1.Sclerotial Development of Grifola umbellata.
Kyung Dal CHOI ; Jung Kyun KWON ; Jae Ouk SHIM ; Sang Sun LEE ; Tae Soo LEE ; Min Woong LEE
Mycobiology 2002;30(2):65-69
Sclerotial development of Grifola umbellata (Pers. : Fr.) Donk was investigated through microscopic examinations. The sclerotium of G. umbellata was bumpy and rugged, multi-branched, and dark-brown to black in color. The sclerotial development of G. umbellata was categorized into three stages such as sclerotial initial, development and maturation. Sclerotium development was initiated as the white fungal mass. The superficial part of white sclerotium changed into gray, light brown and then black as its development proceeded further. As a distinctive characteristic of this fungus, a large number of crystals were observed in the medulla layer of sclerotium during its maturation. For development of new sclerotium, G. umbellata formed a white sclerotial primordium on the matured sclerotium. Development of sclerotium in G. umbellata was intimately associated with rhizomorphs of Armillariella mellea and the developing sclerotia were often penetrated by rhizomorphs of A. mellea into medulla layer.
Fungi
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Grifola*
2.Morphological Characteristics of Pseudosclerotia of Grifola umbellata in In Vitro.
Kyung Dal CHOI ; Kyung Tae LEE ; Hyun HUR ; In Pyo HONG ; Jae Ouk SHIM ; Youn Su LEE ; Tae Soo LEE ; Sang Sun LEE ; Min Woong LEE
Mycobiology 2004;32(1):1-5
The present study was carried out to investigate morphological characteristics of pseudosclerotia of Grifola umbellata formed by artificial cultures. Isolate G. umbellata DUM GUS-01 was obtained from sclerotium cultivated in field. The fungal isolate was cultured on PDYM broth, PDYMA(potato dextrose yeast malt agar) and oak sawdust media at 20degrees C under the dark condition. G. umbellata DUM GUS-01 showed a volumetric increment of fungal lumps rather than mycelial growth. Particularly, G. umbellata DUM GUS-01 produced a large amount of melanin pigments in all culture treatments. The color of the fungal mass has been changed into grey gradually, and then formed melanized rind-like structure on its superficial part. The fungal structures which were covered with melanized rind-like layer were named as pseudosclerotia of G. umbellata. The pseudosclerotia of G. umbellata DUM GUS-01 formed a new white mycelial mass, which was swollen out of the melanized rind structure for its volumetric increment. When the pseudosclerotia were sectioned, their structure was discriminated from two structures such as a melanized rind-like structure layer formed by aggregation of aged mycelia and a white mycelial mass with high density. As results of scanning electron microscopic examination, the pseudosclerotia of G. umbellata DUM GUS-01 which were formed in in vitro conditions were similar to the sclerotia of G. umbellata cultivated in natural conditions except for the crystals formed in medula layer of natural sclerotia. Although size, solidity of rind structure and mycelial compactness of pseudosclerotia were more poor than those of natural sclerotia, the morphological structure and growth pattern of pseudosclerotia were very similar to those of natural sclerotia. Therefore, it is probable to induce pseudosclerotia to sclerotia of G. umbellata in in vitro conditions. Consequently, it seems that the induced pseudosclerotia can be used as inoculum sources to substitute natural sclerotia in field cultivation.
Fungal Structures
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Glucose
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Grifola*
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Melanins
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Yeasts
3.Morphological Characteristics of Hyphal Interaction between Grifola umbellata and its Companion Fungus.
Xiao Ke XING ; Shun Xing GUO ; Min Woong LEE
Mycobiology 2005;33(1):1-6
Morphological characteristics of hyphal interaction between Grifola umbellata (Pers. Ex Fr.) Pilat and its companion fungus which related to sclerotia formation from hyphae were investigated by external observations, light microscopy and transmission electron microscopy (TEM). External observations showed that a dense antagonism line was formed by both G. umbellata and companion fungus after their hyphae contacted each other in dual culture. Many hyphal strands emerged on the colony of G. umbellata and differentiated to sclerotia from where hyphal strands crossed. Light microscope observations revealed the process of antagonism line formation. Mature antagonism with structural differentiation, was composed of three main layers: the rind, the rind underlayer and the hypha layer. TEM observations showed that after colonies hyphal contact, a series of reactions always occurred in both G. umbellata and companion fungus. Cells in the center of antagonism line were dead. Cells of G. umbellata adjacent to the antagonism line were usually large and hollow, with unilateral thickened wall, whereas those of companion fungus were empty, with thin or thick wall. Both hyphal interaction at the antagonism line may be one of the main reasons for sclerotia of G. umbellata differentiation from hypha.
