稻、麦纹枯病菌对井岗霉素的敏感性及其影响因素的研究
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摘要
检测了江苏省13个市56个县(市)的160株小麦纹枯病菌(Rhizoctonia
cerealis)、9个市16个县(市)的51株水稻纹枯病菌(R.solani)对井岗霉素的敏感性,并研究了影响病菌敏感性的营养、物理及化学等各种因子。
通过田间用药分离菌株与野生敏感菌株对井岗霉素的敏感性比较以及敏感性频率分布研究表明:江苏省小麦纹枯病菌对井岗霉素未产生抗药性,井岗霉素仍然是防治小麦纹枯病的高效、低毒、经济的主要药剂;水稻纹枯病菌中部分AG_(1-1A)菌株对井岗霉素已产生抗药性,田间出现了低抗、中抗菌株。禾谷丝核菌对井岗霉素的敏感性要高于立枯丝核菌;同时,两种丝核菌的不同菌丝融合群对药剂的敏感性也有差异。
通过以野生敏感菌株的敏感性(EC_(50))与菌株敏感性频率分布图的方法来确立菌株敏感性基线,这两种方法确定的敏感性基线值略有不同,但差异不大。同时,按这两种方法进行稻、麦纹枯病菌对井岗霉素抗药性监测的结果相一致。因此认为,作菌株敏感性频率分布图的方法确立敏感性基线可能更为合适。
不同氮磷钾水平下稻、麦纹枯病菌对井岗霉素的敏感性不同。室内试验表明,增加氮含量,井岗霉素对稻、麦纹枯病菌的抑制率显著下降;增加钾含量,其抑制率显著增强。而磷含量的变化对药剂抑制率影响不大。盆栽试验表明,植株体内的不同营养元素含量对井岗霉素防治稻、麦纹枯病的效果有显著影响。增施氮肥或氮肥用量过多、植株体内含氮量高,纹枯病发生重,且井岗霉素对纹枯病的防效显著下降;增施钾肥、植株体内含钾量高,纹枯病发生轻,井岗霉素对纹枯病的防效显著增加;增施磷肥、植株体内含磷量的增加对防效的影响不显著。
温度、pH值、几种杀菌剂及除草剂的使用对井岗霉素抑制纹枯病菌的生长均有一定影响,尤其温度、pH值的影响最为显著。22℃时0.2μg/ml井岗霉素对小麦纹枯病菌的抑制率最高,与15℃、28℃时的药剂抑制率相比达显著差异;其次为
扬州大学硕士学位论文
28℃时的药剂抑制率,但与15℃时的相比差异不显著。在28℃时,0.2p岁ml井岗
霉素对水稻纹枯病菌的抑制率最高,与21℃、35℃时的相比达显著差异;21℃与
35℃时抑制率相比也不显著。pH7时井岗霉素对稻、麦纹枯病菌的抑制率最高,pHS
时次之,但二者之间差异不显著;pHg时抑制率最低,并与pHS、7时的抑制率相
比达显著差异。因此,在实验室进行菌株对药剂敏感性测定时,培养温度、培养基
pH值的控制与稳定很重要。多菌灵、三哇酮、戊哇醇等杀菌剂及精恶哇禾草灵、
氟草定、苯磺隆、乙草胺、丁草胺等除草剂均能抑制稻、麦纹枯病菌的生长;同时,
它们对井岗霉素抑制纹枯病菌的效果产生促进作用,即稻、麦纹枯病菌经这些药剂
处理后,随着处理浓度的增加,病菌对井岗霉素的敏感性则增强,而且水稻纹枯病
菌的敏感性上升趋势要明显高于小麦纹枯病菌。
160 isolates of Rhizoctonia cerealis causing sharp eye spot of wheat and 51 isolates of R. solani causing rice sheath blight collected respectively from 56 counties and 16 counties of Jiangsu Province, were detected for their sensitivity to Jinggangmycin and some nutritive, physical and chemical factors influencing the sensitivity were studied.
