<Emphasis Type="Italic">Monascus purpureus</Emphasis>-fermented products and oral cancer: a review

Tobacco and alcohol consumption have been reported as major factors for the development of oral cancer. Edible fungi of the Monascus species have been used as traditional Chinese medicine in eastern Asia for several centuries. Monascus-fermented products have many functional secondary metabolites, including monacolin K, citrinin, ankaflavin, and monascin. In several recent studies performed in our laboratory, these secondary metabolites have shown anti-inflammatory, anti-oxidative, and anti-tumor activities. Many published studies have shown the efficacy of Monascus-fermented products in the prevention of numerous types of cancer. The current article discusses and provides evidence to support that Monascus-fermented metabolites may be developed as painting drugs for the mouth to prevent or cure oral carcinogenesis. This is a novel therapeutic approach focusing on tumor growth attenuation to improve patient survival and quality of life.     

Monascus fermentation of dioscorea for increasing the production of cholesterol-lowering agent—monacolin K and antiinflammation agent—monascin

Monacolin K, an inhibitor for cholesterol synthesis, is the secondary metabolite of Monascus species. The formation of the secondary metabolites of the Monascus species is affected by cultivation environment and method. This research uses sweet potato (Ipomoea batatas), potato (Solanum tuberosum), casava (Manihot esculenta), and dioscorea (Dioscorea batatas) as the substrates and discusses the best substrate to produce monacolin K. The results show that Monascus purpureus NTU 301, with dioscorea as the substrate, can produce monacolin K at 2,584 mg kg⁻¹, which is 5.37 times to that resulted when rice is used as the substrate. In addition, more amount of yellow pigment can be found in Monascus-fermented dioscorea than in Monascus-fermented rice. The certain composition of yellow pigment is identified as monascin, which has been shown as an antiinflammation agent exhibiting potent inhibitory effects on 12-O-tetradecanoylphorbol-13-acetate (TPA)-induced inflammation in mice in previous studies. Therefore, dioscorea is concluded to be the best substrate for Monascus species to produce the cholesterol-lowering agent—monacolin K and antiinflammation agent—monascin.     

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.     

Isolation and characterization of a strain of <Emphasis Type="Italic">Klebsiella pneumoniae</Emphasis> with citrinin-degrading activity

Monascus-fermented products have been widely used in Taiwan and other Asian countries as health foods. Unfortunately, many Monascus strains concurrently produce trace amounts of toxic citrinin. This study isolated a strain NPUST-B11 with the ability to degrade citrinin as the only carbon source. The isolated strain NPUST-B11 was characterised and identified as Klebsiella pneumoniae by 16S rRNA gene analysis using UNI-F and UNI-R primers. The isolated strain was then incubated in the mineral broth containing 10 ppm of citrinin, 1.2% of glucose, 0.3% of peptone and 100 ppm of vitamin C under optimal conditions, including pH 7, 200 rpm and 37°C. Citrinin was rapidly degraded with incubation from 97.9% at 1 h to 8.67% at 5 h and completely depleted at 10 h. Overall, this strain could be useful for the degradation of citrinin in food products and other medical applications.     

Biologically active components and nutraceuticals in the <Emphasis Type="Italic">Monascus</Emphasis>-fermented rice: a review

Monascus-fermented rice has traditionally been used as a natural food colorant and food preservative of meat and fish for centuries. It has recently become a popular dietary supplement because of many of its bioactive constituents being discovered, including a series of active drug compounds, monacolins, indicated as the 3-hydroxy-3-methylglutaryl-coenzyme A reductase inhibitors for reducing serum cholesterol level. The controversy of its safety has been provoked because a mycotoxin, citrinin, is also produced along with the Monascus secondary metabolites by certain strains or under certain cultivation conditions. This review introduces the basic production process and addresses on the compounds with bioactive functions. Current advances in avoiding the harmful ingredient citrinin are also discussed.     

