Selection of an effective red-pigment producing Monascus pilosus by efficient transformation with aurintricarboxylic acid

The filamentous fungus Monascus pilosus was genetically transformed with a reporter plasmid, pMS-1.5hp, by aurintricarboxylic acid (ATA) treatment to obtain an efficient red-pigment producing mutant. The transformation efficiency of Monascus pilosus was higher with the ATA-treatment than with either a non-restriction-enzyme-mediated integration (REMI) or a REMI method. This valid and convenient random mutagenesis method shows that ATA can be applied in fungi for efficient genetic transformation.     

红曲霉不同转化方法比较

为了研究红曲霉聚酮体途径,考察和比较了4种不同的转化方法以建立有效的红曲霉遗传转化系统。以潮霉素作为抗性筛选标记,pBC-Hygro作为转化载体,用基于原生质体的传统转化和电击转化、基于萌发孢子的电击转化以及REMI技术转化红曲霉。发现基于萌发孢子的电击转化由于转化率极低而不适于红曲霉转化。基于原生质体的传统转化和电击转化尽管每微克DNA分别能获得135个转化子和125个转化子,但因转化子稳定性差也适合红曲霉转化的转化。应用REMI技术,转化率提高约20倍,每微克DNA 2500个转化子,70%～75%的转化子的稳定,非常适合于红曲霉的转化。      

Identification of <Emphasis Type="Italic">mokB</Emphasis> involved in monacolin K biosynthesis in <Emphasis Type="Italic">Monascus pilosus</Emphasis>

Monacolin K (MK), which is widely used as an antihypercholesterolemia medicine, is produced as a fungal secondary metabolite through the polyketide pathway. The MK biosynthetic gene cluster proposed for Monascus pilosus BCRC38072 was also identified in M. pilosus NBRC4480. The mokB gene, located at the end of the putative gene cluster and possibly encoding polyketide synthase, was disrupted. The mokB disruptant did not produce MK, but accumulated an intermediate that was confirmed to be monacolin J, indicating that mokB encodes the polyketide synthase responsible for the biosynthesis of side-chain diketide moiety.     

Development and production of cholesterol-lowering <Emphasis Type="Italic">Monascus</Emphasis>-nata complex

This study develops a new foodstuff, the Monascus-nata complex, which combines the functions of cholesterol-lowering monacolin k and bacterial dietary-fibre. Two Monascus strains, M. ruber and M. pilosus were fermented within cubical bacterial cellulose, nata de coco, obtained from Acetobacter fermented coconut juice, in a conditioned medium. The production levels and stability of monacolin k in the cultured Monascus-nata complex were determined to develop optimal fermentation conditions. The results indicated that a medium that comprised 5% glucose and 1.5% ammonium phosphate at pH 6.0–7.0 produced the most monacolin k (157 mg/l) for Monascus pilosus NCHU M-35. However, monosodium glutamate (MSG) and 0.001% ZnSO₄ inhibited the intracellular accumulation of monacolin k. Monacolin k within the Monascus-nata complex was relatively resistant to washing and changes of pH, but thermal processing and freezing storage markedly reduced the amount present. This novel Monascus-nata complex is potentially a healthy foodstuff.     

Insertional mutagenesis of Aspergillus fumigatus

We have investigated transformation with heterologous DNA as a method for insertional mutagenesis of Aspergillus fumigatus. Two methods, polyethylene glycol-mediated transformation of protoplasts and electroporation of germinating spores, were used to establish conditions leading to single-copy integration of transforming DNA at different genomic sites. We have assessed the effect of restriction enzyme-mediated integration (REMI) for both methods. Non-REMI protoplast transformation led to integration of multiple copies of transforming DNA in the majority of transformants. Results of REMI with protoplast transformation varied depending on the enzyme used. Low concentrations of several restriction enzymes stimulated transformation, but of ten enzymes investigated only REMI with XhoI and KpnI resulted in single-copy integration of transforming DNA for the majority of transformants. For protoplast transformation with XhoI- or KpnI-based REMI, 50% and 76% of insertions, respectively, were due to integrations at a genomic enzyme site corresponding to the enzyme used for REMI. Electroporation of spores without addition of restriction enzyme resulted in a high transformation efficiency, with up to 67% of transformants containing a single copy of transforming DNA. In contrast to protoplast transformation, electroporation of spores in the presence of a restriction enzyme did not improve transformation efficiency or lead to insertion at genomic restriction sites. Southern analysis indicated that for both protoplast transformation with REMI using KpnI or XhoI and for electroporation of spores without addition of restriction enzymes, transforming DNA inserted at different genomic sites in a high proportion of transformants. Received: 6 March 1998 / Accepted: 25 May 1998     