By comparison of the sensitivity of tested isolates to Jinggangmycin with that of wild ones and the sensitivity frequency distribution of tested isolates, R. cerealis did not develop the resistance to Jinggangmycin, which showed that Jinggangmycin was still an effective agricultural antibiotic to control sharp eye spot of wheat caused by R. cerealis. But the low and moderate resistance of some isolates of R. solani AG1-I A to Jinggangmycin was found in the field. The sensitivity of R. cerealis to Jinggangmycin was higher than that of R. solani. There were some differences in the sensitivity to the antibiotic among anastomosis groups of two pathogens.
EC50 of the wild sensitive isolate and the mean EC50 in the normal distribution of tested were used to determine the sensitive lines. There were little difference in two sensitive lines. It is considered that the method of sensitivity distribution of population was more suitable.
The concentration of nitrogen and potassium in Czapek's dox medium significantly affected the sensitivity of R. cerealis and R. solani to Jinggangmycin. The results showed that the higher concentration of nitrogen in the medium was the lower inhibition of Jinggangmycin to R. cerealis and R. solani and the higher concentration of potassium was, the higher inhibition. But the concentration of phosphorus in the medium had little influence on the inhibition of the antibiotic to two pathogenic fungi. The potted experiment indicated that the control effects of Jinggangmycin against sharp eye spot of wheat and rice sheath blight were significantly correlated to nitrogen and potassium contents of plants. The incidence of two diseases varied with nitrogen contents of plants, and higher nitrogen contents significantly reduced the control effects of Jinggangmycin
against the diseases. While higher potassium contents of plants were of benefit to reduce the incidence of two diseases and obviously increased the control effects of the antibiotic. Cultural temperature, pH value of the medium, the usage of other fungicides and herbicides, especially the temperature and pH value showed influence on the inhibition rates of Jinggangmycin to R. cerealis and R. solani. At 22 C, the inhibitory effect of the antibiotic with 0.2 g/ml Jinggangmycin to R. cerealis was the highest, which was significantly different from that at 15C or 28 C. The second was at 28 C, but the inhibition rate at 28 C was not obviously different from that at 15 C. Furthermore, the inhibition of the antibiotic with 0.2 u g/ml Jinggangmycin to R. solani at 28 C was the highest, which was significantly different from at 21 C or 35 C, but there were not significant difference in the inhibition between at 21 C and at 35 "C. When pH value of the medium was 5 to 7, the inhibition of the antibiotic was higher th
an that on the medium of pH9. Thus, the stability of cultural temperature, pH value of media was of importance to detect the sensitivity of R. cerealis and R. solani to Jinggangmycin. The fungicides and herbicides tested, such as carbendazim, triadimefon, tebuconazole, fenoxaprop-p-ethyl, fluroxypyr, tribenuron methyl, acetochor, butachlor, had some inhibitor on the pathogen and could inhibit the mycelial growth. Furthermore, these fungicides and herbicides increased the inhibitory effects of Jinggangmycin against R. cerealis and R. solani. With increase in the concentration of these chemicals, the sensitivity of the pathogens to Jinggangmycin was increased, and the sensitivity of R. solani to the antibiotic was more obviously increased than that of R. cerealis.
