福建省玉米大斑病菌对吡唑醚菌酯不同敏感性菌株的遗传多样性与群体遗传结构分析

doi:10.3969/j.issn.1674-7968.2023.03.015

Abstract
Figure/Table
References
Related Citation (15)

Download: PDF (2035 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract Northern corn leaf blight (NCLB) is a crucial foliar fungal disease that seriously affects corn (Zea mays) yield and quality. To determine the genetic diversity and genetic structure of Setosphaeria turcica isolates with different sensitivities to pyraclostrobin in Fujian Province, the sensitivity of S. turcica isolates to pyraclostrobin in Fujian Province was evaluated using the method of measuring the colony growth inhibition on the fungicide-amended plate, and genetic diversity and genetic structure of the S. turcica isolates with different sensitivities to pyraclostrobin was analyzed using inter-simple sequence repeats (ISSR) markers in this study. The results showed that the range of effective concentration for 50% colonial inhibition (EC₅₀) values of 62 S. turcica isolates to pyraclostrobin in Fujian Province was 0.002 1~1.288 4 μg/mL, with the mean value of (0.127 4±0.254 5) μg/mL. The frequency distribution curve of pyraclostrobin was continuous and unimodal, and disobeyed the normal distribution (W=0.742 2, P=0.001 0<0.05). The ranges of EC₅₀ value for S. turcica isolates with pyraclostrobin-sensitivity, -medium and -insensitivity were 0.002 1~0.011 2, 0.020 6~0.100 0 and 0.101 9~1.288 4 μg/mL, respectively. The resistant ratios of pyraclostrobin-insensitive isolates ranged from 3.01 to 38.01. Analysis of variance revealed that the mean EC₅₀ value of pyraclostrobin-insensitive isolates was significant difference compared with those of isolates with pyraclostrobin-medium and -sensitivity, respectively (P<0.05). In conclusion, a subpopulation of S. turcica with decreased sensitivity to pyraclostrobin has been developed in Fujian Province. Genetic diversity analysis indicated that a total of 66 loci were amplified using 11 ISSR primers, and the percentage of polymorphic loci (P_L) reached as high as 98.48%. The lowest DNA polymorphism was detected from pyraclostrobin-sensitive population (P_L=60.61%), whereas the most abundant polymorphism was detected from those in pyraclostrobin-insensitive population (P_L=68.18%). The index values of genetic diversity for the insensitive population were higher than those of the sensitive population, suggesting that genetic diversity in the insensitive population of S. turcica was more diverse than those of sensitive and mediate populations. The results of genetic differentiation (Φ_PT) and gene flow (Nm) analysis indicated that low genetic differentiation (Φ_PT<0.054, P>0.37) with frequent gene exchange (Nm>8.60) were detected among pyraclostrobin-sensitive, -mediate and -insensitive populations. Clustering analysis also indicated that S. turcica isolates with different sensitivities to pyraclostrobin were randomly clustered in the same branch, suggesting no obvious correlation between genetic differentiation and the level of fungicide resistance. Analysis of molecular variance (AMOVA) revealed that the all source of genetic variation in Fujian S. turcica populations with different sensitivities to pyraclostrobin was derived from within populations. Principal coordinates (PCoA) and population genetic structure analysis indicated that the 3 S. turcica populations with different sensitivities to pyraclostrobin could be divided into 2 genetic groups, with a high similar genetic structure being observed among the 3 different populations. The results from this study provide a reference for monitoring of fungicide resistance of S. turcica in the field and for ecological regulation of northern corn leaf blight by using resistant cultivars.

Key words： Setosphaeria turcica Sensitivity Pyraclostrobin Genetic diversity Population genetic structure

Received: 13 May 2022

ZTFLH:

S432.1

Corresponding Authors: * yxjzb@126.com

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	DAI Yu-Li
	GAN Lin
	LIU Xiao-Fei
	LAN Cheng-Zhong
	YANG Xiu-Juan

Cite this article:

DAI Yu-Li,GAN Lin,LIU Xiao-Fei, et al. Analysis of Genetic Diversity and Population Genetic Structure of Setosphaeria turcica Isolates with Different Sensitivities to Pyraclostrobin in Fujian Province[J]. 农业生物技术学报, 2023, 31(3): 603-616.

