曲霉属真菌活性代谢产物及在农业生产中的应用研究进展
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摘要
曲霉属(Aspergillus)真菌是一类分布广泛的丝状真菌,种类繁多,代谢产物丰富,应用广泛,在农业、医药、生物能源、化妆品、食品发酵等行业均有应用。对近年来曲霉属真菌活性代谢产物在抗菌、抗氧化、抗病毒方面的研究进展进行了综述。结合实验室研究成果,对近年来曲霉属真菌代谢产物在秸秆腐熟菌剂、溶磷生物菌剂、拮抗植物寄生线虫等农业生产领域中的应用进行综述,以期为开发应用曲霉属真菌活性代谢产物的研究提供参考。
The genus of Aspergillus are widely distributed filamentous fungi of great variety, rich in metabolic products, widely applied in agriculture, medicine, bioenergy, cosmetics, food fermentation and other industries. In this paper, recent advances in active metabolites of the genus of Aspergillus fungi in antiseptic, antioxidant and antivirus were reviewed. In addition, combined with the results of laboratory research, the application of the genus of Aspergillus fungi metabolites in straw-thoroughly-decompose agent, phosphorus-dissolving bio-agents and antagonistic plant parasitic nematodes and other production fields were summarized, so as to provide references for the development of the applications of active metabolites of the genus of Aspergillus fungi.
The genus of Aspergillus are widely distributed filamentous fungi of great variety, rich in metabolic products, widely applied in agriculture, medicine, bioenergy, cosmetics, food fermentation and other industries. In this paper, recent advances in active metabolites of the genus of Aspergillus fungi in antiseptic, antioxidant and antivirus were reviewed. In addition, combined with the results of laboratory research, the application of the genus of Aspergillus fungi metabolites in straw-thoroughly-decompose agent, phosphorus-dissolving bio-agents and antagonistic plant parasitic nematodes and other production fields were summarized, so as to provide references for the development of the applications of active metabolites of the genus of Aspergillus fungi.
引文
[1] 胡倩.两株曲霉属对虾肠道真菌次级代谢产物的研究 [D].杭州:浙江大学,2017.
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[35] Xiao CQ,Fang YJ,Chi RA.Phosphate solubilization in vitro by isolated Aspergillus niger and Aspergillus carbonarius[J].Research on Chemical Intermediates,2015,41(5):2867-2878.
[36] 杨顺,杨婷,林斌,等.两株溶磷真菌的筛选、鉴定及溶磷效果的评价[J].微生物学报,2017,58(2):264-273.
[37] 马卫,刘诚,邵闯,等.一株高效溶磷真菌MEM07的筛选鉴定及其溶磷条件优化[J].绿色科技,2017,20:193-195.
[38] Cheng F,Wang J,Song Z,et al.Nematicidal Effects of 5-Aminolevulinic Acid on Plant-Parasitic Nematodes[J].Journal of Nematology,2017,49(3):295-303.
[39] Jones JT,Haegeman A,Danchin EGJ,et al.Top 10 plant-parasitic nematodes in molecular plant pathology[J].Molecular Plant Pathology,2013,14(9):946-961.
[40] 坚晋卓.禾谷孢囊线虫生防菌株的筛选及鉴定[D].兰州:甘肃农业大学,2016.
[41] Shemshura ON,Bekmakhanova NE,Mazunina MN,et al.Isolation and identification of nematode-antagonistic compounds from the fungus Aspergillus candidus[J].Fems Microbiology Letters,2016,363(5):1-9.
[42] Kimura Y,Tani S,Hayashi A,et al.Nematicidal activity of 5-hydroxymethyl-2-furoic acid against plant-parasitic nematodes[J].Zeitschrift Fur Naturforschung Section C-a Journal of Biosciences,2007,62(4):234-238.
[43] 徐坚,沈颖,王华弟,等.水稻白叶枯病的发生危害与综合防治技术探讨[J].中国稻米,2016,22(2):65-76.
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[46] Verdier V,Vera Cruz C,Leach JE.Controlling rice bacterial blight in Africa:needs and prospects[J].Journal of Biotechnology,2012,159(4):320-328.
[47] El-Shakh ASA,Kakar KU,Wang X,et al.Controlling bacterial leaf blight of rice and enhancing the plant growth with endophytic and rhizobacterial Bacillus strains[J].Toxicological & Environmental Chemistry,2015,97(6):766-785.
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[2] Rokas A.Aspergillus[J].Current Biology,2009,23(5):187-188.
[3] Liu S,Wang HB,Su MZ,et al.New metabolites from the sponge-derived fungus Aspergillus sydowii J05B-7F-4[J].Natural Product Research,2017,31(14) :1682-1686.