Application of random amplified polymorphic DNA (RAPD) analysis coupled with microchip electrophoresis for high-resolution identification of <Emphasis Type="Italic">Monascus</Emphasis> strains

Monascus fungi are commonly used for a variety of food products in Asia, and are also known to produce some biologically active compounds. Since the use of Monascus is expected to increase in food industries, strain-level identification and management of Monascus will be needed in the near future. In the present study, random amplified polymorphic DNA (RAPD) analysis coupled with microchip electrophoresis was applied for this purpose. Evaluations of the analysis stability revealed that reproducible results could be obtained, although template DNA fragmentation could influence the resulting RAPD pattern. RAPD analysis using 15 Monascus strains consisting of four species, M. ruber, M. pilosus, M. purpureus, and M. kaoliang showed that each strain generated a unique RAPD pattern, which allows strain-level identification of Monascus. In addition, the phylogenetic tree constructed from RAPD patterns reflected M. ruber–M. pilosus and M. purpureus–M. kaoliang clusters inferred from both ITS and β-tubulin gene sequences, which indicated that the RAPD pattern could reflect their phylogenetic traits to a certain extent. On the other hand, RAPD analysis did not support the monophyletic clustering of the four Monascus species used in this study, which suggests the necessity of reexamination of species boundaries in Monascus.     

Red mold fermented products and Alzheimer's disease: a review

Alzheimer's disease is seen mainly in individuals over the age of 65, and the morbidity rate increases with age. Regarding the health function of Monascus-fermented red mold rice (RMR), besides hypolipidemic and hypotensive effects, other health functions of RMR such as anti-oxidation, cancer prevention, anti-fatigue, and anti-obesity have also been reported. Many published studies have shown the efficacy of RMR in the prevention of Alzheimer's disease. The current article discusses and provides evidence to support the beneficial potential of RMR in the prevention of Alzheimer's disease by discussing the pathogenic factors of Alzheimer's disease and the secondary metabolites of Monascus.     

Red mold,diabetes, and oxidative stress: a review

Type 2 diabetes is a major health concern and a rapidly growing disease with a modern etiology, which produces significant morbidity and mortality. The optimal management of type 2 diabetes aims to control hyperglycemia, hypertension, and dyslipidemia to reduce overall risks. Diabetes and its complications usually develop as oxidative stress increases. Monascus-fermented rice, also called red mold rice or red mold dioscorea are used in China to enhance food color and flavor. Red mold-fermented products are popular health foods that are considered to have antiobesity, antifatigue, antioxidation, and cancer prevention effects. This review article describes the antidiabetic and antioxidative stress effects on humans and animals of red mold-fermented products or their secondary metabolites.     

Monascus secondary metabolites: production and biological activity

The genus Monascus, comprising nine species, can reproduce either vegetatively with filaments and conidia or sexually by the formation of ascospores. The most well-known species of genus Monascus, namely, M. purpureus, M. ruber and M. pilosus, are often used for rice fermentation to produce red yeast rice, a special product used either for food coloring or as a food supplement with positive effects on human health. The colored appearance (red, orange or yellow) of Monascus-fermented substrates is produced by a mixture of oligoketide pigments that are synthesized by a combination of polyketide and fatty acid synthases. The major pigments consist of pairs of yellow (ankaflavin and monascin), orange (rubropunctatin and monascorubrin) and red (rubropunctamine and monascorubramine) compounds; however, more than 20 other colored products have recently been isolated from fermented rice or culture media. In addition to pigments, a group of monacolin substances and the mycotoxin citrinin can be produced by Monascus. Various non-specific biological activities (antimicrobial, antitumor, immunomodulative and others) of these pigmented compounds are, at least partly, ascribed to their reaction with amino group-containing compounds, i.e. amino acids, proteins or nucleic acids. Monacolins, in the form of β-hydroxy acids, inhibit hydroxymethylglutaryl-coenzyme A reductase, a key enzyme in cholesterol biosynthesis in animals and humans.     

