspergillus niger cultures, respectively, by mass spectrometry and NMR spectroscopy. Three fungi were identified to have the ability to biotransform loratadine to its active metabolite and other different metabolites.     

Biotransformation of artemisinic acid by the fungus Trichothecium roseum and anti-candidal activity of its metabolites

The microbial transformation of artemisinic acid (1) using cell culture of endophytic fungus Trichothecium roseum was investigated. Previously, we have reported two major metabolites, 3β-hydroxyartemisinic acid (2) and 3β,15-dihydroxyartemisinic acid (3) from the biotransformation of artemisinic acid by the fungus T. roseum CIMAPN1. Here in the present paper, we obtained a new minor compound 4 (5.2% in yield) along with compounds 2 and 3 through scale-up of biotransformation process of artemisinic acid using the same fungus. The structure of compound 4 was established as 3-oxoartemisinic acid on the basis of its IR, ESI-MS, HRMS, 1?D (¹H and ¹³C, DEPT), and 2?D (COSY, HSQC, HMBC) NMR spectral data analysis. The possible reaction mechanism of the formation of 3-oxoartemisinic acid from artemisinic acid was proposed. Furthermore, all the three metabolites along with the artemisinic acid were evaluated for their antifungal activity against the three fungal strains Candida albicans (ATCC 14053), Candida albicans clinical isolates and Candida kefyr (ATCC 204093). 3-Oxoartemisinic acid was the most active (4 to 16 times more potent than artemisinic acid) with MIC ranges from 125 to 500?µg/mL among all tested compounds. This study suggested that the artemisinic acid molecule has a great potential to be exploited for further biotransformation by the different fungi and can produce chemically diverse molecules with better biological activity.     

嗜热毁丝霉高通量培养技术及其应用

【背景】丝状真菌是一类重要的工业发酵生产宿主菌,如何进行高通量纯菌培养和高效检测筛选性能优异的菌株是工业丝状真菌研究的重要方向。【目的】研究建立丝状真菌的高通量培养技术并测试应用效果。【方法】通过对丝状真菌培养过程中的制种、接种、培养和检测研究,建立基于孔板的高通量培养技术,并以嗜热毁丝霉为例对该技术进行验证。【结果】与传统的平板制种和摇瓶接种培养方式相比,高通量孔板的培养方式将制种通量提高24倍,单位面积产孢子能力提高350%,液体培养转接效率提高10-40倍,并建立96孔板测定乙醇含量的高通量检测技术。【结论】将丝状真菌的培养和检测通量提高1-2个数量级,为快速检测丝状真菌改造过程产生的大量性状不同菌株并获得目标菌株奠定基础,为丝状真菌高通量筛选研究提供应用指导价值。     

Major bioactive metabolites from marine fungi: A Review

Biologists and chemists of the world have been attracted towards marine natural products for the last five decades. Approximately 16,000 marine natural products have been isolated from marine organisms which have been reported in approximately 6,800 publications, proving marine microorganisms to be a invaluable source for the production of novel antibiotic, anti tumor, and anti inflammatory agents. The marine fungi particularly those associated with marine alga, sponge, invertebrates, and sediments appear to be a rich source for secondary metabolites, possessing Antibiotic, antiviral, antifungal and antiyeast activities. Besides, a few growth stimulant properties which may be useful in studies on wound healing, carcinogenic properties, and in the study of cancers are reported. Recent investigations on marine filamentous fungi looking for biologically active secondary metabolites indicate the tremendous potential of them as a source of new medicines. The present study reviews about some important bioactive metabolites reported from marine fungal strains which are anti bacterial, anti tumour and anti inflammatory in action. It highlights the chemistry and biological activity of the major bioactive alkaloids, polyketides, terpenoids, isoprenoid and non-isoprenoid compounds, quinones, isolated from marine fungi.     

Exhaustive extraction of cyclopeptides from Amanita phalloides: Guidelines for working with complex mixtures of secondary metabolites

1. Understanding plant‐insect interactions is an active area of research in both ecology and evolution. Much attention has been focused on the impact of secondary metabolites in the host plant or fungi on these interactions. Plants and fungi contain a variety of biologically active compounds, and the secondary metabolite profile can vary significantly between individual samples. However, many experiments characterize the biological effects of only a single secondary metabolite or a subset of these compounds.
2. Here, we develop an exhaustive extraction protocol using an accelerated solvent extraction protocol to recover the complete suite of cyclopeptides and other secondary metabolites found in Amanita phalloides (death cap mushrooms) and compare its efficacy to the “Classic” extraction method used in earlier works.
3. We demonstrate that our extraction protocol recovers the full suite of cyclopeptides and other secondary metabolites in A. phalloides unlike the “Classic” method that favors polar cyclopeptides.
4. Based on these findings, we provide recommendations for how to optimize protocols to ensure exhaustive extracts and also the best practices when using natural extracts in ecological experiments.

