|本期目录/Table of Contents|

[1]徐彦刚,羊杏平,李良俊.瓜类作物抗蔓枯病研究进展[J].江苏农业科学,2020,48(03):49-55.
 Xu Yangang,et al.Research progress on resistance of cucurbit crops to gummy stem blight[J].Jiangsu Agricultural Sciences,2020,48(03):49-55.
点击复制

瓜类作物抗蔓枯病研究进展(PDF)
分享到:

《江苏农业科学》[ISSN:1002-1302/CN:32-1214/S]

卷:
第48卷
期数:
2020年第03期
页码:
49-55
栏目:
专论与综述
出版日期:
2020-03-15

文章信息/Info

Title:
Research progress on resistance of cucurbit crops to gummy stem blight
作者:
徐彦刚12 羊杏平1 李良俊2
1.江苏省农业科学院蔬菜研究所,江苏南京 210014; 2.扬州大学园艺与植物保护学院,江苏扬州 225009
Author(s):
Xu Yanganget al
关键词:
瓜类作物蔓枯病致病机理抗病育种
Keywords:
-
分类号:
S436.42
DOI:
-
文献标志码:
A
摘要:
蔓枯病是瓜类作物生产中最主要的病害之一,其发病率呈现逐年上升的蔓延趋势,对我国乃至世界瓜类产业的发展造成严重危害。该病害致病菌可附着与土壤、病残体或其他宿主进行越冬,待翌年适宜的条件刺激后进行初侵染与再侵染,从而致使该病害防控难度增加及连年发生。目前该病的主要防治手段有化学防治、生物防治及抗性育种,抗性育种最为有效和安全,而不同瓜类作物之间对蔓枯病的抗性表现多为主效基因或多基因控制的数量性状,且在蔓枯病菌侵染瓜类作物时寄主表现出相似或不同的抵御方式,其中主要包括自身固有的物理屏障和外界触发的PTI、EPI免疫。因此,本文通过对不同瓜类作物间抗性遗传表现及防御机制进行阐述,以期为瓜类作物抗性育种及病害防控提供指导。
Abstract:
-

参考文献/References:

[1]Keinath A P. From native plants in central Europe to cultivated crops worldwide:the emergence of Didymella bryoniae as a cucurbit pathogen[J]. HortScience,2011,46(4):532-535.
[2]Basim E,Basim H,Abdulai M,et al. Identification and characterization of Didymella bryoniae causing gummy stem blight disease of watermelon (Citrullus lanatus) in Turkey[J]. Crop Protection,2016,90:150-156.
[3]Hao W Y,Ren L X,Ran W,et al. Allelopathic effects of root exudates from watermelon and rice plants on Fusarium oxysporum f.sp. niveum[J]. Plant and Soil,2010,336(1/2):485-497.
[4]鲁秀梅,张宁,夏美玲,等. 不同抗性甜瓜接种蔓枯病菌后内源激素含量变化及其相关基因的表达分析[J]. 南京农业大学学报,2018,41(2):248-255.
[5]Keinath A P. Survival of Didymella bryoniae in infested muskmelon crowns in South Carolina[J]. Plant Disease,2008,92(8):1223-1228.
[6]Keinath A P. Differential susceptibility of nine cucurbit species to the foliar blight and crown canker phases of gummy stem blight[J]. Plant Disease,2014,98(2):247-254.
[7]李伟,张爱香,江蛟,等. 甜瓜蔓枯病病原鉴定及其生物学特性[J]. 江苏农业学报,2008,24(2):148-152.
[8]任海英,李岗,方丽,等. 不同甜瓜品种蔓枯病抗性与抗坏血酸过氧化物酶基因表达的关系[J]. 植物病理学报,2012(3):306-310.
[9]Stewart J E,Turner A N,Brewer M T. Evolutionary history and variation in host range of three Stagonosporopsis species causing gummy stem blight of cucurbits[J]. Fungal Biology,2015,119(5):370-382.
[10]Li H X,Gottilla T M,Brewer M T. Organization and evolution of mating-type genes in three Stagonosporopsis species causing gummy stem blight of cucurbits and leaf spot and dry rot of papaya[J]. Fungal Biology,2017,121(10):849-857.
[11]Li H X,Brewer M T. Spatial genetic structure and population dynamics of gummy stem blight fungi within and among watermelon fields in the southeastern United States[J]. Phytopathology,2016,106(8):900-908.
[12]Ronald T,Kother A,Anthony P,et al. AFLP analysis of a worldwide collection of Didymella bryoniae[J]. Mycological Research,2003,107(3):297-304.
[13]Babu B,Kefialew Y W,Li P F,et al. Genetic characterization of Didymella bryoniae isolates infecting watermelon and other cucurbits in Florida and Georgia[J]. Plant Disease,2015,99(11):1488-1499.
[14]胡凤云,莫贱友,韦继光,等. 西瓜甜瓜蔓枯病病菌差异性初步研究[J]. 中国瓜菜,2012,25(6):9-12.
[15]Li P F,Ren R S,Yao X F,et al. Identification and characterization of the causal agent of gummy stem blight from muskmelon and watermelon in East China[J]. Journal of Phytopathology,2015,163(4):314-319.
[16]Burdon J J,Thrall P H. Coevolution of plants and their pathogens in natural habitats[J]. Science,2009,324:755-756.
[17]Yao X F,Li P F,Xu J H,et al. Rapid and sensitive detection of Didymella bryoniaeby visual loop-mediated isothermal amplification assay[J]. Frontiers in Microbiology,2016,8:1372.
[18]徐秀兰,宋顺华,张志勇,等. 西瓜重要种传病害研究进展[J]. 植物保护,2016,42(1):12-18,39.
[19]胡凤云,莫贱友,韦继光,等. 西瓜甜瓜蔓枯病防治研究进展[J]. 中国瓜菜,2011,24(6):40-44.
[20]Café-Filho A C,Santos G R,Laranjeira F F. Temporal and spatial dynamics of watermelon gummy stem blight epidemics[J]. European Journal of Plant Pathology,2010,128(4):473-482.
[21]Sudisha J,Niranjana S R,Umesha S,et al. Transmission of seed-borne infection of muskmelon by Didymella bryoniae and effect of seed treatments on disease incidence and fruit yield[J]. Biological Control,2006,37(2):196-205.
[22]姚协丰,徐锦华,李苹芳,等. 菜瓜蔓枯病苗期抗性鉴定方法比较[J]. 中国瓜菜,2017,30(2):11-14.
[23]Gasparotto F,de Oliveira R R,Penharbel M P,et al. Effect of grafting on the control of gummy stem blight in muskmelons[J]. Semina Ciencias Agrarias,2016,37(5):2859-2866.
[24]Brewer M T,Rath M,Li H X. Genetic diversity and population structure of cucurbit gummy stem blight fungi based on microsatellite markers[J]. Phytopathology,2015,105(6):815-824.
[25]Buzi A,Chilosi G,Magro P. Induction of resistance in melon to Didymella bryoniae and Sclerotinia sclerotiorum by seed treatments with acibenzolar-S-methyl and methyl jasmonate but not with salicylic acid[J]. Journal of Phytopathology,2004,152(1):34-42.
[26]Zhang J,Bruton B D,Biles C L. Cell wall-degrading enzymes of Didymella bryoniae in relation to fungal growth and virulence in cantaloupe fruit[J]. European Journal of Plant Pathology,2014,139(4):749-761.