Perstraction of intracellular pigments by submerged cultivation of <Emphasis Type="Italic">Monascus</Emphasis> in nonionic surfactant micelle aqueous solution

“Milking processing” describes the cultivation of microalgae in a water-organic solvent two-phase system that consists of simultaneous fermentation and secretion of intracellular product. It is usually limited by the conflict between the biocompatibility of the organic solvent to the microorganisms and the ability of the organic solvent to secret intracellular product into its extracellular broth. In the present work, submerged cultivation of Monascus in the nonionic surfactant Triton X-100 micelle aqueous solution for pigment production is exploited, in which the fungus Monascus remains actively growing. Permeabilization of intracellular pigments across the cell membrane and extraction of the pigments to the nonionic surfactant micelles of its fermentation broth occur simultaneously. “Milking” the intracellular pigments in the submerged cultivation of Monascus is a perstraction process. The perstractive fermentation of intracellular pigments has the advantage of submerged cultivation by secretion of the intracellular pigments to its extracellular broth and the benefit of extractive microbial fermentation by solubilizing the pigments into nonionic surfactant micelles. It is shown as the marked increase of the extracellular pigment concentration by the submerged cultivation of Monascus in the nonionic surfactant Triton X-100 micelle solution.     

Production of the secondary metabolites γ-aminobutyric acid and monacolin K by <Emphasis Type="Italic">Monascus</Emphasis>

γ-Aminobutyric acid (GABA), a hypotensive agent, and monacolin K, a cholesterol-lowering drug, can be produced by Monascus spp. Under optimal culture conditions, the products of fermentation using Monascus spp. may serve as a multi-functional dietary supplement and can prevent heart disease. In this study, Monascus purpureus CCRC 31615, the strain with the highest amount of monacolin K, was identified from 16 strains using solid fermentation. Its GABA productivity was particularly high. Addition of sodium nitrate during solid-state fermentation of M. purpureus CCRC 31615 improved the productivity of monacolin K and GABA to 378 mg/kg and 1,267.6 mg/kg, respectively. GABA productivity increased further to 1,493.6 mg/kg when dipotassium hydrophosphate was added to the medium. Electronic Publication     

In vivo hypolipidemic effects and safety of low dosage Monascus powder in a hamster model of hyperlipidemia

Monascus or more commonly known as red mold rice is fermented rice on which Monascus purpureus has been grown. It has been a traditional Chinese food additive for thousands of years in China. Secondary metabolite product of Monascus, monacolin K, has been proven that it could be used as an antihypercholesterolemic agent. In this study, M. purpureus NTU568 mutated and selected from a monacolin K productivity strain—M. purpureus HM105 produced high quantities of monacolin K at a level of 9,500 mg kg⁻¹. This research focused on the effect of adding red mold rice powder of M. purpureus NTU568 to a hamster diet on total cholesterol (TC), triglyceride (TG), high-density lipoprotein cholesterol, and low-density lipoprotein cholesterol (LDL-C). In the results, the oral administration of Monascus powder in hyperlipidemia hamster was indeed proven to decrease TC, TG, and LDL-C levels. Plasma TC levels in hamster fed with Monascus powder at onefold dosage [10.78 mg (day 100 g bw)⁻¹] for 4 and 8 weeks were significantly lower (31.2 and 22.0%, respectively) than that in hyperlipidemia hamster. Plasma TG (30.1 and 17.9%) and LDL-C levels (36.0 and 20.7%) were also significantly lowered by feeding Monascus powder at onefold dosage for 4 and 8 weeks compared to hyperlipidemia hamster. In addition, examinations of liver TC and TG levels of hyperlipidemia hamster were also performed and showed similar effects on lipid-lowering action by oral administration of Monascus powder. Since citrinin is a mycotoxin that possesses nephrotoxic and hepatoxic effects, it has a negative impact on the safety of red mold rice for people. This study examined the liver somatic index [plasma glutamyl oxaloacetic transaminase (GOT) and glutamyl pyruvic transaminase (GPT) levels] and liver biopsy to investigate whether Monascus powder induced damage in liver. It was found that the plasma GOT and GPT levels were not significantly increased by feeding Monascus powder. There was no difference in the results of the liver biopsy between the Monascus powder-treated groups and the control group.     