     

Synthesis of sterigmatocystin on a chemically defined medium by species ofAspergillus andChaetomium

Sterigmatocystin (ST) is a secondary metabolite and a principal mycotoxin known to be produced by over 30 species of filamentous fungi. It is also one of the late intermediates in aflatoxin biosynthesis. We have tested the ability of 7 species ofAspergillus, including 4 strains ofA. versicolor, one species ofBipolaris, and two species ofChaetomium, to produce ST on a sucrose-salts-phenylalanine defined medium as well as on three complex substrates. Highest ST production in our survey was by a strain ofA. versicolor grown on wheat, whereas, the highest ST production on defined medium was byC. cellulolyticum. To our knowledge, this is the first report of ST production byC. cellulolyticum on any substrate. In precursor feeding studies, resting cultures of wild typeA. nidulans andA. versicolor were unable to biotransform O-methylsterigmatocystin (OMST), the last known intermediate in aflatoxin biosynthesis. These results suggest that ST is the end product of polyketide metabolism in the strains tested.     

Biology and applications of Clonostachys rosea

Clonostachys rosea is a promising saprophytic filamentous fungus that belongs to phylum Ascomycota. Clonostachys rosea is widespread around the world and exists in many kinds of habitats, with the highest frequency in soil. As an excellent mycoparasite, C. rosea exhibits strong biological control ability against numerous fungal plant pathogens, nematodes and insects. These behaviours are based on the activation of multiple mechanisms such as secreted cell-wall-degrading enzymes, production of antifungal secondary metabolites and induction of plant defence systems. Besides having significant biocontrol activity, C. rosea also functions in the biodegradation of plastic waste, biotransformation of bioactive compounds, as a bioenergy sources and in fermentation. This mini review summarizes information about the biology and various applications of C. rosea and expands on its possible uses.     

Microbial metabolism of the \-adrenoreceptor antagonist bisoprolol

Eighteen filamentous fungi and six actinomycetes species were screened for their ability to metabolize bisoprolol, a \-blocking drug. All strains of Cunninghamella tested accumulated metabolite M4 = EMD 46193 ([4-(2-hydroxy-3-isopropylaminopropoxy)benzyloxy]ethanol). Among the strains investigated only Gliocladium deliquescens excreted the corresponding carbonic acid M1 = EMD 44025 into the culture medium. Biotransformation of bisoprolol by fungi occurred only during growth in complex medium or with resting cells after cultivation in complex medium. The screened Actinomycetes showed no biotransformation of the drug. Correspondence to: H. Schwartz     

Diversity of Physiological and Biochemical Characters of Microdochium Fungi

The biological characterization of Microdochium majus, M. nivale, and M. seminicola strains with wide geographical origins showed the diversity of their pathogenic properties and metabolite compounds, allowing them to exist in their habitats. Significant differences in the ability of Microdochium fungi to cause lesions on wheat and oat leaves were found. The intensity of symptoms depended on the species and substrate origin of the strains. On average M. seminicola strains were able to cause less leaf necrosis than M. majus and M. nivale. The volatile organic compound (VOC) profile of Microdochium fungi included 29 putative fungal metabolites. The spectrum of the identified VOCs in M. seminicola strains was much richer than that in M. majus and M. nivale strains. In addition, the strains of M. seminicola emitted at least six sesquiterpenes. Mycotoxin analysis by HPLC/MS/MS revealed that the analyzed Microdochium strains did not produce any toxic metabolites typically produced by filamentous fungi.     

