Scientia Agricultura Sinica ›› 2019, Vol. 52 ›› Issue (2): 262-272.doi: 10.3864/j.issn.0578-1752.2019.02.006

• PLANT PROTECTION • Previous Articles     Next Articles

Analysis of Main Pathogens and Dominant Species of Maize Stalk Rot in the Main Summer Maize Producing reas of Huang-Huai-Hai

LIU ShuSen,MA HongXia,GUO Ning,SHI Jie(),ZHANG HaiJian,SUN Hua,JIN Ge   

  1. Plant Protection Institute, Hebei Academy of Agricultural and Forestry Sciences/Key Laboratory of IPM on Crops in Northern Region of North China, Ministry of Agriculture/IPM Centre of Hebei Province, Baoding 071000, Hebei
  • Received:2018-09-04 Accepted:2018-11-23 Online:2019-01-16 Published:2019-01-21
  • Contact: Jie SHI E-mail:shij99@163.com

Abstract:

【Objective】 The objective of this study is to determine the main pathogens and dominant species of maize stalk rot in the main summer maize producing areas of Huang-Huai-Hai, and to provide a basis for understanding the pathogenic mechanism, resistant breeding, and ultimately maize stalk rot management.【Method】 In 2014-2017, 850 samples of maize stalk rot were collected from three provinces (Hebei, Henan and Shandong) in the main summer maize producing areas of Huang-Huai-Hai. The isolated fungi or oomycetes were morphologically characterized and confirmed by using universal and specific primers, those primers were also used for detecting pathogens in diseased tissues. The combined results of isolate identification and tissue molecular detection were analyzed to determine the main pathogens and the dominant species. The detection rates of main pathogens in different provinces and different years of the same province were analyzed to reveal the population dynamics. The detection rates of pathogens in individual samples were also analyzed to determine the coexistence patterns of multiple pathogens.【Result】 Fungi or oomycetes were detected in 667 samples, accounting for 78.47% of all samples. The detection rates were different among years, less than 50% in 2014 and more than 90% in 2015-2017. Detected fungi or oomycetes were classified to 46 species of 20 genera. Fusarium spp. had the highest detection rate of 89.96%, including F. graminearum species complex, F. proliferatum, F. verticillioides, F. chlamydosporum, F. subglutinans, F. oxysporum, F. culmorum, F. fujikuroi, F. incarnatum, F. equiseti and F. solani. In addition, Pythium spp. had the second highest detection rate of 34.18%, including P. aristosporum, P. graminicola, P. acanthicum, P. amasculinum and P. oligandrum. The detection rates of four main pathogens, F. verticillioides, F. graminearum species complex, P. aristosporum and F. proliferatum, were 62.07%, 46.93%, 29.09% and 28.04%, respectively. It indicated that the dominant species was F. verticillioides. There were some differences in the detection rates of the four main pathogens among provinces. The detection rate of F. verticillioides in Hebei Province was 73.98%, which was significantly higher than that in Henan and Shandong Provinces, and the detection rates of F. graminearum species complex in the three provinces were similar. The detection rates of F. proliferatum and P. aristosporum in Shandong Province were 35.78% and 34.31%, respectively, which were higher than those in other two provinces. The detection rates of the four main pathogens from the same province were dynamic in different years, and any one of them can be the dominant species. Furthermore, several pathogens could be detected in a single sample. While 38.38% samples were colonized by only one pathogen, 29.24% and 19.04% samples were colonized by two and three pathogens. The patterns of two or multiple pathogens in single samples were mainly coexistence of Fusarium spp. and Pythium spp., or coexistence of Fusarium spp. and Fusarium spp..【Conclusion】 The main pathogens of maize stalk rot in the main summer maize producing areas of Huang-Huai-Hai are F. verticillioides, F. graminearum species complex, P. aristosporum and F. proliferatum, and the dominant species is F. verticillioides. The detection rate of F. verticillioides in Hebei Province and that of F. proliferatum and P. aristosporum in Shandong Province are the highest, and the detection rate of F. graminearum species complex in the three provinces is similar. There is a coexistence pattern of two or multiple pathogens in a single sample.

Key words: maize stalk rot, Huang-Huai-Hai region, pathogen detection, dominant species, Fusarium spp., Pythium spp.