[27]Curren T. Pectic and cellulolytic enzymes produced by Mycosphaerella citrullina[J]. Canadian Journal of Botany,2011,47(5):791-794.
[28]Zhang J X,Bruton B D,Miller M E,et al. Relationship of developmental stage of cantaloupe fruit to black rot susceptibility and enzyme production by Didymella bryoniae[J]. Plant Disease,1999,83(11):1025-1032.
[29]Grube M,Fuernkranz M,Zitzenbacher S,et al. Emerging multi-pathogen disease caused by Didymella bryoniae and pathogenic bacteria on Styrian oil pumpkin[J]. European Journal of Plant Pathology,2011,131(3):539-548.
[30]van der Meer Q P,van Bennekom J L,van der Giessen V. Gummy stem blight resistance of cucumber (Cucumis sativus L.)[J]. Euphytica,1978,27:861-864.
[31]Wehner T C,Amand P C S. Field tests for cucumber resistance to gummy stem blight in North Carolina[J]. HortScience,1993,28(4):327-329.
[32]Wehner T C,Shetty N V. Screening the cucumber germplasm collection for resistance to gummy stem blight in North Carolina field tests[J]. HortScience,2000,35(6):1132-1140.
[33]李英. 瓜类蔓枯病菌的生物学特性和黄瓜抗病资源的筛选[D]. 南京:南京农业大学,2007.
[34]Sowell G. Additional sources of resistance to gummy stem blight of muskmelon[J]. Plant Disease,1981,65:253-254.
[35]Zhang Y P,Kyle M,Anagnostou K,et al. Screening melon(Cucumis melo L.) for resistance to gummy stem blight in the greenhouse and field[J]. HortScience,1997,32(1):117-121.
[36]Frantz J D,Jahn M M. Five Independent loci each control monogenic resistance to gummy stem blight in melon (Cucumis melo L.)[J]. Theoretical and Applied Genetics,2004,108(6):1033-1038.
[37]Wolukau J N,Zhou X H,Li Y,et al. Resistance to gummy stem blight in melon (Cucumis melo L.) germplasm and inheritance of resistance from plant introductions 157076,420145,and 323498[J]. HortScience,2007,42(2):215-221.
[38]Santos L D,Candido W D,Rabelo H D,et al. Reaction of melon genotypes to Didymella bryoniae (Fuckel) Rehm[J]. Chilean Journal of Agricultural Research,2017,77(1):71-77.
[39]顾卫红,杨红娟,马坤,等. 西瓜种质资源的抗蔓枯病性鉴定及其利用[J]. 上海农业学报,2004,20(1):65-67.
[40]Gusmini G,Song R H,Wehner T C. New sources of resistance to gummy stem blight in watermelon[J]. Crop Science,2005,45(2):582-588.
[41]宋荣浩,戴富明,杨红娟,等. 西瓜品种资源对枯萎病和蔓枯病的抗性鉴定[J]. 植物保护,2009,35(1):117-120.
[42]王晓东,李国英. 哈密瓜蔓枯病菌分生孢子器诱发及室内品种抗病性测定[J]. 新疆农业科学,2004,41(5):341-344.
[43]Ausubel F M. Are innate immune signaling pathways in plants and animals conserved?[J]. Nature Immunology,2005,6(10):973-979.
[44]Chisholm S T,Coaker G,Day B,et al. Host-microbe interactions:shaping the evolution of the plant immune response[J]. Cell,2006,124(4):803-814.
[45]Boller T,He S Y. Innate immunity in plants:an arms race between pattern recognition receptors in plants and effectors in microbial pathogens[J]. Science,2009,324(5928):742-744.
[46]Yamazaki A,Hayashi M. Building the interaction interfaces:host responses upon infection with microorganisms[J]. Current Opinion in Plant Biology,2015,23(1):132-139.
[47]Kunst L,Samuels A L. Biosynthesis and secretion of plant cuticular wax[J]. Progress in Lipid Research,2003,42(1):51-80.
[48]戎福喜,秦亚光,陈菲帆,等. 抗白粉病黄瓜叶微卷突变体的叶片结构分析[J]. 中国瓜菜,2017,30(3):11-14.
[49]田丽波,商桑,杨衍,等. 苦瓜叶片结构与白粉病抗性的关系[J]. 西北植物学报,2013,33(10):2010-2015.
[50]Adebooye O C,Hunsche M,Noga G A. Morphology and density of trichomes and stomata of Trichosanthes cucumerina (Cucurbitaceae) as affected by leaf age and salinity[J]. Turkish Journal of Botany,2012,36(4):328-335.
[51]Beckman C H,Mueller W C,McHardy W E. The localization of stored phenols in plant hairs[J]. Physiological Plant Pathology,1972,2(1):69-74.
[52]Rennberger G,Keinathl A P,Hess M. Correlation of trichome density and length and polyphenol fluorescence with susceptibility of five cucurbits to Didymella bryoniae[J]. Journal of Plant Diseases & Protection,2017,124(4):313-318.
[53]Davidsson P,Broberg M,Kariola T,et al. Short oligogalacturonides induce pathogen resistance-associated gene expression in Arabidopsis thaliana[J]. BMC Plant Biology,2017,17(1):1-17.
