The secretory protein COA1 enables Metarhizium robertsii to evade insect immune recognition during cuticle penetration.

The interplay between the insect immune system and entomopathogenic fungi during cuticle penetration is not yet fully understood. Here, we show that a secretory protein COA1 (coat of appressorium 1) from Metarhizium robertsii, an entomopathogenic fungus causing diseases in a wide range of insects, is required to avoid host immune recognition during cuticle penetration. COA1 is highly expressed on the cuticle and translocated to the cell surface, where it directly binds with and masks carbohydrates of the fungal cell wall to avoid provoking the host's intense immune response.

Microbial production of trans-aconitic acid.

Trans-aconitic acid (TAA) is a promising bio-based chemical with the structure of unsaturated tricarboxylic acid, and also has the potential to be a non-toxic nematicide as a potent inhibitor of aconitase. However, TAA has not been commercialized because the traditional production processes of plant extraction and chemical synthesis cannot achieve large-scale production at a low cost. The availability of TAA is a serious obstacle to its widespread application.

Improving the production of the micafungin precursor FR901379 in an industrial production strain.

Background: Micafungin is an echinocandin-type antifungal agent used for the clinical treatment of invasive fungal infections. It is semisynthesized from the sulfonated lipohexapeptide FR901379, a nonribosomal peptide produced by the filamentous fungus Coleophoma empetri. However, the low fermentation efficiency of FR901379 increases the cost of micafungin production and hinders its widespread clinical application.

Construction of an efficient cell factory for lysergic acid production.

Lysergic acid (LA) is the key precursor of ergot alkaloids, and its derivatives have been used extensively for the treatment of neurological disorders. However, the poor fermentation efficiency limited its industrial application. At the same time, the hardship of genetic manipulation has hindered the metabolic engineering of strains to improve the LA titer further.

Discovery of a Unique Flavonoid Biosynthesis Mechanism in Fungi by Genome Mining.

Flavonoids are important plant natural products with variable structures and bioactivities. All known plant flavonoids are generated under the catalysis of a type III polyketide synthase (PKS) followed by a chalcone isomerase (CHI) and a flavone synthase (FNS). In this study, the biosynthetic gene cluster of chlorflavonin, a fungal flavonoid with acetolactate synthase inhibitory activity, was discovered using a self-resistance-gene-directed strategy.

Biosynthesis mechanism, genome mining and artificial construction of echinocandin O-sulfonation.

Micafungin, a semisynthetic derivative of the cyclic hexapeptide FR901379 produced by Coleophoma empetri fermentation, is the only O-sulfonated echinocandin-type antifungal drug. However, the detailed formation mechanism of O-sulfonate group, whether before or after the assembly of hexapeptide, remains elusive. Here, we confirmed that O-sulfonylation occurs after hexapeptide assembly as a kind of postmodification in the biosynthesis of FR901379.

Microbial production of the plant-derived fungicide physcion.

Physcion is a characteristic component of the traditional herb rhubarb with diverse pharmacological activities that has been commercially approved as an herbal fungicide. Nevertheless, its extremely low contents, costly purification procedure and geographically restricted planting severely hinder its application. Here, a cell factory was constructed in the filamentous fungus Aspergillus terreus for physcion production via microbial fermentation by integrating a pathway-modified emodin accumulation module and a position-selective emodin methylation module.

Identification of PKS-NRPS Hybrid Metabolites in Marine-Derived .

Filamentous fungi are abundant resources of bioactive natural products. Here, 151 marine-derived fungi were collected from the north Yellow Sea and identified by an internal transcribed spacer (ITS) sequence. The crude extracts of all strains were evaluated for their antimicrobial activities and analyzed by HPLC fingerprint.

Characterization and Structural Analysis of Emodin--Methyltransferase from .

All -methylated derivatives of emodin, including physcion, questin, and 1--methylemodin, show potential antifungal activities. Notably, emodin and questin are two pivotal intermediates of geodin biosynthesis in . Although most of the geodin biosynthetic steps have been investigated, the key -methyltransferase (OMT) responsible for the -methylation of emodin to generate questin has remained unidentified.

Identification of a polyketide biosynthesis gene cluster by transcriptional regulator activation in Aspergillus terreus.

In filamentous fungi, the secondary metabolism is environmentally sensitive. Most of the biosynthetic gene clusters of secondary metabolites are silent under laboratory conditions. In this study, a highly conserved naphthopyrone PKS ATEG_06206 was identified in the genome sequence of A.

Bienzyme-Catalytic and Dioxygenation-Mediated Anthraquinone Ring Opening.

The C-10-C-4a bond cleavage of anthraquinone is believed to be a crucial step in fungal seco-anthraquinone biosynthesis and has long been proposed as a classic Baeyer-Villiger oxidation. Nonetheless, genetic, enzymatic, and chemical information on ring opening remains elusive. Here, a revised questin ring-opening mechanism was elucidated by gene disruption, enzymatic analysis, and O chasing experiments.

Establishing an Efficient Genetic Manipulation System for Sulfated Echinocandin Producing Fungus .

Micafungin is an important echinocandin antifungal agent for the treatment of invasive fungal infections. In industry, micafungin is derived from the natural product FR901379, which is a non-ribosomal cyclic hexapeptide produced by the filamentous fungus . The difficulty of genetic manipulation in restricts the clarification of FR901379 biosynthetic mechanism.

Aspergillus terreus as an industrial filamentous fungus for pharmaceutical biotechnology.

Aspergillus terreus is an important Aspergillus species, which has been applied in the industrial production of the bio-based chemical itaconic acid and the lipid-lowering drug lovastatin. The excellent fermentation capability has been demonstrated in these industrial applications. The genomic information revealed that the outstanding capacity of natural product synthesis by A.

