禾生指葡孢霉的遗传多样性及对苗期青稞的致病性

doi:10.3864/j.issn.0578-1752.2020.01.020

中国农业科学 ›› 2020, Vol. 53 ›› Issue (1): 213-224.doi: 10.3864/j.issn.0578-1752.2020.01.020

• 研究简报 • 上一篇

禾生指葡孢霉的遗传多样性及对苗期青稞的致病性

陈琳¹,蔺瑞明¹(),王凤涛¹,庞云星¹,李雪¹,赵爱平¹,张艳霞²,张金玲^1,³,李文兴⁴,何苏琴⁵,冯晶¹,李赟^1,⁶,文才艺⁶,徐世昌¹

1 中国农业科学院植物保护研究所植物病虫害生物学国家重点实验室,北京 100193
2 青海海北藏族自治州农业科学研究所,青海海北 810299
3 西南科技大学生命科学与工程学院,四川绵阳 621010
4 西藏日喀则市农业科学研究所,西藏日喀则 857000
5 甘肃省农业科学院植物保护研究所,兰州 730070
6 河南农业大学植物保护学院,郑州 450001

收稿日期:2019-06-18 接受日期:2019-08-16 出版日期:2020-01-01 发布日期:2020-01-19
通讯作者: 蔺瑞明
作者简介:陈琳,E-mail：lin170521@163.com。
基金资助:
国家现代农业产业技术体系建设专项(CARS-05)

Genetic Diversity of Dactylobotrys graminicola and Its Pathogenicity to Hordeum vulgare var. nudum Seedlings

Lin CHEN¹,RuiMing LIN¹(),FengTao WANG¹,YunXing PANG¹,Xue LI¹,AiPing ZHAO¹,YanXia ZHANG²,JinLing ZHANG^1,³,WenXing LI⁴,SuQin HE⁵,Jing FENG¹,Yun LI^1,⁶,CaiYi WEN⁶,ShiChang XU¹

1 State Key Laboratory for Biology of Plant Diseases and Insect Pests, Institute of Plant Protection, Chinese Academy of Agricultural Sciences, Beijing 100193
2 Institute of Agricultural Sciences, Haibei Tibetan Autonomous Prefecture of Qinghai, Haibei 810299, Qinghai
3 School of Life Science and Engineering, Southwest University of Science and Technology, Mianyang 621010, Sichuan
4 Shigatse Institute of Agricultural Sciences of Tibet, Shigatse 857000, Tibet
5 Institute of Plant Protection, Gansu Academy of Agricultural Sciences, Lanzhou 730070
6 College of Plant Protection, Henan Agricultural University, Zhengzhou 450001

Received:2019-06-18 Accepted:2019-08-16 Online:2020-01-01 Published:2020-01-19
Contact: RuiMing LIN