[4] Awaad AS,Al-Mudhayyif HA,Al-Othman MR,et al.Amhezole,A novel fungal secondary metabolite from Aspergillus terreus for treatment of microbial mouth infection[J].Phytotherapy Research,2017,31(3):395-402.
[5] Awaad SA,El-Meligy RM,Al-Jaber NA,et al.Anti-ulcerative colitis activity of compounds from Euphorbia granuleta Forssk[J].Phytotherapy Research,2013,27(11):1729-1734.
[6] Zain ME,Awaad AS,Al-Outhman MR,et al.Antimicrobial activities of Saudi Arabian desert plants[J].Phytopharmacology,2012,2(1):106-113.
[7] Ratnaweera PB,Williams DE,Silva EDD,et al.Antibacterial metabolites from the Sri Lankan demosponge-derived fungus,Aspergillus flavipes[J].Current Science,2016,111(9):1473-1479.
[8] Mendes G,Oliveira DDM,Kohlhoff M,et al.Alkaloidal metabolites from Aspergillus felis and their activities against Paracoccidioides brasiliensis[J].Phytochemistry Letters,2016,17:28-35.
[9] Pan C,Shi Y,Chen X,et al.New compounds from a hydrothermal vent crab-associated fungus Aspergillus versicolor XZ-4[J].Organic & Biomolecular Chemistry,2017,15(5):1155-1163.
[10] Tetz G,Cynamon M,Hendricks G,et al.In vitro activity of a novel compound,Mul-1867,against clinically significant fungi Candida spp.and Aspergillus spp.[J].International Journal of Antimicrobial Agents,2017,50(1):47-54.
[11] 严岩.自由基清除剂结合亚低温治疗急性脑梗死临床分析[J].中国实用神经疾病杂志,2012,15(7):31-32.
[12] 徐燕,田莎莎,俞和,等.棘孢曲霉中分离的 2 个新化合物[J].高等学校化学学报,2015,36(6):1107-1111.
[13] Rajamanikyam M,Gade S,Vadlapudi V,et al.Biophysical and biochemical characterization of active secondary metabolites from Aspergillus allahabadii[J].Process Biochemistry,2017,56:45-56.
[14] Saghaie L,Pourfarzam M,Fassihi A,et al.Synthesis and tyrosinaseinhibitory properties of some novel derivatives of kojic acid[J].Results in Pharma Sciences,2013,8(4):233-242.
[15] 郭雷,王聪,郭家才,等.海洋来源塔宾曲霉 LWG- 42 菌株的鉴定及其抗氧化活性化合物的分离[J].微生物学杂志,2017,37(6):30-35.
[16] 宋双,徐佳怡.海洋来源的曲霉属真菌次级代谢产物及其活性研究进展[J].中山大学研究生学刊,2015,36(3):20-32.
[17] He F,Bao J,Zhang XY,et al.Asperterrestide A,a cytotoxic cyclic tetrapeptide from the marine-derived fungus Aspergillus terreus SCSGAF0162[J].Journal of Natural Products,2013,76(6):1182-1186.
[18] Tan QW,Gao FL,Wang FR,et al.Anti-TMV activity of malformin A1,a cyclic penta-peptide produced by an endophytic fungus Aspergillus tubingensis FJBJ11[J].International Journal of Molecular Sciences,2015,16(3):5750-5761.
[19] Zhou M,Zhou K,He P,et al.Antiviral and cytotoxic isocoumarin derivatives from an endophytic fungus Aspergillus oryzae[J].Planta Medica,2016,82(5):414-417.
[20] Du G,Wang ZC,Yang YK,et al.New isochromenes from the fermentation products of entophytic fungus Aspergillus Versicolor and their anti-tobacco mosaic virus activities[J].Cheminform,2016,47(10):1996-2002.
[21] Hu QF,Xing HH,Wang YD,et al.Prenylated isocoumarins from the fermentation products of the endophytic fungus Aspergillus versicolor and their anti-tobacco mosaic virus activities[J].Chemistry of Natural Compounds,2017,53(3):436-439.
[22] Ebadaa SS,El-Neketi M,Ebrahim W,et al.Cytotoxic secondary metabolites from the endophytic fungus Aspergillus versicolor KU258497[J].Phytochemistry Letters,2018,24:88-93.
[23] 王晶.黄柄曲霉和烟曲霉次生代谢产物化学成分的研究[D].武汉:华中科技大学,2016.
[24] 韦苏慧,黄雪年,张伟,等.洛伐他汀工业菌株土曲霉 HZ01 的次级代谢产物合成分析[J].微生物学报,2018,58(5):793-803.
[25] 杨振兴,周怀平,关春林,等.秸秆腐熟剂在玉米秸秆还田中的效果[J].山西农业科学,2013,41(4):354-357.
[26] 韩梦颖,王雨桐,高丽,等.降解秸秆微生物及秸秆腐熟剂的研究进展[J].南方农业学报,2017,48(6):1024-1030.