Discovery and Characterization of a PKS-NRPS Hybrid in by Genome Mining.

Fungal polyketide synthase-nonribosomal peptide synthetase (PKS-NRPS) hybrids have been characterized to produce polyketide-amino acid compounds with striking structural features and biological activities. In this study, a PKS-NRPS hybrid enzyme was found in by genome mining. By activating the cluster-specific transcriptional regulator, this cryptic PKS-NRPS gene cluster was successfully activated and ten products (-) were identified as pyranterreones.

Collaborative Biosynthesis of a Class of Bioactive Azaphilones by Two Separate Gene Clusters Containing Four PKS/NRPSs with Transcriptional Crosstalk in Fungi.

Azaphilones are a family of fungal polyketide metabolites with diverse chemical structures and biological activities with a highly oxygenated pyranoquinone bicyclic core. Here, a class of azaphilones possessing a 6/6/6/6 tetracyclic ring system was identified in Aspergillus terreus, and exhibited potential anticancer activities. The gene deletions and biochemical investigations demonstrated that these azaphilones were collaboratively synthesized by two separate clusters containing four core-enzymes, two nonreducing PKSs, one highly reducing PKS, and one NRPS-like.

Construction of an Efficient and Robust Aspergillus terreus Cell Factory for Monacolin J Production.

Monacolin J is a key precursor for the synthesis of the cholesterol-lowering drug simvastatin. Industrially, monacolin J is manufactured through the alkaline hydrolysis of the fungal polyketide lovastatin, which is relatively complex and environmentally unfriendly. A cell factory for monacolin J production was created by heterologously introducing lovastatin hydrolase into Aspergillus terreus in our previous study.

Enhanced Single-Step Bioproduction of the Simvastatin Precursor Monacolin J in an Industrial Strain of Aspergillus terreus by Employing the Evolved Lovastatin Hydrolase.

Biosynthesis of simvastatin, the active pharmaceutical ingredient of cholesterol-lowering drug Zocor, has drawn increasing global attention in recent years. Although single-step in vivo production of monacolin J, the intermediate biosynthetic precursor of simvastatin, has been realized by utilizing lovastatin hydrolase (PcEST) in our previous study, about 5% of residual lovastatin is still a problem for industrial production and quality control. In order to improve conversion efficiency and reduce lovastatin residues, modification of PcEST is carried out through directed evolution and a novel two-step high-throughput screening method.

Single-step production of the simvastatin precursor monacolin J by engineering of an industrial strain of Aspergillus terreus.

Monacolin J is a key precursor for the synthesis of simvastatin (Zocor), an important drug for treating hypercholesterolemia. Industrially, monacolin J is manufactured through alkaline hydrolysis of lovastatin, a fungal polyketide produced by Aspergillus terreus. Multistep chemical processes for the conversion of lovastatin to simvastatin are laborious, cost expensive and environmentally unfriendly.

Establishing an efficient gene-targeting system in an itaconic-acid producing Aspergillus terreus strain.

Objectives: To develop an efficient gene-targeting platform in an excellent itaconic acid producing strain Aspergillus terreus CICC40205.

Results: The frequency of homologous recombination was improved by deleting the ku80 gene. A nutritional transformation system based on the bidirectionally selectable marker, pyrG An , was established in the ku80-/pyrG-double mutant which is convenient for following marker rescue.

Identification of an itaconic acid degrading pathway in itaconic acid producing Aspergillus terreus.

Itaconic acid, one of the most promising and flexible bio-based chemicals, is mainly produced by Aspergillus terreus. Previous studies to improve itaconic acid production in A. terreus through metabolic engineering were mainly focused on its biosynthesis pathway, while the itaconic acid-degrading pathway has largely been ignored.

Improving itaconic acid production through genetic engineering of an industrial Aspergillus terreus strain.

Background: Itaconic acid, which has been declared to be one of the most promising and flexible building blocks, is currently used as monomer or co-monomer in the polymer industry, and produced commercially by Aspergillus terreus. However, the production level of itaconic acid hasn't been improved in the past 40 years, and mutagenesis is still the main strategy to improve itaconate productivity. The genetic engineering approach hasn't been applied in industrial A.

Direct production of itaconic acid from liquefied corn starch by genetically engineered Aspergillus terreus.

Background: Itaconic acid is on the DOE (Department of Energy) top 12 list of biotechnologically produced building block chemicals and is produced commercially by Aspergillus terreus. However, the production cost of itaconic acid is too high to be economically competitive with the petrochemical-based products. Itaconic acid is generally produced from raw corn starch, including three steps: enzymatic hydrolysis of corn starch into a glucose-rich syrup by α-amylase and glucoamylase, fermentation, and recovery of itaconic acid.

Engineering self-sufficient aldehyde deformylating oxygenases fused to alternative electron transfer systems for efficient conversion of aldehydes into alkanes.

Self-sufficient aldehyde deformylating oxygenases (ADOs) from Synechococcus elongatus PCC7942 fused to alternative electron transfer systems were successfully designed, constructed, characterized and used for efficient conversion of aldehydes into alkanes for the first time.

Cloning, characterization and application of a glyceraldehyde-3-phosphate dehydrogenase promoter from Aspergillus terreus.

It is important to develop native and highly efficient promoters for effective genetic engineering of filamentous fungi. Although Aspergillus terreus is an important industrial fungus for the production of itaconic acid and lovastatin, the available genetic toolbox for this microorganism is still rather limited. We have cloned the 5' upstream region of the glyceraldehyde-3-phosphate dehydrogenase gene (gpd; 2,150 bp from the start codon) from A.