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.     

Monacolin K production by citrinin‐free Monascus pilosus MS‐1 and fermentation process monitoring

Monacolin K (MK) is a naturally occurring hypocholesterolemic agent that specifically inhibits HMG‐CoA reductase. As a natural source of MK, Monascus‐fermented products are of special interest; however, some Monascus strains could produce citrinin, which is a nephrotoxin, as a contaminant in Monascus‐derived products. A Monascus pilosus strain (MS‐1) that produces high amounts of MK, but no citrinin, was screened in previous investigations. Herein, liquid‐state fermentation parameters of the MS‐1 strain were optimized using statistical methods to maximize the MK yield with potato juice as a basic medium. The maximum MK yield (326.74 μg/mL) was predicted with 50 mL of medium in a 250‐mL conical flask containing 30 g/L sucrose, 38.75 g/L soybean flour, 0.00105 mol/L Mg²⁺ at pH 5.48, and 8% v/v seed inoculum precultured for 42 h at 30°C, incubated at 30°C for 3 days, followed by further incubation for 11 days at 24.7°C. The verified MK yield was 390.68 μg/mL and the MK yield increased to 565.64 μg/mL after 21 days of fermentation. No citrinin was detected in MS‐1‐fermented products. The results suggest that citrinin‐free MK can be obtained from natural medium through liquid‐state fermentation in an economical way. This method will be of practical value to the industrial production of MK.     

Isolation and screening of low-density polyethylene (LDPE) bags degrading bacteria from Addis Ababa municipal solid waste disposal site “Koshe”

Purpose

The present study aimed to explore the binding ability of acyl-CoA binding protein 2 to fatty acid acyl-CoA esters and its effect on Monascus pigment production in M. ruber CICC41233.

Methods

The Mracbp2 gene from M. ruber CICC41233 was cloned with a total DNA and cDNA as the templates through the polymerase chain reaction. The cDNA of the Mracbp2 gene fragment was ligated to expression vector pGEX-6P-1 to construct pGEX-MrACBP2, which was expressed in Escherichia coli BL21 to obtain the fusion protein GST-MrACBP2 and then measure the binding ability of fatty acid acyl-CoA esters. Additionally, the DNA of the Mracbp2 gene fragment was ligated to expression vector pNeo0380 to construct pNeo0380-MrACBP2, which was homologously over-expressed in M. ruber CICC41233 to evaluate Monascus pigment production and fatty acid.

Results

The cloned Mracbp2 gene of the DNA and cDNA sequence was 1525 bp and 1329 bp in length, respectively. The microscale thermophoresis binding assay revealed that the purified GST-MrACBP2 had the highest affinity for palmitoyl-CoA (Kd =70.57 nM). Further, the Mracbp2 gene was homologously overexpressed in M. ruber CICC41233, and a positive transformant M. ruber ACBP-E was isolated. In the Monascus pigments fermentation, the expression level of the Mracbp2 gene was increased by 1.74-fold after 2 days and 2.38-fold after 6 days. The palmitic acid content and biomass in M. ruber ACBP2-E were significantly lower than that in M. ruber CICC41233 on 2 days and 6 days. However, compared with M. ruber CICC41233, the yields of total pigment, ethanol-soluble pigment, and water-soluble pigment in M. ruber ACBP2-E increased by 63.61%, 71.61%, and 29.70%, respectively.