摘要/Abstract

摘要：

【背景】在青藏高原及周边高海拔地区,青稞是当地唯一的小禾谷类粮食作物,也是主要饲草来源。穗腐病是近年来仅在青藏高原青稞种植区发现的一种新真菌病害,病原菌为禾生指葡孢霉（Dactylobotrys graminicola）,它能侵染多种麦类作物及禾本科杂草,给青稞安全生产带来严重的挑战。【目的】研究禾生指葡孢霉遗传多样性、系统进化以及对寄主种子萌发的影响,揭示该病原菌的流行传播、与寄主植物互作关系以及初侵染菌源,为病害防治提供参考。【方法】从病害流行区采集病株标本,并从典型病穗组织分离禾生指葡孢霉菌株27个,依据无性世代形态特征加以鉴定,分离获得菌株的单孢培养物,提取基因组DNA。利用SRAP分子标记分析禾生指葡孢霉的全基因组多态性,获得菌株特异性分子标记;利用LSU和Rpb2保守遗传位点比较禾生指葡孢霉与其近缘种属的进化关系;将禾生指葡孢霉分生孢子悬浮液与未萌发或发芽后的青稞种子共培养,分析其对青稞种子萌发及幼苗的影响。【结果】选用14对SRAP引物组合进行穗腐菌遗传多样性分析,平均一对引物扩增产生90个多态性条带;平均每个穗腐病菌株1.4个特异分子性标记,分离自小麦的菌株Z 13008特异性标记最多（7个）,而对照菌株禾谷镰孢（Fusarium graminearum）具有20个特异性标记。禾生指葡孢霉的地域分布与其遗传多样性缺乏明显相关性。在鉴定的菌株中,仅有分离自小麦（Z 13008）、黑麦（Z 13024）和2个分离自青稞的菌株（Z 13013和Z 13006）的遗传多样性与其他菌株差异较大,说明病原菌群体的遗传变异水平较低。利用20个分子标记编制DNA指纹二叉式分类检索表,可鉴定21个禾指葡孢霉菌株。系统进化分析揭示禾生指葡孢霉与丛赤壳属真菌遗传距离较近。青稞种子萌发前接种处理对种子萌发、幼苗生长均无明显的抑制作用,在萌发后共培养处理能明显抑制幼苗根系生长,导致根系变为浅褐色,但对幼苗植株生长无明显影响。【结论】与近缘种禾谷镰孢相比,禾生指葡孢霉群体内基因组DNA多态性较低,而且其遗传变异与寄主种类密切相关。禾生指葡孢霉致病性较弱,对青稞种子萌发和幼苗生长无明显的抑制作用。

关键词: 大麦, 青稞, 禾生指葡孢霉, 穗腐病, SRAP, 遗传多样性, 指纹检索表

Abstract:

【Background】In the high-latitude agricultural areas of Qinghai-Tibet Plateau and its peripheral regions, hulless or naked barley (Hordeum vulgare var. nudum) is the only small grain cereal crop in the local area, and it is also the major forage. Dactylobotrys spike blight, caused by Dactylobotrys graminicola, is a new fungal disease only found in the hulless barley growing areas in Qinghai-Tibet Plateau in recent years, which can attack several triticeae crops and cereal grasses and make a great challenge to security of hulless barley production.【Objective】The objective of this study is to research the genetic diversity, systemic evolution of the fungal pathogen of D. graminicola and its effects on the host seed germination, reveal the pathogen epidemics and spread ways, host-pathogen interrelationship and the primary inoculum, and to provide valuable information for disease control.【Method】The diseased plant samples were collected from the disease epidemic areas, and 27 strains were isolated from the typical infected host spike tissues. After identification based on its biological traits of anamorph, the single-conidium strains were cultivated and used for genomic DNA extraction. The whole genomic diversity was evaluated with SRAP markers and strain-specific markers were developed. The evolution relationship between D. graminicola and its related genera or species was analyzed using the two conserved loci of LSU and Rpb2. The conidium suspension was co-cultivated with the germinated or ungerminated hulless barely seeds, and its effect on barley seed germination and seedling growth of hulless barely was analyzed.【Result】Fourteen SRAP primer combinations were selected to detect genetic diversity of D. graminicola strains, and on average, 90 polymorphic DNA bands were produced per primer combination. For D. graminicola strains, only 1.4 strain-specific markers were developed averagely. The strain of Z 13008 derived from common wheat possessed the most 7 SRAP markers. For Fusarium graminearum used as a control strain, 20 specific markers were identified. It was confirmed that there is no close relationship between strain origins of D. graminicola and their genetic diversity. Among the identified strains, only those like Z 13008 from common wheat, Z 13024 from rye and another two (Z 13013 and Z 13006) from hulless barley showed higher differences in genetic diversity compared with the others, indicating that the genetic variation level of D. graminicola population is low. Besides, it is feasible to characterize the 21 D. graminicola strains with a DNA dichotomous fingerprinting key constructed with 20 SRAP markers. D. graminicola is genetically closely related to the fungal species of genus Nectria through phylogenetic analysis. When inoculating seeds with conidial suspensions before germination, the pathogen had no significant suppression on seed germination and growth of seedlings and their roots. While it could infect and restrain seedling root growth when co-cultivating the germinated seeds with conidial suspensions, and resulted in the infected young roots changing into light brown color, but had no significant effect on seeding growth.【Conclusion】D. graminicola showed lower genetic diversity compared with its relative species of F. graminearum, and its genetic variation is closely related to its host plant species. The pathogenicity of the pathogen is weak, and it has no obvious inhibiting effect on the germination and seedling growth of hulless barley.