cerealis)、9个市16个县(市)的51株水稻纹枯病菌(R.solani)对井岗霉素的敏感性,并研究了影响病菌敏感性的营养、物理及化学等各种因子。
通过田间用药分离菌株与野生敏感菌株对井岗霉素的敏感性比较以及敏感性频率分布研究表明:江苏省小麦纹枯病菌对井岗霉素未产生抗药性,井岗霉素仍然是防治小麦纹枯病的高效、低毒、经济的主要药剂;水稻纹枯病菌中部分AG_(1-1A)菌株对井岗霉素已产生抗药性,田间出现了低抗、中抗菌株。禾谷丝核菌对井岗霉素的敏感性要高于立枯丝核菌;同时,两种丝核菌的不同菌丝融合群对药剂的敏感性也有差异。
通过以野生敏感菌株的敏感性(EC_(50))与菌株敏感性频率分布图的方法来确立菌株敏感性基线,这两种方法确定的敏感性基线值略有不同,但差异不大。同时,按这两种方法进行稻、麦纹枯病菌对井岗霉素抗药性监测的结果相一致。因此认为,作菌株敏感性频率分布图的方法确立敏感性基线可能更为合适。
不同氮磷钾水平下稻、麦纹枯病菌对井岗霉素的敏感性不同。室内试验表明,增加氮含量,井岗霉素对稻、麦纹枯病菌的抑制率显著下降;增加钾含量,其抑制率显著增强。而磷含量的变化对药剂抑制率影响不大。盆栽试验表明,植株体内的不同营养元素含量对井岗霉素防治稻、麦纹枯病的效果有显著影响。增施氮肥或氮肥用量过多、植株体内含氮量高,纹枯病发生重,且井岗霉素对纹枯病的防效显著下降;增施钾肥、植株体内含钾量高,纹枯病发生轻,井岗霉素对纹枯病的防效显著增加;增施磷肥、植株体内含磷量的增加对防效的影响不显著。
温度、pH值、几种杀菌剂及除草剂的使用对井岗霉素抑制纹枯病菌的生长均有一定影响,尤其温度、pH值的影响最为显著。22℃时0.2μg/ml井岗霉素对小麦纹枯病菌的抑制率最高,与15℃、28℃时的药剂抑制率相比达显著差异;其次为
扬州大学硕士学位论文
28℃时的药剂抑制率,但与15℃时的相比差异不显著。在28℃时,0.2p岁ml井岗
霉素对水稻纹枯病菌的抑制率最高,与21℃、35℃时的相比达显著差异;21℃与
35℃时抑制率相比也不显著。pH7时井岗霉素对稻、麦纹枯病菌的抑制率最高,pHS
时次之,但二者之间差异不显著;pHg时抑制率最低,并与pHS、7时的抑制率相
比达显著差异。因此,在实验室进行菌株对药剂敏感性测定时,培养温度、培养基
pH值的控制与稳定很重要。多菌灵、三哇酮、戊哇醇等杀菌剂及精恶哇禾草灵、
氟草定、苯磺隆、乙草胺、丁草胺等除草剂均能抑制稻、麦纹枯病菌的生长;同时,
它们对井岗霉素抑制纹枯病菌的效果产生促进作用,即稻、麦纹枯病菌经这些药剂
处理后,随着处理浓度的增加,病菌对井岗霉素的敏感性则增强,而且水稻纹枯病
菌的敏感性上升趋势要明显高于小麦纹枯病菌。
160 isolates of Rhizoctonia cerealis causing sharp eye spot of wheat and 51 isolates of R. solani causing rice sheath blight collected respectively from 56 counties and 16 counties of Jiangsu Province, were detected for their sensitivity to Jinggangmycin and some nutritive, physical and chemical factors influencing the sensitivity were studied.
By comparison of the sensitivity of tested isolates to Jinggangmycin with that of wild ones and the sensitivity frequency distribution of tested isolates, R. cerealis did not develop the resistance to Jinggangmycin, which showed that Jinggangmycin was still an effective agricultural antibiotic to control sharp eye spot of wheat caused by R. cerealis. But the low and moderate resistance of some isolates of R. solani AG1-I A to Jinggangmycin was found in the field. The sensitivity of R. cerealis to Jinggangmycin was higher than that of R. solani. There were some differences in the sensitivity to the antibiotic among anastomosis groups of two pathogens.
EC50 of the wild sensitive isolate and the mean EC50 in the normal distribution of tested were used to determine the sensitive lines. There were little difference in two sensitive lines. It is considered that the method of sensitivity distribution of population was more suitable.