Conclusions

The purified fusion protein GST-MrACBP2 exhibited the highest affinity for palmitoyl-CoA. The Mracbp2 gene was overexpressed in M. ruber CICC41233, which resulted in a decrease in palmitic acid and an increase in Monascus pigments. Overall, the effect of MrACBP2 on the synthesis of fatty acid and Monascus pigment was explored. This paper explored the effect of MrACBP2 on the fatty acid synthesis and the synthesis of Monascus pigment. The results indicated the regulation of fatty acid synthesis could affect Monascus pigment synthesis, providing a novel strategy for improving the yield of Monascus pigment.

     

Use of the <Emphasis Type="Italic">pyrG</Emphasis> gene as a food-grade selection marker in <Emphasis Type="Italic">Monascus</Emphasis>

Ma-pyrG was cloned from Monascus aurantiacus AS3.4384 using degenerate PCR with primers designed with an algorithm called CODEHOP, and its complete sequence was obtained by a PCR-based strategy for screening a Monascus fosmid library. Ma-pyrG encodes orotidine-5′-phosphate decarboxylase (OMPdecase), a 283-aminoacid protein with 81% sequence identity to that from Aspergillus flavus NRRL 3357. A pyrG mutant strain from M. aurantiacus AS3.4384, named UM28, was isolated by resistance to 5-fluoroorotic acid after UV mutagenesis. Sequence analysis of this mutated gene revealed that it contained a point mutation at nucleotide position +220. Plasmid pGFP-pyrG, bearing the green fluorescent protein gene (GFP) as a model gene and Ma-pyrG as a selection marker, were constructed. pGFP-pyrG were successfully transformed into UM28 by using the PEG method.     

Analyses of Monascus pigment secretion and cellular morphology in non‐ionic surfactant micelle aqueous solution

Monascus pigments produced by Monascus spp. are widely used as natural food colourants. Extractive fermentation technology can facilitate the secretion of intracellular Monascus pigments into extracellular non‐ionic surfactant micelle aqueous solution, so as to avoid the feedback inhibition and decomposition. In this study, behaviour of the trans‐membrane secretion of Monascus pigments was investigated using morphological and spectroscopic analyses. Laser scanning confocal microscopy (LSCM) traced that pigment secretion occurred through rapid trans‐membrane permeation in 4 min, with a simultaneous conversion in pigment characteristics. Approximately 50% of intracellular pigments (AU₄₇₀) extracted to extracellular broth with 40 g l^?1 Triton X‐100, indicating the capacity for pigment extraction was limited by the saturation concentrations of surfactant. Scanning electron microscope (SEM) and transmission electron microscope (TEM) imaging showed some damage in the cell wall but an intact cell membrane with a slightly increased mycelial diameter. However, the physiological properties of the cell membrane, including integrity, fluorescence intensity and permeability, were altered. A diagram was provided to demonstrate the behaviour of Monascus pigment secretion induced by Triton X‐100. This study lays a foundation for the further investigation of Monascus pigment metabolism and secretion in extractive fermentation.     

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.     

红色红曲菌M7的丝衣霉酸基因簇及其功能研究

【目的】明确红色红曲菌(Monascus ruber) M7的基因组中是否存在丝衣霉酸(byssochlamic acid, BA)基因簇,并探讨BA基因簇中聚酮合酶基因mr-Bys及3-羟酰基辅酶A脱氢酶基因mr-hdh对BA产生的影响。【方法】采用生物信息学方法对M7基因组进行分析,以确定BA候选基因簇;以基因敲除及过表达方法研究mr-Bys和mr-hdh对BA产生的影响;以超高效液相色谱(ultra-performance liquid chromatography, UPLC)和质谱(mass spectrometry, MS)方法分析BA。【结果】在红色红曲菌M7基因组中发现了BA基因簇,敲除mr-Bys后,BA消失,而敲除和过表达mr-hdh均可影响BA的产生。【结论】红色红曲菌M7基因组中存在BA基因簇,可产生BA。研究结果不仅丰富了红曲菌次生代谢产物及其合成途径的相关研究,也为以红曲菌为菌种开发新产品奠定了基础。