Microbial transformation of curcumin by Rhizopus chinensis

Abstract

Curcumin (1) is a potent antioxidant and antitumor natural product. In spite of its efficacy and safety, its clinical use is hindered mainly by poor water solubility and bioavailability. Structural modification to introduce hydrophilic functions is a promising approach to resolve this problem. In the present study we first found that curcumin could be efficiently converted into glucosides by filamentous fungi including Rhizopus chinensis IFFI 03043, Absidia coerulea AS 3.3389 and Cunninghamella elegans AS 3.1207. Curcumin 4′-O-β-d-glucoside (2), together with hexahydrocurcumin (3), was isolated from a preparative-scale biotransformation with R. chinensis IFFI 03043 and characterized fully by NMR and MS. A time-course study revealed that curcumin could be efficiently converted into curcumin 4′-O-β-d-glucoside within 8 h when administered at 0.05 mmol L^?1 and the productivity was 57%. Additionally, the biotransformation products of curcumin by different fungal strains were analyzed by LC/MS. At least 15 metabolites were detected, and the predominant biotransformation reaction was glucosylation. This study provides a simple, efficient and less expensive approach for the preparation of curcumin glucosides. The introduction of the glucosyl function might be able to enhance the bioavailability of curcumin.     

Novel mechanisms of biotransformation of p-tert-amylphenol by bacteria and fungi with special degradation abilities and simultaneous detoxification of the disinfectant

The compound p-tert-amylphenol (p-(1,1-dimethylpropyl)phenol) is a widely used disinfectant belonging to the group of short branched-chain alkylphenols. It is produced in or imported into the USA with more than one million pounds per year and can be found in the environment in surface water, sediments, and soil. We have investigated for the first time the biotransformation of this disinfectant and the accumulation of metabolites by five bacterial strains, three yeast strains, and three filamentous fungi, selected because of their ability to transform either aromatic or branched-chain compounds. Of the 11 microorganisms tested, one yeast strain and three bacteria could not transform the disinfectant despite of a very low concentration applied (0.005 %). None of the other seven organisms was able to degrade the short branched alkyl chain of p-tert-amylphenol. However, two yeast strains, two filamentous fungi, and two bacterial strains attacked the aromatic ring system of the disinfectant via the hydroxylated intermediate 4-(1,1-dimethyl-propyl)-benzene-1,2-diol resulting in two hitherto unknown ring fission products with pyran and furan structures, 4-(1,1-dimethyl-propyl)-6-oxo-6-H-pyran-2-carboxylic acid and 2-[3-(1,1-dimethyl-propyl)-5-oxo-2H-furan-2-yl]acetic acid. While the disinfectant was toxic to the organisms applied, one of the ring cleavage products was not. Thus, a detoxification of the disinfectant was achieved by ring cleavage. Furthermore, one filamentous fungus formed sugar conjugates with p-tert-amylphenol as another mechanism of detoxification of toxic environmental pollutants. With this work, we can also contribute to the allocation of unknown chemical compounds within environmental samples to their parent compounds.     

曲霉属真菌活性代谢产物及在农业生产中的应用研究进展

曲霉属(Aspergillus)真菌是一类分布广泛的丝状真菌,种类繁多,代谢产物丰富,应用广泛,在农业、医药、生物能源、化妆品、食品发酵等行业均有应用。对近年来曲霉属真菌活性代谢产物在抗菌、抗氧化、抗病毒方面的研究进展进行了综述。结合实验室研究成果,对近年来曲霉属真菌代谢产物在秸秆腐熟菌剂、溶磷生物菌剂、拮抗植物寄生线虫等农业生产领域中的应用进行综述,以期为开发应用曲霉属真菌活性代谢产物的研究提供参考。     

链霉菌形态分化与次级代谢产物合成的研究进展

链霉菌是一类具有复杂的形态分化周期和强大的次级代谢能力的高GC含量的放线菌,能够利用其初级代谢产生的前体化合物和能量,合成多种结构复杂、功能多样的具有生物活性的次级代谢产物,在农业、食品、畜牧业、工业以及医药研究等领域都具有重要的价值。在链霉菌的形态分化后期常常伴随着次级代谢产物的生物合成,并且两者都受到复杂的网络调控;同时链霉菌的形态对次级代谢产物的产量和种类造成很大影响。对链霉菌生长周期的全面理解将加深对链霉菌形态分化与次级代谢产物合成关系的认识。本文将对链霉菌的形态分化过程、形态分化和抗生素合成两者共同的调控因子以及链霉菌形态与抗生素产量之间的关系进行综述,这将有助于理解抗生素的合成过程,也将会在缩短发酵周期、构建高产工程菌株、新型杀菌剂的研发以及新型抗生素的合成等方面给予我们启发。     