The concentration of nitrogen and potassium in Czapek's dox medium significantly affected the sensitivity of R. cerealis and R. solani to Jinggangmycin. The results showed that the higher concentration of nitrogen in the medium was the lower inhibition of Jinggangmycin to R. cerealis and R. solani and the higher concentration of potassium was, the higher inhibition. But the concentration of phosphorus in the medium had little influence on the inhibition of the antibiotic to two pathogenic fungi. The potted experiment indicated that the control effects of Jinggangmycin against sharp eye spot of wheat and rice sheath blight were significantly correlated to nitrogen and potassium contents of plants. The incidence of two diseases varied with nitrogen contents of plants, and higher nitrogen contents significantly reduced the control effects of Jinggangmycin
against the diseases. While higher potassium contents of plants were of benefit to reduce the incidence of two diseases and obviously increased the control effects of the antibiotic. Cultural temperature, pH value of the medium, the usage of other fungicides and herbicides, especially the temperature and pH value showed influence on the inhibition rates of Jinggangmycin to R. cerealis and R. solani. At 22 C, the inhibitory effect of the antibiotic with 0.2 g/ml Jinggangmycin to R. cerealis was the highest, which was significantly different from that at 15C or 28 C. The second was at 28 C, but the inhibition rate at 28 C was not obviously different from that at 15 C. Furthermore, the inhibition of the antibiotic with 0.2 u g/ml Jinggangmycin to R. solani at 28 C was the highest, which was significantly different from at 21 C or 35 C, but there were not significant difference in the inhibition between at 21 C and at 35 "C. When pH value of the medium was 5 to 7, the inhibition of the antibiotic was higher th
an that on the medium of pH9. Thus, the stability of cultural temperature, pH value of media was of importance to detect the sensitivity of R. cerealis and R. solani to Jinggangmycin. The fungicides and herbicides tested, such as carbendazim, triadimefon, tebuconazole, fenoxaprop-p-ethyl, fluroxypyr, tribenuron methyl, acetochor, butachlor, had some inhibitor on the pathogen and could inhibit the mycelial growth. Furthermore, these fungicides and herbicides increased the inhibitory effects of Jinggangmycin against R. cerealis and R. solani. With increase in the concentration of these chemicals, the sensitivity of the pathogens to Jinggangmycin was increased, and the sensitivity of R. solani to the antibiotic was more obviously increased than that of R. cerealis.
引文
[1] Cromey MG, Butler RC, Boddington HJ, et al. Effects of sharp eyespot on yield of wheat in New Zealand [J]. New Zealand Journal of Crop and Horticultural Science, 2002, 30(1):9~17.
[2] 朱尔玺.小麦纹枯病危害情况的调查[J].河南农林科技,1982,12:13.
[3] 周凯南.小麦纹枯病研究初报[J].山东农业科学,1982,3:33~36.
[4] 孟庆忠 刘志恒 王鹤影等.水稻纹枯病研究进展[J].沈阳农业大学学报,2001,32(5):376~381.
[5] 吴汉章 潘以楼.小麦纹枯病的发生与药剂防治的技术关键[J].江苏农业科学,1983,11:34~37.
[6] 丁友珍.贵州小麦纹枯病病原丝核菌的初步研究[J].贵州农学院学报,1986,2:87~89.
[7] 沈素文 王裕中 史建荣等.菌龄与温度对小麦纹枯病菌致病力的影响[J].江苏农业科学,1997.6:35~37.
[8] 陈厚德 王彰明 胡广淦等.几种与小麦纹枯病相关症状初步研究[J].江苏农业科学,1993,(专辑):30~31.
[9] 刘志恒.水稻纹枯病[J].新农业,2003,9:41~42.
[10] Blair JD. Studies on growth in soil and the parasitic action of certain Rhizoctonia solani isolates from wheat [J]. Can. J. Res, 1942, 20:174~185.
[11] Bruehl GW. Rhizoctonia solani in relation to cereal crown and root rot [J]. Phytopathology, 1951,41:375~377.
[12] Parmetor JR, Sherwood RT, Platt WD. Anastomosis group of among isolates of Thanatephorus cucumeris [J]. Phytopathology, 1969, 59:1270~1278.
[13] Boerema GH, Vander Hoeven A. A. Check-list for scientific names of common parasitic fungi series 26: Fungi on field crops: cerealis and grasses [J]. Neth. J. Plant pathol., 1976,83:165~204.
[14] 陈延熙 唐文华 张敦华等.我国小麦纹枯病病原学的初步研究[J].植物保护,1986,13(1):39~44.
[15] 李清铣.江苏几种作物病原丝核菌生物学特性研究[J].江苏农学院学报,1988,9(3):23~26.
[16] 史建荣 王裕中 陈怀谷等.小麦纹枯病菌的菌丝融合群及其致病力测定[J].江苏农业科学,
1993,(专辑):25~29.