Key words: Hordeum vulgare, Hordeum vulgare var. nudum, Dactylobotrys graminicola, Dactylobotrys spike blight, SRAP, genetic diversity, fingerprinting key

陈琳,蔺瑞明,王凤涛,庞云星,李雪,赵爱平,张艳霞,张金玲,李文兴,何苏琴,冯晶,李赟,文才艺,徐世昌. 禾生指葡孢霉的遗传多样性及对苗期青稞的致病性[J]. 中国农业科学, 2020, 53(1): 213-224.

Lin CHEN,RuiMing LIN,FengTao WANG,YunXing PANG,Xue LI,AiPing ZHAO,YanXia ZHANG,JinLing ZHANG,WenXing LI,SuQin HE,Jing FENG,Yun LI,CaiYi WEN,ShiChang XU. Genetic Diversity of Dactylobotrys graminicola and Its Pathogenicity to Hordeum vulgare var. nudum Seedlings[J]. Scientia Agricultura Sinica, 2020, 53(1): 213-224.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2020.01.020

https://www.chinaagrisci.com/CN/Y2020/V53/I1/213

图/表 8

表1

禾生指葡孢霉菌株来源、寄主种类及分离的病变组织"

菌株Strain	来源Origin	寄主种类/组织Host species/tissue	采集日期Collection date
Z 13001	甘肃合作市 Hezuo, Gansu	黑麦/穗 Rye/spike	2013-08
Z 13002	甘肃合作市 Hezuo, Gansu	野燕麦/穗 Wild oat/spike	2013-08
Z 13003	甘肃合作市 Hezuo, Gansu	青稞/穗 Naked barley/spike	2013-08
Z 13004	甘肃卓尼县 Zhuoni, Gansu	青稞/穗 Naked barley/spike	2013-08
Z 13005	甘肃临潭县 Lintan, Gansu	青稞/穗 Naked barley/spike	2013-08
Z 13006	甘肃临潭县 Lintan, Gansu	青稞/穗 Naked barley/spike	2013-08
Z 13007	甘肃临潭县 Lintan, Gansu	黑麦/穗 Rye/spike	2013-08
Z 13008	甘肃临潭县 Lintan, Gansu	小麦/穗 Common wheat/spike	2013-08
Z 13009	甘肃临潭县 Lintan, Gansu	青稞/穗 Naked barley/spike	2013-08
Z 13010	青海湟中县 Huangzhong, Qinghai	青稞/穗 Naked barley/spike	2013-07
Z 13011	青海湟中县 Huangzhong, Qinghai	野燕麦/穗 Wild oat/spike	2013-07
Z 13012	青海互助县 Huzhu, Qinghai	野燕麦/穗 Wild oat/spike	2013-07
Z 13013	青海互助县 Huzhu, Qinghai	青稞/穗 Naked barley/spike	2013-07
Z 13014	青海海晏县 Haiyan, Qinghai	青稞/穗 Naked barley/spike	2013-07
Z 13015	青海海晏县 Haiyan, Qinghai	青稞/穗 Naked barley/spike	2013-07
Z 13016	青海海晏县 Haiyan, Qinghai	青稞/穗 Naked barley/spike	2013-07
Z 13017	青海门源县 Menyuan, Qinghai	野燕麦/穗 Wild oat/spike	2013-07
Z 13018	青海门源县 Menyuan, Qinghai	青稞/穗 Naked barley/spike	2013-07
Z 13019	青海门源县 Menyuan, Qinghai	野燕麦/穗 Wild oat/spike	2013-07
Z 13020	青海门源县 Menyuan, Qinghai	青稞/穗 Naked barley/spike	2013-07
Z 13021	青海门源县 Menyuan, Qinghai	野燕麦/穗 Wild oat/spike	2013-07
Z 13022	青海门源县 Menyuan, Qinghai	野燕麦/穗 Wild oat/spike	2013-07
Z 13023	青海门源县 Menyuan, Qinghai	青稞/穗 Naked barley/spike	2013-07
Z 13024	青海湟源县 Huangyuan, Qinghai	黑麦/穗 Rye/spike	2013-07
Z 13025	青海湟源县 Huangyuan, Qinghai	野燕麦/穗 Wild oat/spike	2013-07
Z 13026	青海湟源县 Huangyuan, Qinghai	青稞/穗 Naked barley/spike	2013-07
Z 13027	青海海晏县 Haiyan, Qinghai	青稞/籽粒 Naked barley/seed	2013-07