Friends*
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Fungi*
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Grifola*
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Humans
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Hyphae
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Microscopy
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Microscopy, Electron, Transmission
4.A New Method for Cultivation of Sclerotium of Grifola umbellata.
Kyung Dal CHOI ; Kyung Tae LEE ; Jae Ouk SHIM ; Youn Su LEE ; Tae Soo LEE ; Sang Sun LEE ; Shun Xing GUO ; Min Woong LEE
Mycobiology 2003;31(2):105-112
Sclerotia of Grifola umbellata were cultivated by two methods such as burying and root inoculation methods. The sclerotia of G. umbellata produced by the burying method were 6.0~6.8 x 3.4~4.6 x 1.8~1.9 cm (Width x Length x Thickness) in size and 17.3~19.6 g in weight, respectively. Their increase rate was 1.10~1.12 times. On the other hand, the sclerotia cultivated by the root inoculation method were 18.3~31.5 x 12.5~26.4 x 3.1~3.7 cm (Wx L x T) in size and 219.1~576.6 g in weight, respectively. Their growth increment was 11.18~39.77 times. The rhizomorphs of Armillaria mellea were developed with a high density under fallen leaves layer covering cultivation site, and distributed mainly between soil surface and soil depth of about 10 cm as well as colonized prominently on the inoculated wood logs. Fungal interaction between G. umbellata and A. mellea were observed mainly in the stage of white sclerotium of G. umbellata. The sclerotia of G. umbellata which were developed newly and harvested in the root inoculation method were twined with root hairs of host tree and rhizomorphs of A. mellea. The sclerotia of G. umbellata decomposing root hairs of host tree were confirmed through SEM examination. Physiochemical characteristics of soil in all cultivation sites had no significant differences. Soil pH were in the range of pH 3.98~4.40. Organic matters were the range of 17.97~23.86% and moisture contents of soil were 12.00~18.20%. Soil temperatures showed 12.9~13.8degrees C in November and 22.0~23.9degrees C in August, respectively. In conclusion, the root inoculation method seems to be a practical method for cultivating sclerotia of G. umbellata due to its many advantages such as simplicity of inoculation process, shortening of cultivation periods and facility of harvest.
Armillaria
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Colon
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Grifola*
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Hair
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Hand
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Hydrogen-Ion Concentration
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Soil
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Trees
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Wood
5.Production of Polysaccharide by the Edible Mushroom, Grifola frondosa.
Mycobiology 2003;31(4):205-208
The production of polysaccharide according to various developmental stages (mycelium growth, primordium appearance, and fruiting-body formation) in the edible mushroom Grifola frondosa was studied. The cap of the mature mushroom showed the highest amount of polysacchride. Mycelial growth and polysaccharide synthesis were optimal at pH 5 and 20degrees C. Polysaccharide synthesis was maximal after 12 days of cultivation, whereas maximum mycelial growth was shown after 18 days. Mannose, cellobiose and starch increased the level of polysaccharide as well as growth in submerged culture. Glucose and sucrose appeared to be good substrates for fruiting of Grifola frondosa.
Agaricales*
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Cellobiose
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Fruit
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Glucose
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Grifola*
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Hydrogen-Ion Concentration
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Mannose
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Starch
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Sucrose
6.Structure and immunomodulatory activity of extracellular polysaccharide from Grifola frondosa.
Lirong HAN ; Dai CHENG ; Lirui WANG ; Chunling WANG
Chinese Journal of Biotechnology 2016;32(5):648-656
We aimed at analyzing the structure of extracellular polysaccharide A from Grifola frondosa (EXGFP-A) and testing its immunomodulatory activity. Structural analysis shows that EXGFP-A was a contained α-D-glucoside bond and pyranose ring. GC analysis reveals that EXGFP-A was mainly composed of rhamnose, arabinose, xylose, mannose, glucose, galactose, by the molar ratio of 0.28:0.31:0.30:0.06:7.98:0.61. The results of MTT(3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) assay indicates when EXGFP-A was at a concentration of 80 μg/mL and treatment time of 48 h, RAW264.7 cells proliferation index reached a maximum of 137.5%. Meanwhile, the AO staining showed that EXGFP-A activated RAW264.7 cells and improved the level of intracellular nucleic acid metabolism. In addition, in a certain range of concentration, EXGFP-A was able to increase the release of NO in RAW264.7 cells, and upregulate the mRNA expression of immunological factor TNF-α, IL-1β, IL-6, IL-12, IFN-γ and iNOS of RAW264.7 cells. Our results confirm that EXGFP-A had immunomodulatory activity. Our findings provided scientific basis for the structural analysis and application of Grifola frondosa polysaccharide.
