The correlation between cell microstructure induced by 2,3-butanediol and fungal resistance of creeping bentgrass

doi:10.11686/cyxb2017065

Abstract

Abstract: The brown spot caused by Rhizoctonia solani is one of the most common diseases of creeping bentgrass (Agrostis stolonifera) lawns. Application of 2,3-butanediol (2,3-BD ) can induce plant disease response and improve disease resistance. In the present study, creeping bentgrass was inoculated with R. solani after treatment with 2,3-BD (250 μmol/L) and then the cell microstructure of leaves was observed using a paraffin sectioning method. It was found that the disease index of creeping bentgrass without 2,3-BD reached 70.45% after 15 days from inoculation. However, the disease index of creeping bentgrass treated with 2,3-BD was significantly lower, at 21.63% (P<0.05). Compared to leaves of pathogen-infected plants untreated with 2,3-BD, creeping bentgrass leaves with both pathogen inoculation and 2,3-BD treatment had a closely arranged cell structure, smaller cavities, more papillae, and increased upper and lower epidermal cell size. The size increase of upper and lower epidermal cells of 2,3-BD induced plants, compared to uninduced plants, was a factor of 1.19 and 1.26 times, respectively, and was most significant on day 7 after inoculation. The mesophyll cell size increase was the most significant on the 15th day (×1.30). The chloroplast density 1, 7, and 15 days after inoculation was, respectively, 1.25, 1.20, and 1.24 times that of uninduced plants (P<0.05). The size of vascular bundles and ducts did not change significantly at any time, however, the degree of lignification was higher and the cortical tissue became thicker in induced plants. In conclusion, 2, 3-BD can induce resistance of creeping bentgrass to brown spot disease through change in the cell structure. There was a positive correlation between the upper and lower epidermal cell size, the mesophyll cell size, and the number of chloroplasts per cell in creeping bentgrass leaves, and the disease resistance.

LIU Xing-Ju, MA Yuan, MA Hui-Ling, ZHANG Yong-Mei, YU Qian-Qian. The correlation between cell microstructure induced by 2,3-butanediol and fungal resistance of creeping bentgrass[J]. Acta Prataculturae Sinica, 2017, 26(12): 170-178.