表1

表2

图1

表3

表4

图2

表5

图3

参考文献 30

[1]	何苏琴, 王三喜, 赵桂琴, 文朝慧, 刘永刚, 马福全 .燕麦和青稞的一种新病害——鞘腐病. 甘肃农业科技, 2010(10):3-4.
	HE S Q, WANG S X, ZHAO G Q, WEN Z H, LIU Y G, MA F Q . A new disease of oat and hulless barley—Sheath rot disease. Gansu Agricultural Science and Technology, 2010(10):3-4. (in Chinese)
[2]	何苏琴, 文朝慧, 王生荣, 赵桂琴, 王三喜, 刘永刚, 荆卓琼, 马永强 . 引起青稞和燕麦鞘腐病的无性型菌物新属种——禾生指葡孢霉. 菌物学报, 2015,34(3):331-340.
	HE S Q, WEN Z H, WANG S R, ZHAO G Q, WANG S X, LIU Y G, JING Z Q, MA Y Q . Dactylobotrys graminicola: A new phytopathogen causing sheath rot of hulless barley and oats. Mycosystema, 2015,34(3):331-340. (in Chinese)
[3]	方中达 . 植病研究方法. 3版. 北京: 中国农业出版社, 1998: 122-125.
	FANG Z D . Phytopathology Research Method.3rd ed. Beijing: China Agriculture Press, 1998: 122-125. (in Chinese)
[4]	LI G, QUIROS C F . Sequence-related amplified polymorphism (SRAP) a new marker system based on a simple PCR reaction: Its application to mapping and gene tagging in Brassies. Theoretical and Applied Genetics, 2001,103(2/3):455-461.
[5]	李登辉, 郭焕强, 马丽, 马东方, 王凤涛, 冯晶, 蔺瑞明, 徐世昌 . 我国大麦条纹病菌(Pyrenophora graminea)群体遗传多样性AFLP分析. 植物保护, 2016,42(4):71-76.
	LI D F, GUO H Q, MA L, MA D F, WANG F T, FENG J, LIN R M, XU S C . Genetic diversity analysis of Pyrenophora graminea populations in China, the causal organism of barley leaf stripe by using AFLP method. Plant Protection, 2016,42(4):71-76. (in Chinese)
[6]	VILGALYS R, HESTER M . Rapid genetic identification and mapping of enzymatically amplified ribosomal DNA from several Cryptococcus species. Journal of Bacteriology, 1990,172(8):4238-4246.
[7]	LIU Y J, WHELEN S, HALL B D . Phylogenetic relationships among Ascomycetes: Evidence from an RNA polymerase II subunit. Molecular Biology and Evolution, 1999,16(12):1799-1808.
[8]	SHAN F, CLARKE H, YAN G, PLUMMER J A, SIDDIQUE K H M . Development of DNA fingerprinting keys for discrimination of Cicer echinospermum(P.H. Davis) accessions using AFLP markers. Australian Journal of Agricultural Research, 2004,55(9):947-952.
[9]	柳李旺, 龚义勤, 黄浩, 朱献文 . 新型分子标记——SRAP与TRAP及其应用. 遗传, 2004,26(5):777-781.
	LIU L W, GONG Y Q, HUANG H, ZHU X W . Novel molecular marker systems—SRAP and TRAP and their application. Hereditas, 2004,26(5):777-781. (in Chinese)
[10]	ROBARTS D W H, WOLFE A D . Sequence-related amplified polymorphism (SRAP) markers: A potential resource for studies in plant molecular biology. Applications in Plant Sciences, 2014,2(7):1400017.
[11]	朱坚, 高巍, 林伯德, 孙淑静, 郑昭, 杨洁, 谢宝贵 . 金针菇种质资源的SRAP分析. 福建农林大学学报(自然科学版), 2007,36(2):154-158.
	ZHU J, GAO W, LIN B D, SUN S J, ZHENG Z, YANG J, XIE B G . SRAP analysis of Flammulina velutipes germplasm resources. Journal of Fujian Agriculture and Forestry University (Natural Science Edition), 2007,36(2):154-158. (in Chinese)
[12]	FERRIOL M, PICO B, NUEZ F . Genetic diversity of a germplasm collection of Cucurbita pepo using SRAP and AFLP markers. Theoretical and Applied Genetics, 2003,107(2):271-282.
[13]	LI G, GAO M, YANG B, QUIROS C F . Gene for gene alignment between the Brassica and Arabidopsis genomes by direct transcriptome mapping. Theoretical and Applied Genetics, 2003,107(1):168-180.
[14]	林忠旭, 张献龙, 聂以春 . 新型标记SRAP在棉花F₂分离群体及遗传多样性评价中的适用性分析. 遗传学报, 2004,31(6):622-626.