Molecular mechanisms of insertional mutagenesis in yeasts and mycelium fungi

Random insertional mutagenesis is an efficient tool for studying molecular mechanisms of many genetically determined processes. An improved variant of this method is REMI (Restriction Enzyme Mediated Integration) mutagenesis. In this method, the insertion cassette is introduced into the recipient cell together with restriction endonuclease. As a result, the REMI cassette insertion occurs in sites recognized by the restriction enzyme. The use of restriction endonucleases enhances transformation rate and provides cassette insertion in virtually any locus. A mutation is tagged by the insertion cassette, which can be identified by isolating the REMI cassette together with the flanking genomic DNA regions. The review describes general requirements to REMI. The mechanisms of REMI mutagenesis are surveyed with special reference to yeast Saccharomyces cerevisiae. Special attention is given to the development and use of REMI for other lower eukaryotes (yeasts and mould fungi). Drawbacks of the method and perspectives of its use are discussed.     

Antimicrobial Activity of Monascus pilosus IFO 4520 against Contaminant of Koji

Antimicrobial activity of Monascus pilosus IFO 4520 was examined to prevent contamination during beni-koji making in the open air. The antibacterial effect of the beni-koji prepared with this strain occured with 30 mg/ml of beni-koji extract in combination with 0.5% lactic acid against two contaminants of koji, Micrococcus varians and Bacillus subtilis. There were two compounds, antibacterial and antiyeast substances, in the beni-koji extract. These results suggest a possibility of inhibiting the growths of contaminants during beni-koji making using beni-koji extract and lactic acid.     

Construction of a Homologous Selectable Marker Gene for Lentinula edodes Transformation

We cloned a gene for the iron sulfur protein (Ip) subunit from an edible mushroom, Lentinula edodes, and introduced a point mutation that confers carboxin resistance into it. The mutant gene successfully transformed L. edodes with high efficiency (9 transformants/2.5 μg vector DNA). Restriction enzyme-mediated integration (REMI) increased the transformation efficiency by about two-fold.     

Restriction enzyme-mediated DNA integration in Coprinus cinereus

Restriction enzyme-mediated DNA integration (REMI) has recently received attention as a new technique for the generation of mutants by transformation in fungi. Here we analyse this method in the basidiomycete Coprinus cinereus using the homologous pab1 gene as a selectable marker and the restriction enzymes BamHI, EcoRI and PstI. Addition of restriction enzymes to transformation mixtures results in an earlier appearance of transformants and influences transformation rates in an enzyme- and concentration-dependent manner. Low concentrations of restriction enzyme result in increased numbers of transformants compared to no addition of enzymes. Transformation rates decrease with higher enzyme concentrations. If protoplasts are made from cells stored in the cold, the transformation rates drop drastically even in the presence of low amounts of enzyme. In several transformants, plasmid integration directly correlated with the action of restriction enzyme at random chromosomal restriction sites. In some cases, restriction enzymes appear to reduce the number of integration events per transformant. Simultaneously, mutation rates can be enhanced due to the presence of restriction enzymes. Although restriction enzymes clearly promote plasmid integration into the host genome they also have cytotoxic and possibly mutagenic effects that result from processes other than plasmid integration. In consequence, for any given enzyme used in REMI mutagenesis, the enzyme concentration that gives the highest number of transformants must be defined experimentally. Such optimal transformation conditions should give the highest probability of obtaining mutations caused by a single restriction enzyme-mediated integration of the selection marker. Received: 2 September 1996 / Accepted: 7 April 1997     

Insertional mutagenesis of Aspergillus fumigatus

We have investigated transformation with heterologous DNA as a method for insertional mutagenesis of Aspergillus fumigatus. Two methods, polyethylene glycol-mediated transformation of protoplasts and electroporation of germinating spores, were used to establish conditions leading to single-copy integration of transforming DNA at different genomic sites. We have assessed the effect of restriction enzyme-mediated integration (REMI) for both methods. Non-REMI protoplast transformation led to integration of multiple copies of transforming DNA in the majority of transformants. Results of REMI with protoplast transformation varied depending on the enzyme used. Low concentrations of several restriction enzymes stimulated transformation, but of ten enzymes investigated only REMI with XhoI and KpnI resulted in single-copy integration of transforming DNA for the majority of transformants. For protoplast transformation with XhoI- or KpnI-based REMI, 50% and 76% of insertions, respectively, were due to integrations at a genomic enzyme site corresponding to the enzyme used for REMI. Electroporation of spores without addition of restriction enzyme resulted in a high transformation efficiency, with up to 67% of transformants containing a single copy of transforming DNA. In contrast to protoplast transformation, electroporation of spores in the presence of a restriction enzyme did not improve transformation efficiency or lead to insertion at genomic restriction sites. Southern analysis indicated that for both protoplast transformation with REMI using KpnI or XhoI and for electroporation of spores without addition of restriction enzymes, transforming DNA inserted at different genomic sites in a high proportion of transformants.     