Table 1

Primer pairs used in this study"

引物Primer 引物序列
Primer sequence (5′-3′)
靶标菌
Target
产物大小
Product size (bp)
退火温度
Annealing temperature (℃)
参考文献
Reference
Fg16NF ACAGATGACAAGATTCAGGCACA 禾谷镰孢复合种
F. graminearum species complex
280 57 [29]
Fg16NR TTCTTTGACATCTGTTCAACCCA
PRO1 CTTTCCGCCAAGTTTCTTC 层出镰孢
F. proliferatum
588 56 [30]
PRO2 TGTCAGTAACTCGACGTTGTTG
VER1 CTTCCTGCGATGTTTCTCC 拟轮枝镰孢
F. verticillioides
578 57 [30]
VER2 AATTGGCCATTGGTATTATATATCTA
Fc01F ATGGTGAACTCGTCGTGGC 黄色镰孢
F. culmorum
570 59 [29]
Fc01R CCCTTCTTACGCCAATCTCG
SUB1 CTGTCGCTAACCTCTTTATCCA 亚粘团镰孢
F. subglutinans
631 56 [31]
SUB2 CAGTATGGACGTTGGTATTATATCTAA
FOF1 ACATACCACTTGTTGCCTCG 尖镰孢
F. oxysporum
340 58 [32]
FOR1 CGCCAATCAATTTGAGGAACG
FEF1 CATACCTATACGTTGCCTCG 木贼镰孢
F. equiseti
389 58 [32]
FER1 TTACCAGTAACGAGGTGTATG
DC6 GAGGGACTTTTGGGTAATCA 卵菌
Oomycota
1100 58 [33]
ITS4 TCCTCCGCTTATTGATATGC
EF-1 ATGGGTAAGGARGACAAGAC 镰孢菌
Fusarium
700 54 [34]
EF-2 GGARGTACCAGTSATCATGTT
ITS1 TCCGTAGGTGAACCTGCGG 真菌通用引物
Universal primer for fungus
550 57 [35]
ITS4 TCCTCCGCTTATTGATATGC
EF-1F CATCGAGAAGTTCGAGAAGG 真菌通用引物
Universal primer for fungus
300 58 [36]
EF-1R TACTTGAAGGAACCCTTACC

Table 2

Detection rate of fungi or oomycetes in samples"


Genus

Species
组织分子检测
Tissue molecular detection
分离物鉴定法
Isolate identification
种检出率
Detection rate of species
(%)
属检出率
Detection rate of genus
(%)
检出真菌或卵菌的样本数
Number of samples infected with fungi or oomycetes
检出率
Detection
rate (%)
检出真菌或卵菌的样本数
Number of samples infected with fungi or oomycetes
检出率Detection rate (%)
镰孢属
Fusarium
禾谷镰孢复合种
F. graminearum species complex
264 39.58 141 21.08 46.93 89.96
层出镰孢 F. proliferatum 155 23.24 64 9.53 28.04
拟轮枝镰孢 F. verticillioides 380 56.97 152 22.81 62.07
厚垣镰孢 F. chlamydosporum 1 0.15 22 3.30 3.45
亚粘团镰孢 F. subglutinans 7 1.05 0 0 1.05
尖镰孢 F. oxysporum 32 4.80 1 0.15 4.95
黄色镰孢 F. culmorum 26 3.90 0 0 3.90
藤仓镰孢 F. fujikuroi 3 0.45 3 0.45 0.90
变红镰孢 F. incamatum 0 0 12 1.80 1.80
木贼镰孢 F. equiseti 6 0.90 5 0.76 1.50
茄镰孢 F. solani 0 0 1 0.15 0.15
腐霉属
Pythium
芒孢腐霉 P. aristosporum 169 25.34 23 3.40 29.09 34.18
禾生腐霉 P. graminicola 9 1.35 3 0.45 1.20
棘腐霉 P. acanthicum 1 0.15 0 0 0.15
孤雌腐霉P. amasculinum 4 0.60 0 0 0.60
寡雄腐霉 P. oligandrum 4 0.60 0 0 0.60
链格孢属
Alternaria
互隔交链格孢 A. alternate 9 1.35 12 1.80 1.80 2.10
细极链格孢 A. tenuissima 1 0.15 2 0.30 0.30
曲霉属
Aspergillus
黄曲霉 A. flavus 5 0.75 7 1.05 1.05 1.20
米曲霉 A. oryzae 0 0 1 0.15 0.15
枝顶孢霉属
Acremonium
A. zeae 0 0 1 0.15 0.15 0.15
平脐蠕孢属Bipolaris 玉蜀黍离蠕孢B. maydis 0 0 1 0.15 0.15 0.30
麦根腐平脐蠕孢B. sorokiniana 1 0.15 1 0.15 0.15
旋孢腔菌属Cochliobolus 异旋孢腔菌C. heterostrophus 1 0.15 1 0.15 0.15 0.15
枝孢霉属Cladosporium 芽枝状枝孢C. cladosporioides 1 0.15 15 2.25 2.25 2.25
突脐蠕孢属Exserohilum 喙突脐蠕孢E. rostratum 0 0 35 5.25 5.25 5.25
附球孢属Epicoccum 黑附球菌E. nigrum 0 0 1 0.15 0.15 0.15
地霉属Geotrichum 白地霉G. candidum 0 0 2 0.30 0.30 0.30
粘帚霉属Gliocladium 粉红粘帚霉G. roseum 0 0 2 0.30 0.30 0.30