	LIN Z X, ZHANG X L, NIE Y C . Evaluation of application of a new molecular marker SRAP on analysis of F₂ segregation population and genetic diversity in cotton. Acta Genetica Sinica, 2004,31(6):622-626. (in Chinese)
[15]	PRADHAN A, YAN G, PLUMMER J A . Development of DNA fingerprinting keys for the identification of radish cultivars. Australian Journal of Experimental Agriculture, 2004,44(1):95-102.
[16]	ASTARINI I A, PLUMMER J A, LANCASTER R A, YAN G . Fingerprinting of cauliflower cultivars using RAPD markers. Australian Journal of Agricultural Research, 2004,55(2):117-124.
[17]	YUAN H, YAN G, SIDDIQUE KHM, YANG H . RAMP based fingerprinting and assessment of relationships among Australian narrow-leafed lupin (Lupinus angustifolius L.) cultivars. Australian Journal of Agricultural Research, 2005,56(12):1339-1346.
[18]	LIN R, YANG H, KHAN T N, SIDDIQUE K H M, YAN G, . Characterization of genetic diversity and DNA fingerprinting of Australian chickpea (Cicer arietinum L.) cultivars using MFLP markers. Australian Journal of Agricultural Research, 2008,59(8):707-713.
[19]	CARROLL S P, FOX C W . Conservation Biology:Evolution in Action. Oxford UK: Oxford University Press, 2008: 380.
[20]	MÖLLER M, STUKENBROCK E H . Evolution and genome architecture in fungal plant pathogens. Nature Reviews Microbiology, 2017,15(12):756-771.
[21]	GARCÍA-ARENAL F, FRAILE A, MALPICA J M . Variability and genetic structure of plant virus populations. Annual Review of Phytopathology, 2001,39:157-186.
[22]	HITCHMAN R B, HODGSON D J, KING L A, HAILS R S, CORY J S, POSSEE R D . Host mediated selection of pathogen genotypes as a mechanism for the maintenance of baculovirus diversity in the field. Journal of Invertebrate Pathology, 2007,94(3):153-162.
[23]	FREZAL L, JACQUA G, NEEMA C . Adaptation of a fungal pathogen to host quantitative resistance. Frontier in Plant Science, 2018,9:1554.
[24]	KWON J H, CHOI O, KANG B, LEE Y, PARK J, KANG D W, HAN I, PARK E J, KIM J . Identification of Neocosmospora ipomoeae causing tomato stem rot in Korea. Australasian Plant Disease Notes, 2017,12:34.
[25]	XU X M, ROBINSON J D . Effects of fruit maturity and wetness on the infection of apple fruit by Neonectria galligena. Plant Pathology, 2010,59(3):542-547.
[26]	GOSWAMI R S, CORBY KISTLER H . Heading for disaster:Fusarium graminearum on cereal crops. Molecular Plant Pathology, 2004,5(6):515-525.
[27]	GAI X T, XUAN Y H, GAO Z G . Diversity and pathogenicity of Fusarium graminearum species complex from maize stalk and ear rot strains in northeast China. Plant Pathology, 2017,66(8):1267-1275.
[28]	INGLIS D A, COOK R J . Calonectria nivalis causes scab in the Pacific Northwest. Plant Disease, 1981,65(11):923-924.
[29]	MATHRE D E . 大麦病害概略. 2版. 蔺瑞明,冯晶, 陈万权, 徐世昌, 译. , 北京: 中国农业科学技术出版社, 2014: 66-69, 150-153.
	MATHRE D E . Compendium of Barley Disease. 2nd ed. LIN R M, FENG J, CHEN W Q, XU S C, trans. Beijing:China Agricultural Science and Technology Press, 2014: 66-69, 150-153. (in Chinese)
[30]	LI Q Y, QIN Z, JIANG Y M, SHEN C C, DUAN Z B, NIU J S . Screening wheat genotypes for resistance to black point and the effects of diseased kernels on seed germination. Journal of Plant Diseases and Protection, 2014,121(2):79-88.