[17] 杨小军 杨立军 赵永玉等.湖北省小麦纹枯病病原菌菌丝融合群的致病力研究[J].华中农业大学学报,2000,19(2):106-110.
[18] 夏正俊 李清铣.江苏省大、小麦纹枯病病原学的初步研究[J].植物病理学报,1989,19(3):136~139.
[19] 陆家云主编.植物病害诊断[M].中国农业出版社,1995:177.
[20] 李华荣.丝核菌的菌丝融合群及其遗传多样性研究的新进展[J].菌物系统,1999,18(1):100~107.
[21] 陈延熙.关于Rhizoctonia solani菌丝融合群分类和有性世代的研究[J].植物病理学报,1985,15(3):139~142.
[22] 杜金池.关于Rhizoctonia solani之菌丝融合群及其对水稻之病原性[J].水稻病虫害,1987,12:263~285.
[23] 王裕中 杨新宁 史建荣等.麦类纹枯病防治研究Ⅰ:大、小麦及其轮作物丝核菌的生物学特性与致病力比较[J].江苏农业学报,1986,2(4):29~35.
[24] 檀根甲 季伯衡.小麦纹枯病的研究进展(综述)[J].安徽农业大学学报,1998,25(1):70~75.
[25] 江苏省麦类纹枯病综合防治研究协作组.江苏省麦类纹枯病病原学研究[J].江苏农业科学,1993,(专辑):17~24.
[26] 张敏 陶家凤.立枯丝核菌菌丝融合群培养性状比较[J].四川农业大学学报,1993,11(4):568~573.
[27] 潘以楼 吴汉章.江苏小麦纹枯病菌CAG_1群菌株的特性和致病力分化[J].江苏农业科学,1993,(专辑):35~39.
[28] 李华荣 颜思齐.四川省东、南部稻区水稻纹枯病菌系研究[J].真菌学报,1990,9(1):41~49.
[29] 邓先明.四川省西、北部稻区水稻纹枯病菌系研究[J].西南农业大学学报,1991,13(4):380~383.
[30] 王裕中 吴志凤 史建荣等.江苏省小麦纹枯病发生规律与病害消长因素分析[J].植物保护学报,1994,22(2):109~114.
[31] 李华荣.小麦纹枯病病情消长与气象因子研究[J].西南农业大学学报,1993,15(3):247~249.
[32] 路兴波.小麦品种抗纹枯病鉴定[J].植物保护学报,1999,26(3):283~284.
[33] 郑重.国外水稻纹枯病研究进展[J].植物保护,1992,16(2):52~53.
[34] 李清歌.小麦纹枯病发生与栽培因素关系调查[J].河南农业科学,1993,10:22.
[35] 刘文娟 任寿美 金志高.泰县小麦纹枯病发生规律研究[J].江苏农业科学,1993,(专辑):57~59.
[36] Musthafa K, Potty N.N. Incidence of pests and diseases in rice as influenced by fertilizer application and in situ green manuring [J]. Journal of Tropical Agriculture, 2001, 39(2):194~196.
[37] 刘述英 杨幼平 张晓平.小麦纹枯病发生规律及综合防治[J].四川农业科技,1997,3:18~19.
[38] 万有莲 付春坤 章永发.水稻纹枯病发生与防治[J].云南农业,1997,6:16.
[39] Roy AK. Indian Phytopathology, 1985, 38: 45~49.
[40] Laha GS, Venkataraman S. Sheath blight management in rice with biocontrol agents [J]. Indian Phytopathology, 2001, 54(4):461~464.
[41] 王金生 张学君 李洪连等.小麦纹枯病生防菌株B_3产生抗菌物质条件的研究[J].南京农业大学学报,1995,1(26):45~48.
[42] 赵洪义 郭凤芝.小麦纹枯病发生规律和防治技术[J].河南农业科学.1998,1:12~14.
[43] 史建荣 王裕中 陈怀谷等.戊唑醇种子处理防治小麦纹枯病[J].植物保护学报,2000,27(3):231~237.