Genus

Species
组织分子检测
Tissue molecular detection
分离物鉴定法
Isolate identification
种检出率
Detection rate of species
(%)
属检出率
Detection rate of genus
(%)
检出真菌或卵菌的样本数
Number of samples infected with fungi or oomycetes
检出率
Detection
rate (%)
检出真菌或卵菌的样本数
Number of samples infected with fungi or oomycetes
检出率Detection rate (%)
漆斑菌属Myrothecium 包围漆斑菌M. cinctum 0 0 2 0.30 0.30 0.30
壳球孢属Macrophomina 菜豆壳球孢M. phaseolina 0 0 1 0.15 0.15 0.15
黑孢霉属
Nigrospora
N. osmanthi 0 0 1 0.15 0.15 4.20
穗黑孢霉N. oryzae 0 0 25 3.75 3.75
球黑孢霉N. sphaerica 0 0 2 0.30 0.30
青霉属
Penicillium
草酸青霉P. oxalicum 3 0.45 15 2.25 2.25 3.60
微紫青霉P. janthinellum 0 0 1 0.15 0.15
产紫青霉P. purpureogenum 0 0 4 0.60 0.60
绳状青霉P. funiculosum 0 0 4 0.60 0.60
丝核菌属
Rhizoctonia.
立枯丝核菌R. solani 0 0 3 0.45 0.45 0.45
木霉属
Trichoderma
棘孢木霉T. asperellum 0 0 3 0.45 0.45 5.70
非洲哈茨木霉T. afroharzianum 0 0 7 1.05 1.05
哈茨木霉T. harzianum 1 0.15 26 3.90 3.90
钩状木霉T. hamatum 0 0 1 0.15 0.15
盖姆斯木霉T. gamsii 0 0 1 0.15 0.15
毛霉属Mucor 未知种Unknown species 0 0 4 0.60 0.60 0.60
盾壳霉属Coniothyrium 未知种Unknown species 0 0 1 0.15 0.15 0.15

Table 3

Detection rate of main pathogens in different provinces"

省份
Province
检出真菌或卵菌的样本数
Number of samples infected with fungi or oomycetes
检出率Detection rate (%)
拟轮枝镰孢
F. verticillioides
禾谷镰孢复合种
F. graminearum species complex
层出镰孢
F. proliferatum
芒孢腐霉
P. aristosporum
河北Hebei 123 73.98 45.53 21.95 17.89
河南Henan 340 60.59 48.24 25.59 30.00
山东Shandong 204 57.35 45.59 35.78 34.31

Table 4

Detection rate of main pathogens in different years"

省份
Province
年份
Year
检出真菌或卵菌的样本数
Number of samples infected with fungi or oomycetes
检出率Detection rate (%)
拟轮枝镰孢
F. verticillioides
禾谷镰孢复合种
F. graminearum species complex
层出镰孢
F. proliferatum
芒孢腐霉
P. aristosporum
河北
Hebei
2014 24 41.67 29.17 0 4.17
2015 9 55.56 44.44 11.11 44.44
2016 35 68.57 48.57 34.29 22.86
2017 55 94.55 50.91 25.45 16.36
河南
Henan
2014 52 13.46 40.38 0 59.62
2015 92 51.09 58.70 3.26 25.00
2016 104 73.08 54.81 48.08 16.35
2017 92 82.61 34.78 36.96 33.70
山东
Shandong
2014 52 30.77 9.62 11.54 40.38
2015 52 44.23 55.77 46.15 28.85
2016 35 68.57 45.71 45.71 25.71
2017 65 83.08 66.15 41.54 38.46

Table 5

Percentage of samples infected with multiple fungi or oomycetes species"

年份
Year
检出真菌或卵菌的样本数
Number of samples infected
with fungi or oomycetes
真菌或卵菌种数及样本比例
Number of species of fungi or oomycetes and percentage of sample (%)
1 2 3 4 ≥5
2014 128 77.34 18.75 3.13 0.78 0
2015 153 29.41 39.87 20.26 7.84 2.61
2016 174 36.21 25.86 24.14 12.07 1.72
2017 212 23.11 30.66 23.58 11.79 10.85
总计Total 667 38.38 29.24 19.04 8.85 4.50

Table 6

Coexistence pattern of Fusarium spp. and Pythium spp. in a single sample"

年份
Year
检出真菌或卵菌的样本数
Number of samples infected with fungi or oomycetes
镰孢菌和腐霉菌共存模式及样本比例 Coexistence pattern of F. spp. and P. spp. and percentage of samples (%)
F. spp. P. spp. Other F. spp.+
F. spp
P. spp.+
P. spp.
F. spp.+
P. spp.
F. spp.+ Other P. spp.+ Other Other + Other
2014 128 40.63 24.22 12.50 2.34 0 15.63 0.78 3.13 0.78
2015 153 21.57 3.27 4.58 22.22 0 24.84 20.92 1.96 0.65
2016 174 30.46 1.15 4.60 31.61 0 23.56 8.62 0 0
2017 212 19.81 0.94 2.36 30.19 0 29.72 15.57 1.42 0
总计Total 667 26.99 6.00 5.40 23.39 0 24.29 12.14 1.50 0.30
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