正向引物序列 Forward primer sequence		反向引物序列 Reverse primer sequence
Me1	TGAGTCCAAACCGGATA	Em1	GACTGCGTACGAATTAAT
Me2	TGAGTCCAAACCGGAGC	Em2	GACTGCGTACGAATTTGC
Me3	TGAGTCCAAACCGGAAT	Em4	GACTGCGTACGAATTTGA
Me4	TGAGTCCAAACCGGACC	Em5	GACTGCGTACGAATTAAC
Me5	TGAGTCCAAACCGGAAG	Em6	GACTGCGTACGAATTGCA
Me6	TGAGTCCAAACCGGTAA	Em9	GACTGCGTACGAATTCGA
Me7	TGAGTCCAAACCGGTCC	Em10	GACTGCGTACGAATTCAG
Me8	TGAGTCCAAACCGGTGC	Em11	GACTGCGTACGAATTCCA

引物组合 Primer combination	多态性条带 Polymorphic band	引物组合 Primer combination	多态性条带 Polymorphic band
Me1-Em2	59	Me6-Em5	210
Me3-Em5	102	Me6-Em10	177
Me3-Em11	22	Me7-Em1	67
Me4-Em2	108	Me7-Em4	97
Me4-Em10	97	Me7-Em6	52
Me4-Em11	22	Me7-Em9	47
Me5-Em2	88	Me8-Em5	107