Heterologous expression system in <Emphasis Type="Italic">Aspergillus oryzae</Emphasis> for fungal biosynthetic gene clusters of secondary metabolites

Fungal secondary metabolites have been considered promising resources in the search for novel bioactive compounds. Given the high potential of fungi as genetic resources, it is essential to find an efficient way to link biosynthetic genes to the product in a heterologous system, because many genes for the secondary metabolite in the original strain are silent under standard laboratory conditions. In a previous study, we constructed a heterologous expression system for a biosynthetic gene cluster using Aspergillus oryzae as the host. To make the host more versatile for the expression of secondary metabolism genes, the expression levels of a global regulator, laeA, were increased by placing the A. oryzae laeA gene under the control of the constitutive active pgk promoter. In the A. oryzae overexpressing laeA, two clusters of heterologous biosynthetic genes [the monacolin K (MK) gene cluster from Monascus pilosus and the terrequinone A (TQ) gene cluster from Aspergillus nidulans] were successfully overexpressed, resulting in the production of the corresponding metabolite, MK or TQ. The successful production of secondary metabolites belonging to different structural groups, namely MK as a polyketide and TQ as a hybrid of amino acid and isoprenoid, indicated that the laeA-enriched A. oryzae was a versatile host for the heterologous expression of the biosynthetic gene cluster.     

Bsr-REMI: An improved method for gene tagging using a new vector inDictyostelium

Using a plasmid pBsr2 which carries a blasticidin S-resistant gene, we have improved the method of REMI (restriction enzyme-mediated integration) provided for insertional mutagenesis inDictyostelium discoideum (bsr-REMI). To confirm usefulness of thebsr-REMI, transformation efficiency, copy number of integrated DNA, and randomness of integration into genome were examined.     

Genetic transformation of Monascus purpureus DSM1379

Monascus purpureus was transformed into hygromycin B resistance with hygromycin B phosphotransferase (hph) fused to Aspergillus nidulans trpC or a putative Monascus purpureus gpd1 promoter by electroporation. Among five strains, only M. purpureus DSM1397 was a competent recipient. Normal growth and sporulation on media containing up to 500 mg hygromycin B l^–1 occurred up to five generations. Upon transformation of the strain with the green fluorescent protein gene (sgfp) as a model gene and hph as a selection marker, characteristic green fluorescence was observed under fluoromicroscopy indicating successful transformation.     

Genetic diversity analysis of <Emphasis Type="Italic">Monascus</Emphasis> strains using SRAP and ISSR markers

In this study, sequence-related amplification polymorphism (SRAP) and inter-simple sequence repeat (ISSR) were analyzed for accessing the genetic diversity of 37 Monascus isolates and 14 control strains. According to the dendrogram produced by SRAP data, all the tested strains were grouped into four clusters at a 78% similarity level. Comparatively, 51 tested strains were divided into four major groups at a similarity level of 74% based on the dendrogram generated via ISSR marker analysis. Based on the two sets of dendrograms, Monascus aurantiacus, M. purpureus, M. serorubescens, M. anka, and M. ruber were clustered in the same clade; M. albidus, M. fuliginosus, and M. barkeri were clustered with M. pilosus in a second clade; and M. lunisporas and M. argentinensis occurred together in a third cluster distinct from the other Monascus species. The cluster result produced by SRAP data shared great similarity with that by ISSR data with minor differences in the subgroups, which is basically in agreement with morphological observations. In general, SRAP and ISSR are more simple, rapid, and efficient, which may provide alternative molecular approaches to studying genetic diversity, classification, and identification of Monascus strains.     

Debittering effect of Monascus carboxypeptidase during the hydrolysis of soybean protein

The actions of pepsin and the admixture of pepsin and Monascus pilosus carboxypeptidase 1 (MpiCP-1) on the hydrolysis of soybean protein were studied. The results showed that the pepsin hydrolyzate of soybean protein was much more bitter and contained relatively smaller amounts of total free amino acids than the hydrolyzate obtained with the admixture of pepsin and MpiCP-1. In addition, hydrophilic and hydrophobic amino acids were present in almost equal proportions in the pepsin hydrolyzate, while mainly hydrophobic amino acids made up the hydrolyzate obtained with the admixture of pepsin and MpiCP-1. These results suggest that MpiCP-1 suppresses and reverses the development of the bitterness taste that results from the pepsin hydrolysis of soybean protein by releasing mainly hydrophobic amino acids from the C-termini of the bitter components.     