URL:

http://journal05.magtech.org.cn/Jwk_ny/EN/10.3969/j.issn.1674-7968.2023.03.015 OR http://journal05.magtech.org.cn/Jwk_ny/EN/Y2023/V31/I3/603

[1] 代玉立, 甘林, 廖蕾, 等. 2021. 福建省甜玉米小斑病菌群体遗传结构和致病性分析[J]. 农业生物技术学报, 29(11): 2198-2211.
(Dai Y L, Gan L, Liao L, et al.2021. Population genetic structure and pathogenicity analysis of Cochlibolus heterostrophus from sweet corn (Zea mays) in Fujian Province[J]. Journal of Agricultural Biotechnology, 29(11): 2198-2211.)
[2] 代玉立, 甘林, 阮宏椿, 等. 2019a. 福建省玉米大斑病菌ISSR-PCR反应体系的优化和引物的筛选[J]. 福建农业学报, 34(7): 810-817.
(Dai Y L, Gan L, Ruan H C, et al.2019a. ISSR-PCR optimization and primer selection for analyzing Exserohilum turcicum isolates collected in Fujian[J]. Fujian Journal of Agricultural Sciences, 34(7): 810-817.)
[3] 代玉立, 甘林, 阮宏椿, 等. 2019b. 福建省丙环唑不同敏感性玉米小斑病菌的遗传多样性和致病性[J]. 植物病理学报, 49(1): 64-74.
(Dai Y L, Gan L, Ruan H C, et al.2019b. Genetic diversity and pathogenicity of different propiconazole-sensitive isolates of Bipolaris maydis in Fujian Province[J]. Acta Phytopathologica Sinica, 49(1): 64-74.)
[4] 代玉立, 甘林, 滕振勇, 等. 2020. 玉米大斑病菌和小斑病菌交配型多重PCR检测方法的建立与应用[J]. 中国农业科学, 53(3): 527-538.
(Dai Y L, Gan L, Teng Z Y, et al.2020. Establishment and application of a multiple PCR method to detect mating types of Exserohilum turcicum and Bipolaris maydis[J]. Scientia Agricultura Sinica, 53(3): 527-538.)
[5] 甘林, 代玉立, 卢学松, 等. 2021. 闽南山区鲜食玉米叶斑病季节性流行动态及药剂防治[J]. 植物保护, 47(6): 213-222, 230.
(Gan L, Dai Y L, Lu X S, et al.2021. Seasonal epidemic dynamics and chemical control of leaf spot diseases on fresh corn in the mountain area of the south Fujian[J]. Plant Protection, 47(6): 213-222, 230.)
[6] 郭建国, 杨凤珍, 杜蕙, 等. 2015. 甘肃玉米大斑病菌对嘧菌酯的敏感基线与抗药性监测[J]. 植物保护学报, 42(6): 1044-1049.
(Guo J G, Yang F Z, Du H, et al.2015. Monitoring of resistance and baseline sensitivity of Setosphaeria turcica to azoxystrobin in Gansu[J]. Acta Phytophylacica Sinica, 42(6): 1044-1049.)
[7] 郭丽媛, 贾慧, 曹志艳, 等. 2013. 玉米大斑病菌有性杂交后代的交配型与寄生适合度分化[J]. 中国农业科学, 46(19): 4058-4065.
(Guo L Y, Jia H, Cao Z Y, et al.2013. Analysis on mating type and parasitic fitness diversity in sexual hybridization offsprings of Setosphaeria turcica[J]. Scientia Agricultura Sinica, 46(19): 4058-4065.)
[8] 秦旭升, 刘学敏, 周艳玲, 等. 2000. 植物病原真菌中DNA分子鉴定技术[J]. 植物生理学通讯, 36(4): 342-347.
(Qin X S, Liu X M, Zhou Y L, et al.2000. DNA molecular marker technique of phytopathogenic fungi[J]. Plant Physiology Communications, 36(4): 342-347.)
[9] 唐启义. 2010. DPS数据处理系统: 实验设计、统计分析及数据挖掘(第二版)[M]. 科学出版社, 北京. pp. 19-371.
(Tang Q Y.DPS Data Processing System: Experimental Design, Statistical Analysis and Data Mining (2nd Ed)[M]. Science Press, Beijing. pp. 19-371.)
[10] 王萌, 陈小莉, 赵磊, 等. 2016. 海南芒果蒂腐病可可球二孢抗药性及遗传多样性分析[J]. 热带作物学报, 37(7): 1363-1369.
(Wang M, Chen X L, Zhao L, et al.2016. Fungicide-resistance and genetic diversity of Botryodiplodia theobromae from mango causing stem-end rots in fruits in Hainan[J]. Chinese Journal of Tropical Crops, 37(7): 1363-1369.)
[11] 王晓鸣, 晋齐鸣, 石洁, 等. 2006. 玉米病害发生现状与推广品种抗性对未来病害发展的影响[J]. 植物病理学报, 36(1): 1-11.