References

[1] Xu Z. The World Gramineae Grass. Beijing: Agricultural Science Publishing House, 1999.
徐柱. 世界禾草属志. 北京: 农业科学出版社, 1999.
[2] Guo W J, Chen P, Liu A. Turf establishment and maintenance of creeping bentgrass in South Subtropical China. Agriculture and Technology, 2004, (2): 111-114.
郭伟经, 陈平, 刘艾. 南亚热带匍匐翦股颖草坪建植与管理技术. 农业与技术, 2004, (2): 111-114.
[3] Piper C V, Coe H S. Rhizoctonia in lawns and pastures. Phytopathology, 1919, 9(1): 89-92.
[4] Smith J D, Jackson N, Woolhouse A R. Fungal Diseases of Amenity Turf Grasses. E & FN Spon Ltd., 1989.
[5] Zhou C Q, Yuan H J. The research on occurrence regularity and control technology to Rhizoctonia solani speckle diseases of turfgrasses. Agricultural Technology Extension, 2013, (7): 100.
周翠琴, 袁辉杰. 草坪立枯丝核菌褐斑病的发生规律及防治技术研究. 农技推广, 2013, (7): 100.
[6] Chen H B. Effect of several fungicides on Pythium diseases of turfgrasses. Grassland and Turf, 2009, (2): 17-20.
陈海波. 几种杀菌剂对草坪草腐霉枯萎病的防治试验. 草原与草坪, 2009, (2): 17-20.
[7] Mu H T R, Wang R, Liu R T, et al . Use of carbendazim to control Pythium diseases of turfgrasses. Grassland and Turf, 2000, (2): 22-25.
穆合塔尔, 王瑞, 刘荣堂, 等. 多菌灵防治草坪草腐霉枯萎病的研究. 草原与草坪, 2000, (2): 22-25.
[8] Luo L Y. The research progress and application prospect of plant induced disease resistance. Agricultural Technical Services, 2012, 29(2): 175-177.
罗来银. 植物诱导抗病性研究进展及其应用前景. 农技服务, 2012, 29(2): 175-177.
[9] Suzuki S, He Y, Oyaizu H. Indole-3-acetic acid production in Pseudomonas fluorescens HP72 and its association with suppression of creeping bentgrass brown patch. Current Microbiology, 2003, 47: 138-143.
[10] Ryu C, Farag M, Hu C, et al . Bacterial volatiles inducesystemic resistance in Arabidopsis . Plant Physiology, 2004, 134: 1017-1026.
[11] Cortes-Barco A M, Hsiang T, Goodwin P H. Induced systemic resistance against three foliar diseases of Agrostis stolonifera by (2R, 3R)-Butanediol or an isoparaffin mixture. Annals of Applied Biology Plant Pathology, 2010, 157: 179-189.
[12] Ma X, Ma H L, Yao T, et al . Butanediol induced disease resistant against brown spot in creeping bentgrass. Journal of Gansu Agricultural University, 2011, 46(6): 77-80.
马祥, 马晖玲, 姚拓, 等. 新型诱导剂丁二醇对匍匐翦股颖抗病性诱导的研究. 甘肃农业大学学报, 2011, 46(6): 77-80.
[13] Ma X, Ma H L, An H H, et al . Effects on defense-related enzyme activity in creeping bentgrass with inducer butanediol. Grassland and Turf, 2012, 32(3): 37-42, 48.
马祥, 马晖玲, 安惠惠, 等. 诱导剂丁二醇对匍匐翦股颖抗病相关的防卫酶活性的影响. 草原与草坪, 2012, 32(3): 37-42, 48.
[14] Nan Z B. Grass diseases investigation and evaluation//Ren J Z. The Methods of Grassland Science Rerearch. Beijing: China Agriculture Press, 1998: 214-236.
南志标. 牧草病害的调查与评定//任继周.草业科学研究方法. 北京: 中国农业版社, 1998: 214-236.
[15] Li M. Study on the leaf tissue structure of kiwifruit cultivars in relation to bacterial canker disease resistance. Journal of Anhui Agricultural Sciences, 2002, 30(5): 740-742.
李淼. 猕猴桃品种叶片组织结构与抗溃疡病的关系. 安徽农业科学, 2002, 30(5): 740-742.
[16] Si L T, Tian L B. Relationship between the leaf structure of bitter melon and resistance to powdery mildew. Acta Botanica Boreali-Occidentalia Sinica, 2013, 33(10): 2010-2015.
司龙亭, 田丽波. 苦瓜叶片结构与白粉病抗性的关系. 西北植物学报,2013, 33(10): 2010-2015.
[17] Zhang Z K. Preharvest BTH Treatment Induces Resistance in Fruit of Muskmelon. Lanzhou: Gansu Agricultural University, 2006.
张正科. 采用BTH处理对厚皮甜瓜的抗病性诱导. 兰州: 甘肃农业大学, 2006.
[18] Li M. Effect of BTH or Harpin Treatment on Latent Infection in Muskmelons ( Cucumis melon L.). Lanzhou: Gansu Agricultural University, 2005.
李梅. 采前 BTH 或 Harpin 处理对“银帝”甜瓜潜伏侵染的影响. 兰州: 甘肃农业大学, 2005.
[19] Wang L F. Physiology Mechanism and the Ultrastructure Studies on the Resistance to Sunflower Rust. Hohhot: Inner Mongolia Agricultural University, 2008.
王丽芳. 向日葵抗锈病生理机制及超微结构的研究. 呼和浩特: 内蒙古农业大学, 2008.
[20] Wei L Z. Effects of Antioxidant Enzyme System and Mesophyll Cell Structure on Seeding Leaf of Chinese Cabbage During the Infection of Black Rot. Yangling: North West Agriculture and Forestry University, 2009.
蔚丽珍. 黑腐病侵染对大白菜幼苗叶片抗氧化酶系统和叶肉细胞结构的影响. 杨凌: 西北农林科技大学, 2009.
[21] Bi J X, Yu D D. The research of wheat powdery mildew resistance. Journal of Anhui Agriculture Science, 2008, 36(28): 12320-12321, 12384.
毕建秀, 于冬冬. 小麦白粉病抗性研究. 安徽农业科学, 2008, 36(28): 12320-12321, 12384.
[22] Liu J, Liu J F, Zeng Y, et al . The morphological structure of host plant disease resistance. Journal of Sichuan Forestry Science and Technology, 2001, 22(3): 54-56.
刘进, 刘建锋, 曾义, 等. 寄主植物的形态结构抗病性. 四川林业科技, 2001, 22(3): 54-56.
[23] Chen Z, Xu B L. Relationship between chlorophyll and resistance to leaf blight of turfgrass. Grassland and Turf, 2005, 109(2): 59-61.
陈臻, 徐秉良. 叶绿素含量与草坪草对叶枯病抗病性的关系. 草原与草坪, 2005, 109(2): 59-61.
[24] Wang C M, Du H. Effects of leaf chlorophyll mass fraction on grape cultivar resistance to Plasmopara viticola . Acta Agriculturae Boreali-Occidentalis Sinica, 2016, 25(3): 458-464.
王春明, 杜蕙. 葡萄叶片叶绿素质量分数与其霜霉病抗性的关系. 西北农业学报, 2016, 25(3): 458-464.
[25] Xu B L, Yan H X. Effects of chlorophyll content and stoma density on pumpkin resistance to Powdery mildew. Plant Protection, 2009, 35(1): 79-81.
徐秉良, 颜惠霞. 南瓜品种对白粉病的抗病性与叶绿素含量和气孔密度的相关性. 植物保护, 2009, 35(1): 79-81.