Animals
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Cytokines
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metabolism
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Grifola
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chemistry
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Mice
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Nitric Oxide Synthase Type II
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metabolism
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Polysaccharides
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immunology
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RAW 264.7 Cells
7.Effects of companion fungus on several enzymatic activities of Grofola umbellata.
China Journal of Chinese Materia Medica 2004;29(4):310-313
OBJECTIVETo study the effect of companion fungus on several enzymatic activities of Grifola umbellata.
METHODChitinase, beta-1,3-glucanase, proteinase and extracellular enzymes of G. umbellata were measured during dual culturing with companion fungus.
RESULTCompanion fungus could induce the increase of chitinase and beta-1, 3-glucanase activities of G. umbellata. noevident changeswere found in proteinase activity. When in liquid culture, the activities of extracellular enzymes in dual cultured filtrate were between of these of G. umbellata and companion fungus in monocultures.
CONCLUSIONSclerotia differentiation related materials supplied by mutual nutritional supplement between G. umbellata and companion fungus conduce to sclerotial formation of G. umbellata.
Catechol Oxidase ; analysis ; Chitinases ; analysis ; Coculture Techniques ; Glucan 1,3-beta-Glucosidase ; analysis ; Grifola ; growth & development ; physiology ; Peptide Hydrolases ; analysis ; Polyporaceae ; enzymology ; growth & development
8.Water Extract from Spent Mushroom Substrate of Hericium erinaceus Suppresses Bacterial Wilt Disease of Tomato.
A Min KWAK ; Kyeong Jin MIN ; Sang Yeop LEE ; Hee Wan KANG
Mycobiology 2015;43(3):311-318
Culture filtrates of six different edible mushroom species were screened for antimicrobial activity against tomato wilt bacteria Ralstonia solanacearum B3. Hericium erinaceus, Lentinula edodes (Sanjo 701), Grifola frondosa, and Hypsizygus marmoreus showed antibacterial activity against the bacteria. Water, n-butanol, and ethyl acetate extracts of spent mushroom substrate (SMS) of H. erinaceus exhibited high antibacterial activity against different phytopathogenic bacteria: Pectobacterium carotovorum subsp. carotovorum, Agrobacterium tumefaciens, R. solanacearum, Xanthomonas oryzae pv. oryzae, X. campestris pv. campestris, X. axonopodis pv. vesicatoria, X. axonopodis pv. citiri, and X. axonopodis pv. glycine. Quantitative real-time PCR revealed that water extracts of SMS (WESMS) of H. erinaceus induced expressions of plant defense genes encoding beta-1,3-glucanase (GluA) and pathogenesis-related protein-1a (PR-1a), associated with systemic acquired resistance. Furthermore, WESMS also suppressed tomato wilt disease caused by R. solanacearum by 85% in seedlings and promoted growth (height, leaf number, and fresh weight of the root and shoot) of tomato plants. These findings suggest the WESMS of H. erinaceus has the potential to suppress bacterial wilt disease of tomato through multiple effects including antibacterial activity, plant growth promotion, and defense gene induction.
1-Butanol
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Agaricales*
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Agrobacterium tumefaciens
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Bacteria
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Glycine
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Grifola
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Lycopersicon esculentum*
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Oryza
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Pectobacterium carotovorum
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Plants
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Ralstonia solanacearum
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Real-Time Polymerase Chain Reaction
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Seedlings
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Shiitake Mushrooms
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Water*
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Xanthomonas
9.Meta-analysis on effect of Grifola frondosa polysaccharide in regulating in vivo immunoregulatory function on animal disease models.