[27] Anasontzis GE,Thuy NT,Hang DTM,et al.Rice straw hydrolysis using secretomes from novel fungal isolates from Vietnam[J].Biomass and Bioenergy,2017,99:11-20.
[28] Chen YN,Chen YR,Li YP,et al.Application of Fenton pretreatment on the degradation of rice straw by mixed culture of Phanerochaete chrysosporium and Aspergillus niger[J].Industrial Crops & Products,2018,112:290-295.
[29] 李金花.米曲霉CGMCC5992发酵液降解秸秆研究[D].南京:江苏大学,2017.
[30] Li ZQ,Pei X,Zhang ZY,et al.The unique GH5 cellulase member in the extreme halotolerant fungus Aspergillus glaucus CCHA is an endoglucanase with multiple tolerance to salt,alkali and heat:prospects for straw degradation applications[J].Extremophiles,2018,22(4):675-685.
[31] 马旭光,张宗舟.航天诱变菌株黑曲霉ZM-8降解小麦秸秆产纤维素酶条件的优化[J].中国饲料,2011,11:17-31.
[32] Prajapati BP,Suryawanshi RK,Agrawal S,et al.Characterization of cellulase from Aspergillus tubingensis NKBP-55 for generation of fermentable sugars from agricultural residues[J].Bioresource Technology,2018,250:733-740.
[33] 林英,司春灿,韩文华,等.解磷生物研究进展[J].江西农业学报,2017,29(2):99-103.
[34] Khan MS,Zaidi A,Wani PA.Role of phosphate-solubilizing microorganisms in sustainable agriculture:a review[J].Agronomy for Sustainable Development,2007,27(1):29-43.
[35] Xiao CQ,Fang YJ,Chi RA.Phosphate solubilization in vitro by isolated Aspergillus niger and Aspergillus carbonarius[J].Research on Chemical Intermediates,2015,41(5):2867-2878.
[36] 杨顺,杨婷,林斌,等.两株溶磷真菌的筛选、鉴定及溶磷效果的评价[J].微生物学报,2017,58(2):264-273.
[37] 马卫,刘诚,邵闯,等.一株高效溶磷真菌MEM07的筛选鉴定及其溶磷条件优化[J].绿色科技,2017,20:193-195.
[38] Cheng F,Wang J,Song Z,et al.Nematicidal Effects of 5-Aminolevulinic Acid on Plant-Parasitic Nematodes[J].Journal of Nematology,2017,49(3):295-303.
[39] Jones JT,Haegeman A,Danchin EGJ,et al.Top 10 plant-parasitic nematodes in molecular plant pathology[J].Molecular Plant Pathology,2013,14(9):946-961.
[40] 坚晋卓.禾谷孢囊线虫生防菌株的筛选及鉴定[D].兰州:甘肃农业大学,2016.
[41] Shemshura ON,Bekmakhanova NE,Mazunina MN,et al.Isolation and identification of nematode-antagonistic compounds from the fungus Aspergillus candidus[J].Fems Microbiology Letters,2016,363(5):1-9.
[42] Kimura Y,Tani S,Hayashi A,et al.Nematicidal activity of 5-hydroxymethyl-2-furoic acid against plant-parasitic nematodes[J].Zeitschrift Fur Naturforschung Section C-a Journal of Biosciences,2007,62(4):234-238.
[43] 徐坚,沈颖,王华弟,等.水稻白叶枯病的发生危害与综合防治技术探讨[J].中国稻米,2016,22(2):65-76.
[44] Midha S,Bansal K,Kumar S,et al.Population genomic insights into variation and evolution of Xanthomonas oryzae pv.oryzae[J].Scientific Reports,2017,10(7):1-10.
[45] 李仲惺.水稻白叶枯病局部重发生状态下的防控对策探讨[J].中国植保导刊,2014,34(3):28-30.
[46] Verdier V,Vera Cruz C,Leach JE.Controlling rice bacterial blight in Africa:needs and prospects[J].Journal of Biotechnology,2012,159(4):320-328.
[47] El-Shakh ASA,Kakar KU,Wang X,et al.Controlling bacterial leaf blight of rice and enhancing the plant growth with endophytic and rhizobacterial Bacillus strains[J].Toxicological & Environmental Chemistry,2015,97(6):766-785.
[48] Elshakh ASA,Anjum SI,Qiu W,et al.Controlling and defence-related mechanisms of Bacillus strains against bacterial leaf blight of rice[J].Journal of Phytopathology,2016,164(7-8):534-546.
[49] 陈雅涵,王颖,汝冰露,等.皮尔瑞俄类芽孢杆菌 BC-39 对水稻白叶枯病的防治研究[J].杂交水稻,2017,32(2):55-57.
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