菌株 Strain	标记数目 Number of markers	菌株特异性标记 Specific marker details ^a
F. graminearum^b	20	Me6-Em5, 230; Me7-Em1, 70; Me7-Em1, 500; Me7-Em4, 120; Me7-Em4, 550; Me7-Em6, 200; Me7-Em6, 310; Me7-Em6, 400; Me8-Em5, 580; Me8-Em5, 120; Me8-Em5, 250; Me4-Em10, 370; Me4-Em10, 330; Me4-Em2, 330; Me4-Em2, 360; Me3-Em5, 500; Me3-Em5, 260; Me3-Em5, 180; Me3-Em5, 160; Me1-Em2, 430
Z 13003-1	4	Me1-Em2, 430; Me4-Em2, 180; Me4-Em11, 270; Me3-Em2, 250
Z 13003	3	Me3-Em2, 250; Me3-Em5, 600; Me3-Em5, 400
Z 13002	5	Me4-Em2, 330; Me3-Em5, 210; Me3-Em2, 370; Me6-Em5, 570; Me6-Em10, 380
Z 13008	7	Me4-Em2, 180; Me4-Em11, 270; Me4-Em11, 210; Me5-Em2, 530; Me3-Em5, 600; Me6-Em10, 100; Me7-Em4, 280
Z 13006	2	Me6-Em5, 320; Me6-Em10, 230
Z 13009	1	Me7-Em4, 230
Z 13012	1	Me3-Em2, 270
Z 13020	1	Me4-Em11, 270
Z 13021	1	Me6-Em10, 100
Z 13024	5	Me7-Em1, 310; Me7-Em1, 120; Me7-Em1, 380; Me7-Em1, 350; Me7-Em1, 600

SRAP标记 SRAP marker^a	P/A^b	菌株数Strain number^c
1. Me6-Em5, 290	P	4, 6, 8, 12, 15, 16, 19, 20, 21
1.1 Me6-Em10, 450	P	4, 12, 15, 16, 19, 21
1.1.1 Me7-Em4, 270	P	19
1.1.2 Me7-Em4, 270	A	4, 12, 15, 16, 21
1.1.2.1 Me7-Em4, 190	P	4, 12, 16
1.1.2.1.1 Me3-Em2, 450	P	4
1.1.2.1.2 Me3-Em2, 450	A	12, 16
1.1.2.1.2.1 Me4-Em2, 190	P	12
1.1.2.1.2.2 Me4-Em2, 190	A	16
1.2 Me6-Em10, 450	A	6, 8, 20
1.2.1 Me6-Em5, 260	P	6, 20
1.2.1.1 Me6-Em10, 230	P	6
1.2.1.2 Me6-Em10, 230	A	20
1.2.2 Me6-Em5, 260	A	8
2. Me6-Em5, 290	A	1, 2, 3, 5,7 ,9, 10, 11, 13, 14, 17, 18, 22
2.1 Me7-Em4, 130	P	2, 3, 7, 9, 17, 18, 22
2.1.1 Me6-Em10, 330	P	2, 9, 17
2.1.1.1 Me3-Em2, 650	P	2
2.1.1.2 Me3-Em2, 650	A	9, 17
2.1.1.2.1 Me6-Em10, 170	P	9
2.1.1.2.2 Me6-Em10, 170	A	17
2.1.2 Me6-Em10, 330	A	3, 7, 18, 22
2.1.2.1 Me6-Em10, 120	P	7, 21
2.1.2.1.1 Me7-Em4, 130	P	7
2.1.2.1.2 Me7-Em4, 130	A	21
2.1.2.2 Me6-Em10, 120	A	3, 18
2.1.2.2.1 Me3-Em5, 500	P	3
2.1.2.2.2 Me3-Em5, 500	A	18
2.2 Me7-Em4, 130	A	1, 5, 10, 11, 13, 14
2.2.1 Me1-Em2, 480	P	1, 5
2.2.1.1 Me3-Em2, 500	P	1
2.2.1.2 Me3-Em2, 500	A	5
2.2.2 Me1-Em2, 480	A	10, 11, 13, 14
2.2.2.1 Me3-Em2, 450	P	10, 11
2.2.2.1.1 Me7-Em6, 450	P	10
2.2.2.1.2 Me7-Em6, 450	A	11
2.2.2.2 Me3-Em2, 450	A	13, 14
2.2.2.2.1 Me7-Em9, 450	P	13
2.2.2.2.2 Me7-Em9, 450	A	14

禾生指葡孢霉的遗传多样性及对苗期青稞的致病性

Genetic Diversity of Dactylobotrys graminicola and Its Pathogenicity to Hordeum vulgare var. nudum Seedlings