Ting ZHANG ; Fei ZHAO ; Kai-Nan WU ; Yu JIA ; Xu-Liang LIAO ; Feng-Wen YANG ; Jun-Hua ZHANG ; Bin MA
China Journal of Chinese Materia Medica 2019;44(23):5174-5183
The study aimed to explore the in vivo immunoregulatory function of Grifola frondosa polysaccharide( GFP) on animal disease models. Databases of PubMed,Embase,Web of Scinece,CNKI,CBM and Wan Fang Data were searched from the date of their establishment to February 2018. Two reviewers independently screened included studies and evaluated their quality by using SYRCLE's risk of bias tool. R software was used to analyze the data. Finally,20 animal experiment studies were included. According to Metaanalysis. For cellular immunity,GFP could effectively enhance the proliferation of effect or T cells,natural killer cells and macrophages in mice. The percentage of CD4+T cells( MD = 1. 89,95% CI [0. 94,2. 83],P < 0. 000 1),CD8+T cells( MD = 8. 46,95% CI[5. 93,11. 00],P<0. 000 1),NK cells( MD= 2. 67,95% CI [0. 23,5. 11],P= 0. 03),and macrophages( MD= 14. 09,95% CI[0. 84,27. 34],P= 0. 04) were all higher than those in control group. For humoral immunity,GFP could increase the secretion of TNF-α and INF-γ. The secretion of TNF-α( SMD = 15. 92,95% CI [9. 07,22. 76],P<0. 000 1) and INF-γ( SMD = 5. 34,95% CI[3. 42,7. 26],P<0. 000 1) were all higher than those in control group. In conclusion,GFP could regulate immunologic function by enhancing the proliferation activity of immune cells( CD4+T cells,CD8+T cells,NK cells and macrophages) and the secretion of immune factors( TNF-α and INF-γ) . However,it is necessary to further standardize the selection of specific surface markers of immune cells and the administration of GFP,in order to reduce the heterogeneity among the studies. At the same time,more attention shall be paid to experimental design,implementation and full report,especially to the establishment and implementation of animal experimental registration system,so as to improve the transparency and quality of the whole process of animal experimental research,enhance the value of basic research ultimately,and provide a reliable theoretical basis for the transformation of basic research into clinical research.
Animals
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Cytokines/immunology*
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Disease Models, Animal
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Grifola/chemistry*
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Immune System
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Killer Cells, Natural/immunology*
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Macrophages/immunology*
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Mice
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Polysaccharides/pharmacology*
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T-Lymphocytes/immunology*
10.Experimental study on intervention effect of Grifola frondosa on nonalcoholic steatohepatitis.
Xian-wei DAI ; Zhi-yun CHEN ; Mao-xiang YAN ; Bei-hui HE
China Journal of Chinese Materia Medica 2015;40(9):1808-1811
To study the preventive effect of Grifola frondosa on nonalcoholic steatohepatitis (NASH). The rat model of NASH was established by feeding high-fat diets for 12 weeks and intervened with 0.5 g · kg(-1) · d(-1) and 1.0 g · kg(-1) · d(-1) of C. frondosa powder suspensions. The degrees of hepatocyte fatty degeneration and inflammation were observed under the optical microscope with routine HE staining. The NAFLD activity scores (NAS) were calculated. Serum ALT, AST and hepatic TG and CHOL were tested by the biochemical method. The hepatic MDA was examined by thiobarbituric acid method. The hepatic SOD was tested by the xanthine oxidase test. The hepatic GSH-PX activity was determined by the dithio-nitrobenzoic acid method. Hepatic TNF-α and IL-6 were detected by the enzyme-linked immunosorbent assay (ELISA). The NASH model group induced by high-fat diets showed higher hepatic NAS, ser- um ALT, AST, CHOL and hepatic TG, CHOL, MDA, TNF-α, IL-6 (P < 0.01 or P < 0.05) and lower serum TG and hepatic SOD, GSH-PX (P < 0.01, P < 0.05) than the normal control group. After being intervened with different doses of G. frondosa, the NASH group revealed significantly lower hepatic NAS, serum ALT and hepatic TG, CHOL, MDA, TNF-α and IL-6 (P < 0.05) and higher hepatic SOD, GSH-PX (P < 0.05) than the model group. G. frondosa may prevent the further development of NASH by improving the disorder of lipid metabolism in rats with NASH induced by high-fat diets, relieving the level of oxidative stress and reducing the generation of inflammatory cytokines.
Animals
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Drugs, Chinese Herbal
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administration & dosage
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Grifola
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chemistry
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Humans
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Interleukin-6
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metabolism
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Liver
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drug effects
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metabolism
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Male
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Non-alcoholic Fatty Liver Disease
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drug therapy
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metabolism
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Oxidative Stress
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drug effects
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Rats
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Rats, Sprague-Dawley
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Tumor Necrosis Factor-alpha
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metabolism