[54]Jones J D G,Dangl J L. The plant immune system[J]. Nature,2006,444:323-329.
[55]Reimermichalski E M,Conrath U. Innate immune memory in plants[J]. Seminars in Immunology,2016,28(4):319-327.
[56]Khan M,Subramaniam R,Desveaux D. Of guards,decoys,baits and traps:pathogen perception in plants by type Ⅲ effector sensors[J]. Current Opinion in Microbiology,2016,29:49-55.
[57]Gururani M A,Venkatesh J,Upadhyaya C P,et al. Plant disease resistance genes:current status and future directions[J]. Physiological and Molecular Plant Pathology,2012,78(51):51-65.
[58]Durrant W E,Dong X. Systemic acquired resistance[J]. Annual Review of Phytopathology,2004,42(4):185-209.
[59]van Loon L C,Bakker P A H M. Induced systemic resistance as a mechanism of disease suppression by rhizobacteria[J]. Biocontrol & Biofertilization,2006:39-66.
[60]Choudhary D K,Prakash A,Johri B N. Induced systemic resistance(ISR)in plants:mechanism of action[J]. Indian Journal of Microbiology,2007,47(4):289-297.
[61]Keinath A P. Reproduction of Didymella bryoniae on nine species of cucurbits under field conditions[J]. Plant Disease,2014,98(10):1379-1386.
[62]Norton J D. Chilton,a high quality fruit for the commercial market[J]. Ala Agric Exp Stn Leaf,1972,10:184.
[63]Norton J D,Cosper R D. AC-70-154,a gummy stem blight-resistant muskmelon breeding line[J]. HortScience,1989,24(4):709-711.
[64]Wolukau J N,Zhou X H,Chen J F. Identification of amplified fragment length polymorphism markers linked to gummy stem blight (Didymella bryoniae) resistance in melon (Cucumis melo L.) PI420145[J]. HortScience,2009,44(1):32-34.
[65]Zhang N,Xu B H,Bi Y F,et al. Development of a muskmelon cultivar with improved resistance to gummy stem blight and desired agronomic traits using gene pyramiding[J]. Czech Journal of Genetics and Plant Breeding,2017,53(1):23-29.
[66]刘龙洲,翟文强,陈亚丽,等. 甜瓜蔓枯病抗性QTL定位的研究[J]. 果树学报,2013,30(5):748-752.
[67]Norton J. Inheritance of resistance to gummy stem blight in watermelon[J]. HortScience,1979,14(5):630-632.
[68]Gusmini G,Rivera-Burgos L A,Wehner T C. Inheritance of resistance to gummy stem blight in watermelon[J]. HortScience,2017,52(11):1477-1482.
[69]刘文睿,张永兵,周晓慧,等. 甜瓜抗蔓枯病基因Gsb-1的分子标记及其与抗源PI420145中抗病基因的关系[J]. 中国瓜菜,2009,22(5):1-4.
[70]张永兵,陈劲枫,伊鸿平,等. 甜瓜抗蔓枯病基因Gsb-2的ISSR分子标记[J]. 果树学报,2011,28(2):296-300.
[71]张学军,张永兵,张龑,等. 甜瓜抗蔓枯病基因Gsb-3的ISSR分子标记[J]. 西北植物学报,2013,33(2):261-265.
[72]王红英,钱春桃,娄丽娜,等. 甜瓜抗蔓枯病基因Gsb-4的分子标记[J]. 园艺学报,2012,39(3):574-580.
[73]Wolukau J N.Molecular studies of melon(Cucumis melo L.)resistance to gummy stem blight(Didymella bryoniae)[D]. Nanjing:Nanjing Agricultural University,2007.
[74]Chen J F,Staub J E,Tashiro Y,et al. Successful interspecific hybridization between Cucumis sativus L.and C.hystrix Chakr[J]. Euphytica,1997,96(3):413-419.
[75]Lou L A,Wang H Y,Qian C T,et al. Genetic mapping of gummy stem blight (Didymella bryoniae) resistance genes in Cucumis sativus-hystrix introgression lines[J]. Euphytica,2013,192(3):359-369.
[76]Zhang S P,Liu S L,Miao H,et al. Inheritance and QTL mapping of resistance to gummy stem blight in cucumber stem[J]. Molecular Breeding,2017,37(4):49.
[77]娄丽娜. 黄瓜-酸黄瓜渐渗系抗蔓枯病的资源鉴定、遗传分析及主效QTLs定位[D]. 南京:南京农业大学,2012.
[78]Liu S L,Shi Y X,Miao H,et al. Genetic analysis and QTL mapping of resistance to gummy stem blight in Cucumis sativus seedling stage[J]. Plant Disease,2017,101(7):1145-1152.

相似文献/References:

[1]白甜,黄大跃,刘欣,等.西瓜品种及材料对3种真菌病害的抗性评价[J].江苏农业科学,2024,52(2):123.
 Bai Tian,et al.Evaluation of resistance of watermelon varieties and materials to three fungal diseases[J].Jiangsu Agricultural Sciences,2024,52(03):123.
[2]张惠敏,闫洪朗,王曼曼,等.瓜类作物霜霉病研究进展[J].江苏农业科学,2024,52(22):1.
 Zhang Huimin,et al.Research progress on downy mildew of melon crops[J].Jiangsu Agricultural Sciences,2024,52(03):1.

备注/Memo

备注/Memo:
收稿日期:2018-12-04
基金项目:国家西甜瓜产业技术体系(编号:CARS-26-NO.8);江苏省农业三新工程项目[编号:SXGC(2017)259]。
作者简介:徐彦刚(1992—),男,甘肃平凉人,硕士研究生,从事植物抗病育种与综合治理研究。E-mail:1340111782@qq.com。
通信作者:羊杏平,博士,研究员,从事西瓜、甜瓜育种与生物技术研究。E-mail:1394654153@qq.com。
更新日期/Last Update: 2020-02-05