Molecular mechanisms of insertional mutagenesis in yeasts and mycelium fungi

Random insertional mutagenesis is an efficient tool for studying molecular mechanisms of many genetically determined processes. An improved variant of this method is REMI (Restriction Enzyme Mediated Integration) mutagenesis. In this method, the insertion cassette is introduced into the recipient cell together with restriction endonuclease. As a result, the REMI cassette insertion occurs in sites recognized by the restriction enzyme. The use of restriction endonucleases enhances transformation rate and provides cassette insertion in virtually any locus. A mutation is tagged by the insertion cassette, which can be identified by isolating the REMI cassette together with the flanking genomic DNA regions. The review describes general requirements to REMI. The mechanisms of REMI mutagenesis are surveyed with special reference to yeast Saccharomyces cerevisiae. Special attention is given to the development and use of REMI for other lower eukaryotes (yeasts and mould fungi). Drawbacks of the method and perspectives of its use are discussed.     

Increased transformation frequency and tagging of developmental genes in Aspergillus nidulans by restriction enzyme-mediated integration (REMI)

We have used a plasmid containing the argB gene to transform an Aspergillus nidulansargB-deleted strain in the presence of restriction enzymes and show a 20- to 60-fold increase in transformation frequency via restriction enzyme-mediated integration (REMI). This procedure was used to try to tag new genes involved in the asexual development of this fungus. More than 2000 transformants isolated following electroporation of conidia and ∼3700 transformants recovered following protoplast fusion were screened for sporulation defects. Unexpectedly, developmental mutants were obtained only when the protoplast fusion approach was used. Southern blot analysis of these mutants, and of randomly selected transformants obtained by electroporation, was consistent with the occurrence of single plasmid integration events in 33 and 65% of the cases, respectively. The argB marker was shown to be tightly linked to the mutant phenotype in only 62% of the mutants analyzed by sexual crosses. Partial DNA sequencing of a tagged gene, whose mutation delays asexual sporulation and results in a fluffy phenotype, showed no homology to previously reported sequences. Our results indicate that REMI can be used in A. nidulans to increase the transformation frequency and illustrate the advantages and potential problems when using REMI to tag genes of interest in this and other fungi. Received: 22 August 1997 / Accepted: 20 November 1997     

Simultaneous Enrichment of Deglycosylated Ginsenosides and Monacolin K in Red Ginseng by Fermentation with Monascus pilosus

To improve its bioavailability and pharmacological effects in humans, red ginseng was fermented with a newly isolated fungus, Monascus pilosus KMU103. Most of the ginsenosides were converted to deglycosylated ginsenocides, such as Rh₁, Rh₂, and Rg₃. The total amount of ginsenosides Rh₁, Rh₂, and Rg₃ was 838.7 mg/kg in the red ginseng, and increased to 4,117 mg/kg after 50 L fermentation in 13% red ginseng and 2% glucose. In addition, the Monascus-fermented red ginseng contained 3,089 mg/kg of monacolin K, one of the metabolites produced by Monascus known to reduce cholesterol in the blood. This newly developed Monascus-fermented red ginseng should result in improved health effects, not only by biotransforming gisenosides to deglycosylated ones but also by creating additional bioactive compounds.     

Improvement on genetic transformation in the nematode-trapping fungus Arthrobotrys oligospora and its quantification on dung samples

An improved DNA-mediated transformation system for nematode-trapping fungus Arthrobotrys oligospora based on hygromycin B resistance was developed. The transformation frequency varied between 34 and 175 transformants per μg linearized DNA and 93% of the transformants were stable for drug resistance when tested 100 randomly selected transformants. More than 2000 transformants were obtained by transformation of the fungus with pBChygro in the presence of HindIII and among them, one, YMF1.00110, which lost its ability of forming predacious structure, was isolated. Southern analysis showed that the plasmid DNA had integrated into the genome of all tested transformants (including YMF 1.00110) except one. The transformant tagged with hph gene could be re-isolated and quantified from dung samples based on the resistance of hygromycin B. All the results suggested that the method of restriction enzyme mediated integration (REMI) should facilitate not only the insertional mutagenesis for tagging and analysis genes of interest but also the ecological investigation of tagged fungi in a given environment.     

Transformation of taxol-producing endophytic fungi by restriction enzyme-mediated integration (REMI)

The REMI method was used to introduce the plasmid pV2 harboring the hygromycin B phosphotransferase (hph) gene controlled by the Aspergillus nidulans trpC promoter and the trpC terminator into a taxol-producing endophytic fungus BT2. REMI transformation yielded stable transformants capable of continuing to grow on PDA medium containing 125 mug mL(-1) hygromycin B. The transformation efficiency was about 5-6 transformants mug(-1) plasmid DNA. The presence of hph gene in transformants was confirmed by PCR and Southern blot analyses. To the authors' knowledge, this is the first report on the transformation of taxol-producing endophytic fungi by the REMI technique. This study provides an effective approach for improving taxol production of endophytic fungi by the genetic engineering of taxol biosynthetic pathway genes in the future.