RichHTML

PDF

赞

可视化

摘要/Abstract

引用本文

使用本文

图/表 8

参考文献 30

相关文章 15

Metrics

本文评价

推荐阅读 0

[1]	柴海燕,贾娇,白雪,孟玲敏,张伟,金嵘,吴宏斌,苏前富. 吉林省玉米穗腐病致病镰孢菌的鉴定与部分菌株对杀菌剂的敏感性[J]. 中国农业科学, 2023, 56(1): 64-78.
[2]	肖璐婷,李秀红,刘栗君,叶发银,赵国华. 淀粉粒径对大麦淀粉物化特性的影响[J]. 中国农业科学, 2022, 55(5): 1010-1024.
[3]	姜朋, 张鹏, 姚金保, 吴磊, 何漪, 李畅, 马鸿翔, 张旭. 宁麦系列小麦品种的性状特点及相关基因位点分析[J]. 中国农业科学, 2022, 55(2): 233-247.
[4]	李晓川,王朝海,周平,马维,吴瑞,宋治豪,梅艳. 马铃薯品种（系）田间晚疫病抗性评价和全基因组遗传多样性分析[J]. 中国农业科学, 2022, 55(18): 3484-3500.
[5]	万映伶,朱梦婷,刘爱青,金亦佳,刘燕. 中国观赏芍药表型多样性解析与资源评价[J]. 中国农业科学, 2022, 55(18): 3629-3639.
[6]	胡光明,张琼,韩飞,李大卫,李作洲,汪志,赵婷婷,田华,刘小莉,钟彩虹. 猕猴桃属植物通用型SSR分子标记引物的筛选及应用[J]. 中国农业科学, 2022, 55(17): 3411-3425.
[7]	王璐伟,沈志军,李贺欢,潘磊,牛良,崔国朝,曾文芳,王志强,鲁振华. 基于SSR荧光标记的79份桃种质遗传多样性分析[J]. 中国农业科学, 2022, 55(15): 3002-3017.
[8]	陈旭,郝雅琼,聂兴华,杨海莹,刘松,王雪峰,曹庆芹,秦岭,邢宇. 板栗总苞和坚果主要性状与SSR标记的关联分析[J]. 中国农业科学, 2022, 55(13): 2613-2628.
[9]	徐晓,任根增,赵欣蕊,常金华,崔江慧. 中国高粱地方品种和育成品种穗部表型性状精准鉴定及综合评价[J]. 中国农业科学, 2022, 55(11): 2092-2108.
[10]	唐修君,樊艳凤,贾晓旭,葛庆联,陆俊贤,唐梦君,韩威,高玉时. 基于线粒体DNA D-loop区的肉鸡品种遗传多样性和起源分析[J]. 中国农业科学, 2021, 54(24): 5302-5315.
[11]	王钰麟,雷琳,熊文文,叶发银,赵国华. 蒸煮-老化预处理对炒制青稞粉理化性质及体外淀粉消化的影响[J]. 中国农业科学, 2021, 54(19): 4207-4217.
[12]	李琴珵,石洁,何康来,王振营. 化学防控玉米蛀穗害虫对减轻拟轮枝镰孢穗腐病及伏马毒素的作用[J]. 中国农业科学, 2021, 54(17): 3702-3711.
[13]	李昕芫, 娄金秀, 刘清源, 胡健, 张英俊. 中国东北和华北地区紫花苜蓿根瘤菌遗传多样性研究[J]. 中国农业科学, 2021, 54(16): 3393-3405.
[14]	王富强,张建,温常龙,樊秀彩,张颖,孙磊,刘崇怀,姜建福. 基于KASP标记的葡萄品种鉴定[J]. 中国农业科学, 2021, 54(13): 2830-2842.
[15]	闻竞,沈彦岐,王梓钰,李世界,莫蓝月,雷宇豪,张艳,韩四平. 基于图像分析的玉米抗拟轮枝镰孢穗腐病的QTL定位[J]. 中国农业科学, 2021, 54(13): 2724-2736.