Functional and biotechnological insights into diglycosidases*

Abstract

β-Glucosidases are reported to act in an exo manner and so are unable to hydrolyze the bond if another sugar is attached to a non-reducing terminus of glucose. However, endo-β-glucosidases recognizing the heterosidic linkage have been known to plant physiologists for eight decades, although they have been described in detail only recently. Because of the ability of these enzymes to split off a disaccharide they were named disaccharide-specific glycosidases or ‘diglycosidases’. In contrast to the sequential mechanism of two monoglycosidases, the transformation of some secondary metabolites in one step was reported as responsible for the production of toxic compounds involved in plant defense mechanisms against herbivores, such as hydrogen cyanide. The current focus of interest is on the application of their unique substrate specificity for biotransformation of plant-based foods. Four activities have been described and characterized so far, recognizing the following disaccharidic sugar moieties: primeverose, acuminose, rutinose and vicianose. Moreover, three of these proteins have been fully sequenced and mutants of one of them constructed by site-directed mutagenesis, in order to elaborate the molecular basis of substrate recognition. The present paper reviews the role of these enzymes in plant and filamentous fungi, as well as their prospects for technological applications.     

Fruit,flies and filamentous fungi – experimental analysis of animal–microbe competition using Drosophila melanogaster and Aspergillus mould as a model system

In addition to their fundamental role in nutrient recycling, saprobiotic microorganisms may be considered as typical consumers of food‐limited ephemeral resource patches. As such, they may be engaged in inter‐specific competition with saprophagous animals feeding from the same resource. Bacteria and filamentous fungi are known to synthesise secondary metabolites, some of which are toxic and have been proposed to deter or harm animals. The microorganisms may, however, also be negatively affected if saprophagous animals do not avoid microbe‐laden resources but feed in the presence of microbial competitors. We hypothesised that filamentous fungi compete with saprophagous insects, whereby secondary metabolites provide a chemical shield against the insect competitors. For testing this, we developed a new ecological model system representing a case of animal–microbe competition between saprobiotic organisms, comprising Drosophila melanogaster and species of the fungus Aspergillus (A. nidulans, A. fumigatus, A. flavus). Infestation of Drosophila breeding substrate with proliferating fungal colonies caused graduated larval mortality that strongly depended on mould species and colony age. Confrontation with conidiospores only, did not result in significant changes in larval survival, suggesting that insect death may not be ascribed to pathogenic effects. When confronted with colonies of transgenic fungi that lack the ability to express the global secondary metabolite regulator LaeA (ΔlaeA), larval mortality was significantly reduced compared to the impact of the wild type strains. Yet, also in the ΔlaeA strains, inter‐specific variation in the influence on insect growth occurred. Competition with Drosophila larvae impaired fungal growth, however, wild type colonies of A. nidulans and A. flavus recovered more rapidly from insect competition than the corresponding ΔlaeA mutants (not in A. fumigatus). Our findings provide genetic evidence that toxic secondary metabolites synthesised by saprotrophic fungi may serve as a means to combat insect competitors. Variation in the ability of LaeA to control expression of various secondary metabolite gene clusters might explain the observed species‐specific variation in Drosophila–Aspergillus competition.     

The use of secondary metabolite profiling in chemotaxonomy of filamentous fungi

A secondary metabolite is a chemical compound produced by a limited number of fungal species in a genus, an order, or even phylum. A profile of secondary metabolites consists of all the different compounds a fungus can produce on a given substratum and includes toxins, antibiotics and other outward-directed compounds. Chemotaxonomy is traditionally restricted to comprise fatty acids, proteins, carbohydrates, or secondary metabolites, but has sometimes been defined so broadly that it also includes DNA sequences. It is not yet possible to use secondary metabolites in phylogeny, because of the inconsistent distribution throughout the fungal kingdom. However, this is the very quality that makes secondary metabolites so useful in classification and identification. Four groups of organisms are particularly good producers of secondary metabolites: plants, fungi, lichen fungi, and actinomycetes, whereas yeasts, protozoa, and animals are less efficient producers. Therefore, secondary metabolites have mostly been used in plant and fungal taxonomy, whereas chemotaxonomy has been neglected in bacteriology. Lichen chemotaxonomy has been based on few biosynthetic families (chemosyndromes), whereas filamentous fungi have been analysed for a wide array of terpenes, polyketides, non-ribosomal peptides, and combinations of these. Fungal chemotaxonomy based on secondary metabolites has been used successfully in large ascomycete genera such as Alternaria, Aspergillus, Fusarium, Hypoxylon, Penicillium, Stachybotrys, Xylaria and in few basidiomycete genera, but not in Zygomycota and Chytridiomycota.     