(Wang X M, Jin Q M, Shi J, et al.2006. The status of maize diseases and the possible effect of variety resistance on disease occurrence in the future[J]. Acta Phytopathologica Sinica, 36(1): 1-11.)
[12] 肖明纲, 宋凤景, 孙兵, 等. 2018. 玉米大斑病广谱抗性外引自交系的发掘与抗病基因初步鉴定[J]. 作物学报, 44(4): 614-619.
(Xiao M G, Song F J, Sun B, et al.2018. Exploration of foreign maize inbred lines with broad spectrum resistance to northern corn leaf blight and preliminary identification of resistance genes[J]. Acta Agronomica Sinica, 44(4): 614-619.)
[13] 杨凤珍, 郭建国, 杜蕙, 等. 2016. 甘肃玉米大斑病菌对吡唑醚菌酯的敏感性监测分析[J]. 西北农业学报, 25(10): 1548-1553.
(Yang F Z, Guo J G, Du H, et al.2016. Monitoring and analyzing sensitivity of Setosphaeria turcica to pyraclostrobin in Gansu[J]. Acta Agriculturae Boreali-occidentalis Sinica, 25(10): 1548-1553.)
[14] Borchardt D S, Welz H G, Geiger H H.1998. Genetic structure of Setosphaeria turcica populations in tropical and temperate climates[J]. Phytopathology, 88(4): 322-329.
[15] Campbell S E, Brannen P M, Scherm H, et al.2021. Efficacy of fungicide treatments for Plasmopara viticola control and occurrence of strobilurin field resistance in vineyards in Georgia, USA[J]. Crop Protection, 139: 105371.
[16] Castroagudín V L, Ceresini P C, De Oliveira S C, et al.2015. Resistance to QoI fungicides is widespread in Brazilian populations of the wheat blast pathogen Magnaporthe oryzae[J]. Phytopathology, 105(3): 284-294.
[17] Chitolina G M, Silva-Junior G J, Feichtenberger E, et al.2021. Distribution of alternaria alternata isolates with resistance to quinine outside inhibitor (QoI) fungicides in Brazilian orchards of tangerines and their hybrids[J]. Crop Protection, 141: 105493.
[18] Cui L, Deng J, Zhao L, et al.2022. Genetic diversity and population genetic structure of Setosphaeria turcica from sorghum in three provinces of China using single nucleotide polymorphism markers[J]. Frontiers in Microbiology, 13: 853202.
[19] Dowling M E, Bryson P K, Boatwright H G, et al.2016. Effect of fungicide applications on Monilinia fructicola population diversity and transposon movement[J]. Phytopathology, 106(12): 1504-1512.
[20] Earl D A, Vonholdt B M.2012. STRUCTURE HARVESTER: A website and program for visualizing STRUCTURE output and implementing the Evanno method[J]. Conservation Genetics Resources, 4(2): 359-361.
[21] Evanno G, Regnaut S, Goudet J.2005. Detecting the number of clusters of individuals using the software STRUCTURE: A simulation study[J]. Molecular Ecology, 14(8): 2611-2620.
[22] Fungicide Resistance Action Committee (FRAC). 2022. FRAC Code List 2022: Fungal control agents sorted by cross-resistance pattern and mode of action (including coding for FRAC Groups on product labels)[M]. FRAC, Basel. pp. 1-17. https://www.frac.info/knowledge-database/downloads.
[23] Grünwald N J, Goodwin S B, Milgroom M G, et al.2003. Analysis of genotypic diversity data for populations of microorganisms[J]. Phytopathology, 93(6): 738-746.
