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《北方园艺》[ISSN:1001-0009/CN:23-1247/S]

Issue:

2020年15

Page:

118-124

Research Field:

Publishing date:

Info

Title:

Effects of Increasing Liquid Fermentation Temperature of Ganoderma lucidum on Its Active Component Content

Author(s):

LIU Yueqin; HE Xiaolong; ZHAO Ruihua; REN Guimei

(College of Life Science,Yan′an University,Yan′an,Shaanxi 716000)

Keywords:

Ganoderma lucidum; higher temperature; liquid culture; active ingredient

PACS:

-

DOI:

10.11937/bfyy.20194292

Abstract:

In order to obtain the best fermentation temperature for producing some active components,G.lucidum CGMCC 5.616 was used as the experiment material,the contents of polysaccharide,triterpenoid,polyphenol,flavonoid and total amino acid in G.lucidum were studied under the conditions of 30,32,34,36 ℃ by using high liquid temperature fermentation.The results showed that the contents of polysaccharide,triterpenoid,polyphenol,flavonoid and total amino acid increased first and then decreased with the increased temperature.Under the fermentation temperature at 34 ℃,the contents of polysaccharide,triterpenoid,polyphenol and total amino acid reached the highest on the 6th day,10th day,8th day and 10th day,respectively,which increased by 86.01%,44.91%,52.69% and 29.67% compared with the fermentation temperature at 30 ℃.However,the flavonoids content reached the highest when the fermentation temperature was 32 ℃ and the fermentation time was 10th day, which increased by 40.38% compared with the fermentation temperature at 30 ℃.This study preliminarily confirmed that higher temperature fermentation can improve the content of active ingredients to a certain extent,which provides some ideas and reference value for the low-cost production of G.lucidum active ingredients.

References:

[1]CAO Y,WU S H,DAI Y C.Species clarification of the prize medicinal Ganoderma mushroom ‘Lingzhi’[J].Fungal Diversity,2012,56(1):49-62.[2]BABY S,JOHNSON A J,GOVINDAN B.Secondary metabolites from Ganoderma[J].Phytochemistry,2015,114:66-101.[3]BISHOP K S,KAO C H J,XU Y,et al.From 2000 years of Ganoderma lucidum to recent developments in nutraceuticals[J].Phytochemistry,2015,114:56-65.[4]WEI Z,LIU L,GUO X,et al.Sucrose fed-batch strategy enhanced biomass,polysaccharide,and ganoderic acids production in fermentation of Ganoderma lucidum 5.26[J].Bioprocess and Biosystems Engineering,2016,39(1):37-44.[5]叶丽云,林强,刘梅,等.钙离子和水杨酸诱导灵芝多糖和三萜的合成[J].菌物学报,2017,36(2):220-228.[6]WEI Z,DUAN Y,QIAN Y,et al.Screening of Ganoderma strains with high polysaccharides and ganoderic acid contents and optimization of the fermentation medium by statistical methods[J].Bioprocess and Biosystems Engineering,2014,37(9):1789-1797.[7]TANG Y J,ZHANG W,ZHONG J J.Performance analyses of a pH-shift and DOT-shift integrated fed-batch fermentation process for the production of ganoderic acid and Ganoderma polysaccharides by medicinal mushroom Ganoderma lucidum[J].Bioresource Technology,2009,100(5):1852-1859.[8]TANG Y J,ZHONG J J.Role of oxygen supply in submerged fermentation of Ganoderma lucidum for production of Ganoderma polysaccharide and ganoderic acid[J].Enzyme and Microbial Technology,2003,32(3):478-484.[9]FENG J,ZHANG J S,FENG N,et al.A novel Ganoderma lucidum G0119 fermentation strategy for enhanced triterpenes production by statistical process optimization and addition of oleic acid[J].Engineering in Life Sciences,2017,17(4):430-439.[10]刘月芹,贺晓龙,任桂梅.较高温度对灵芝培养特性及灵芝酸产量的影响[J].微生物学杂志，2019,39(2):90-96.[11]FENG J,FENG N,ZHANG J S,et al.A new temperature control shifting strategy for enhanced triterpene production by Ganoderma lucidum G0119 based on submerged liquid fermentation[J].Applied Biochemistry and Biotechnology,2016,180(4):740-752.[12]孟歌,崔宝凯,李春道,等.药用真菌灵芝液体培养过程中的抗氧化活性研究[J].菌物学报,2018,37(4):486-501.[13]谢春芹,杨鹤同,吴琴燕,等.桑黄黄酮、多糖高产优良菌株的筛选试验[J].江苏农业科学,2019,47(14):209-212.[14]FU Y,SHI L,DING K.Structure elucidation and anti-tumor activity in vivo of a polysaccharide from spores of Ganoderma lucidum (Fr.) Karst[J].International Journal of Biological Macromolecules,2019,141:693-699.[15]陈文华，程显好，谭会颖.灵芝多糖的药理作用及其机制研究进展[J].中国药房，2018,29(24)：3446-3450.[16]KU Y G,KIM H C,BAE J H,et al.Antioxidant capacities and polyphenols in autumn-growing cultivar of Chinese cabbage (Brassica rapa L.ssp.pekinensis cv.Bulam Plus)[J].European Food Research and Technology,2019,245(9):1-9.[17]LAVECCHIA R,MAFFEI G,PACCASSONI F,et al.Artichoke waste as a source of phenolic antioxidants and bioenergy[J].Waste and Biomass Valorization,2019,10(10):2975-2984.[18]MIYATA Y,TATSUZAKI J,YANG J,et al.Potential therapeutic agents,polymethoxylated flavones isolated from Kaempferia parviflora for cataract prevention through inhibition of matrix metalloproteinase-9 in lens epithelial cells[J].Biological and Pharmaceutical Bulletin,2019,42(10):1658-1664.[19]WU S C,HAN F,SONG M R,et al.Natural flavones from morus alba against methicillin-resistant staphylococcus aureus via targeting the proton motive force and membrane permeability[J].Journal of Agricultural and Food Chemistry,2019,67(36):10222-10234.[20]孙冰沁，卓晓沁，何国庆.油酸诱导对灵芝三萜生物合成途径中关键酶编码基因的影响[J].中国食品学报，2019,19(2):251-256.[21]谭贻,唐传红,冯杰,等.灵芝三萜生物合成及调控研究进展[J].食用菌学报,2019,26(3):125-140.[22]LIU Y,ZHANG G,SUN H,et al.Enhanced pathway efficiency of Saccharomyces cerevisiae by introducing thermo-tolerant devices[J].Bioresource Technology,2014,170:38-44.

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Last Update: 2020-10-29