Debaryomyces hansenii as a new biocatalyst in the asymmetric reduction of substituted acetophenones

Chiral secondary alcohols are convenient mediator for the synthesis of biologically active compounds and natural products. In this study fifteen yeast strains belonging to three food originated yeast species Debaryomyces hansenii, Saccharomyces cerevisiae and Hanseniaspora guilliermondii were tested for their capability for the asymmetric reduction of acetophenone to 1-phenylethanol as biocatalyst microorganisms. Of these strains, Debaryomyces hansenii P1 strain showed an effective asymmetric reduction ability. Under optimized conditions, substituted acetophenones were converted to the corresponding optically active secondary alcohols in up to 99% enantiomeric excess and at high conversion rates. This is the first report on the enantioselective reduction of acetophenone by D. hansenii P1 from past?rma, a fermented Turkish meat product. The preparative scale asymmetric bio reduction of 3-methoxy acetophenone 1g by D. hansenii P1 gave (R)-1-(3-methoxyphenyl) ethanol 2g 82% yield, and >99% enantiomeric excess. Compound 2g can be used for the synthesis of (+)-NPS-R-568 [3-(2-chlorophenyl)-N-[(1R)-1-(3-methoxyphenly) ethyl] propan-1-amine] which have a great potential for the treatment of primary and secondary hyper-parathyroidism. In addition, D. hansenii P1 successfully reduced acetophenone derivatives. This study showed that this yeast can be used industrially to produce enantiomerically pure chiral secondary alcohols, which can be easily converted to different functional groups.     

新疆野果林苹果腐烂病病原菌鉴定及药用植物内生细菌对其抑菌效果

【背景】药用植物内生细菌能产生与寄主植物相同或相似的化合物及一些新的次级代谢产物等,具有促进宿主植物生长、抵抗病虫害、降解有毒有害化合物等作用。【目的】进一步提高苹果腐烂病生物防治的效率,丰富新疆药用植物内生细菌拮抗功能菌株的资源库。【方法】从新疆伊犁新源县和塔城额敏县野果林中采集带腐烂病病斑的果树枝条,分离鉴定苹果腐烂病病原菌,并采用平板对峙法从药用植物内生细菌中筛选对苹果腐烂病具有抑制作用的拮抗菌株。【结果】从两地共分离获得234株分离株,筛选鉴定出25株Valsa malicola和2株Valsa mali;同时,筛选出92株具有抑菌效果的内生细菌菌株,其中70株来自甘草植物内生细菌。【结论】药用植物甘草中富含较为丰富的抗苹果腐烂病病原菌的微生物菌株资源。本研究在新疆野果林苹果腐烂病的生物防治及药用植物内生细菌的开发利用等方面具有重要意义。     

Initial oxidative and subsequent conjugative metabolites produced during the metabolism of phenanthrene by fungi

Three filamentous fungi were examined for the ability to biotransform phenanthrene to oxidative (phase I) and conjugative (phase II) metabolites. Phenanthrene metabolites were purified by high-performance liquid chromatography (HPLC) and identified by UV/visible absorption, mass, and¹H NMR spectra.Aspergillus niger ATCC 6275,Syncephalastrum racemosum UT-70, andCunninghamella elegans ATCC 9245 initially transformed [9-¹⁴C]phenanthrene to produce metabolites at the 9,10-, 1,2-, and 3,4- positions. Subsequently, sulfate conjugates of phase I metabolites were formed byA. niger, S. racemosum, andC. elegans. Minor glucuronide conjugates of 9-phenanthrol and phenanthrenetrans-9,10-dihydrodiol were formed byS. racemosum andA. niger, respectively. In addition,C. elegans produced the glucose conjugates 1-phenanthryl -d-glucopyranoside and 2-hydroxy-1-phenanthryl -d-glucopyranoside, a novel metabolite. [9-¹⁴C]Phenanthrene metabolites were not detected in organic extracts from biotransformation experiments with the yeasts,Candida lipolytica 37-1,Candida tropicalis ATCC 32113, andCandida maltosa R-42.