[24] Human M P, Barnes I, Craven M, et al.2016. Lack of population structure and mixed reproduction modes in Exserohilum turcicum from South Africa[J]. Phytopathology, 106(11): 1386-1392.
[25] Jindal K K, Tenuta A U, Woldemariam T, et al.2019. Occurrence and distribution of physiological races of Exserohilum turcicum in Ontario, Canada[J]. Plant Disease, 103(7): 1450-1457.
[26] Kaur N, Mullins C, Kleczewski N M, et al.2021. Occurrence of quinone outside inhibitor resistance in Virginia populations of Parastagonospora nodorum infecting wheat[J]. Plant Disease, 105(6): 1837-1842.
[27] Li X, Li C, Li G, et al.2021. Detection of a point mutation (G143A) in Cyt b of Corynespora cassiicola that confers pyraclostrobin resistance[J]. Horticulturae, 7: 155.
[28] Li Y G, Jiang W Y, Zhang Q F, et al.2019. Population structure and genetic diversity of Setosphaeria turcica from corn in Heilongjiang province, China[J]. Journal of Applied Microbiology, 127(6): 1814-1823.
[29] Ma Z J, Liu B, He S D, et al.2020. Analysis of physiological races and genetic diversity of Setosphaeria turcica (Luttr.) K.J. Leonard & Suggs from different regions of China[J]. Canadian Journal of Plant Pathology, 42(3): 396-407.
[30] Mcdermott J M, Mcdonald B A.1993. Gene flow in plant pathosystems[J]. Annual Review of Phytopathology, 31: 353-373.
[31] Navarro B L, Hanekamp H, Koopmann B, et al.2020. Diversity of expression types of Ht genes conferring resistance in maize to Exserohilum turcicum[J]. Frontiers in Plant Science, 11: 607850.
[32] Nieuwoudt A, Human M P, Craven M, et al.2018. Genetic differentiation in populations of Exserohilum turcicum from maize and sorghum in South Africa[J]. Plant Pathology, 67(7): 1483-1491.
[33] Peakall J K, Smouse P T.2012. GenAlEx 6.5: Genetic analysis in Excel. Population genetic software for teaching and research-an update[J]. Bioinformatics, 28(19): 2537-2539.
[34] Pritchard J K, Stephens M, Donnelly P.2000. Inference of population structure using multilocus genotype data[J]. Genetics, 155(2): 945-959.
[35] Tang L, Gao Z G, Yao Y, et al.2015. Identification and genetic diversity of formae speciales of Setosphaeria turcica in China[J]. Plant Disease, 99(4): 482-487.
[36] Usman H M, Tan Q, Karim M M, et al.2021. Sensitivity of Colletotrichum fructicola and Colletotrichum siamense of peach in China to multiple classes of fungicides and characterization of pyraclostrobin-resistant isolates[J]. Plant Disease, 105(11): 3459-3465.
[37] Yang Y, Dong G, Wang M, et al.2021. Multifungicide resistance profiles and biocontrol in Lasiodiplodia theobromae from mango fields[J]. Crop Protection, 145: 105611.
[38] Yeh F C, Yang R C, Boyle T B J, et al.1999. POPGENE Version 1.32, the User-friendly Software for Population Genetic Analysis[M]. University of Alberta, Edmonton. pp. 1-28.
[39] Yin Y N, Kim Y K, Xiao C L.2012. Molecular characterization of pyraclostrobin resistance and structural diversity of the cytochrome b gene in Botrytis cinerea from apple[J]. Phytopathology, 102(3): 315-322.