[44] 史建荣.粉锈宁、利克菌等农药拌种防治小麦纹枯病试验初报[J].江苏农业科学,1989,8:15~16.
[45] 魏先锋.小麦纹枯病药剂防治试验初报[J].江苏农业科学,1989,4:24~25.
[46] 吴洵耻 高士仁.我国小麦纹枯病发生及防治研究现状[J].山东农业科学,1992,2:29~30.
[47] 吕国强 乔清建 丁存.小麦中后期综合施药技术[J].河南科技,1994,3:10.
[48] 潘以楼 张郭阳.稀唑醇拌种对大、小麦纹枯病防效[J].农药,1990,29(1):56~57.
[49] 王裕中.小麦纹枯病的发生与防治[J].植保技术推广,2001,21(8):39~41.
[50] Davis J.R. Sensitivity of sharp eyespot on wheat and Rhizoctonia cerealis to fungicide [J]. Test of agrochemicals and cultivars of aab., 1983, 102(4): 54~55.
[51] Marsh, U. H.W. Evaluation of fungicides for the control of sharp eyespot infection of wheat [J]. Test of agrochemicals and cultivars of aab., 1984, 104(5):46~47.
[52] Barnes, G.N. Control of eyespot with formulations of prochloraze and carbendazim, Med Fec [J]. Land-bouww, Rijksuniv Gent, 1983, 48(3):559~564.
[53] Dekker J. Bacterial plant disease control fungicides [J]. World Review of Pest Control, 1971, 10:9~23.
[54] 吴军林 林炜铁 彭运平等.防治植物病害的农用抗生素研究及应用[J].新农药,2003,4:27~30.
[55] 沈寅初.农用抗生素研究开发的新进展[J].国外医药抗生素分册,1998,19(2):155~160.
[56] 沈寅初.井岗霉素研究开发25年[J].植物保护,1996,22(4):44~45.
[57] 田中信号.抗菌素的作用机制[M].《抗菌素的作用机制》翻译组译.1977,北京:科学出版社.
[58] Trinci A.P.J. Effect of Validamycin A and L-sorbose on the growth and morphology of Rhizoctonia cerealis and Rhizoctonia solani [J]. Exp-Mycol, 1985, 9(1):20~27.
[59] Endo T, Matsuura K, Wakae O. Effect of Validamycin A on infection of Rhizoctonia solani in rice sheaths [J]. Ann Phytopathol Soc Jap, 1983, 49(5):689~697.
[60] Robson GD, Kuhn PJ, Trinci APJ. Effects of Validamycin A on the morphology, growth and sporulation of Rhizoctonia cerealis, Fusarium culmorum and other fungi [J]. J-Gen-Microbiol,Society for General Microbiology, 1988, 134(12):3187~3194.
[61] Hugh D. Sisler. Control of fungal diseases by compounds acting as antipenetrants [J]. Crop Protection, 1986, 5(5):306~313.
[62] 谢彦洁 张君成 陈育新等.多菌灵和井岗霉素对香蕉苗纹枯病的作用方式测定[J].广西植保,1999,12(2):2~4.
[63] 张穗 郭永霞 唐文华等.井岗霉素A对水稻纹枯病菌的毒力和作用机理研究[J].农药学学报,2001,3:31~37.
[64] Naoki Asano, Katsuhiko latsui, Satosi Takeda, et al. Microbial preparation of α,α'-[1, 1'-~(13)C] trehalose [J]. Carbohydrate Research, 1993,243(1):71~78.
[65] Muller J, Boller T, Wiemken A. Effects of Validamycin A, a potent trehalase inhibitor, and phytohormones on trehalose metabolism in roots and root nodules of soybean and cowpea [J]. Planta,1995, 197(2): 362~368.
[66] Wake O. First Intersect. Comgr[J]. IAMS, Sci Counc. Jap, 1975, 3: 65~67.
[67] 黄昌华 杨丹 姚学英.井岗霉素——不易产生抗性的抗菌素[J].湖北植保,1994,2:18~19.
[68] Dekker J. Development of resistance to agricultural antibiotic [J]. Fungicide Resistance in Crop Protection, 1982: 269~275.
[69] Miura H. Mode of occurance of Kasugamycin resistant rice blast fungus [J]. Ann, Phytopathol. Soc. Jpn, 1976, 41:117~123.
[70] Schroth MN. Streptomycin resistance in Erwinia amylovora [J]. Plant Path, 1978, 4: 527.
[71] Wolfe MS. Dynamics of the response of barley mildew to the use of sterol synthesis inhibitors [J]. EPPO Bull, 1985, 15: 451~457.
[72] 杨勤作.井岗霉素施药量已明显增加[J].农药通讯,1983,46(10):2.
[73] 周明国 叶钟音 刘经芬.稻纹枯病菌对井岗霉素抗药性检测、监测和诱导[J].中国水稻科学,1991,5(2):73~78.
[74] 周明国 叶钟音 刘经芬.杀菌剂抗性研究进展[J].南京农业大学学报,1994,17(3):33~41.
[75] 金梅松 蒋文烈.浙江省水稻纹枯病菌对井岗霉素的抗药性测定[J].浙江农业学报,1997,9(3):127~130.
[76] 张穗 周梅先.河南省固始等地稻纹枯病菌对井岗霉素的敏感性[J].植物保护学报,1999,26(2):189~190.
[77] 张穗 许文霞 薛银根等.郑州郊区水稻纹枯病菌对井岗霉素敏感性的初步研究[J].中国生物防治,1995,11(4):171~173.
[78] 沈永安 王力.吉林省水稻纹枯病发生与防治研究初报[J].吉林农业科学,1989,3:9~14.
[79] 史建荣 王裕中.三唑酮、三唑醇和井岗霉素对小麦纹枯病菌生长和侵染的影响[J].江苏农业科学,1993,(专辑):173~175.
[80] 刘经芬 周明国 叶钟音.江苏小麦纹枯病菌对井岗霉素敏感性研究初报[J].南京农业大学学报,1987,(增刊):152~153.
[81] 张承来 欧晓明.植物病原物对杀菌剂的抗药性机制概述[J].湖南化工,2000,30(5):7~10.
[82] Litterick AM, McQuilken MP. Chemical control of binucleate Rhizoctonia during propagation of Calluna vulgaris in Scotland [J]. Crop Protection, 1997, 16(2):173~178.
[83] Shu-Kang Chen, Clive A. Edwards, Scott Subler. Effects of the fungicides benomyl, captan and chlorothalonil on soil microbial activity and nitrogen dynamics in laboratory incubations [J]. Soil Biology&Biochemistry, 2001, 33:1971~1980.
[84] Cotterill PJ, Ballinger DJ, Kollmorgen JF. Evaluation of methods for the chemical control of rhizoctonia root rot of wheat [J]. Crop Protection, 1990, 9(4):275~280.
[85] 祁之秋.小麦纹枯病菌对常用杀菌剂敏感性基线及化学防治原理研究[D].江苏南京:南京农业大学,2001.
[86] Paparizas GP, Lewis JA, O'Neill NR. BAS 389, a new fungicide for control of Rhizoctonia solani [J]. Plant Disease, 1979, 63: 569~573.
[87] Martin SB, Lucas TL, Campbell CL. Comparative sensitivity of Rhizoctonia solani and Rhizoctonia-like fungi to selected fungicides in vitro [J]. Phytopathology, 1984, 74:778~781.
[88] Frisina TA, Benson DM. Sensitivity of binucleate Rhizoctonia spp. and R. solani to selected fungicides in vitro and on azalen under greenhouse conditions [J]. Plant Disease, 1988, 72:303~306.
[89] Thomas WD. Reaction of biotypes of Rhizoctonia solani to different fungicides [J]. Phytopathology, 1962, 52: 366.
[90] Ereniraut E. Adaptation of Rhizoctonia solani küehn to fungicides [J]. Communication V. UV induced mutants with complex resistance. 1977, 7(4):341~343.
[91] 郑丕尧主编.作物生理学导论[M].北京农业大学出版社,北京:1991,174~175.
[92] Allington WB. Sclerotial formation in Rhizoctonia solani was affected by nutritional and other factors [J]. Phytopathology, 1936, 26:831~844.
[93] Moromizatoz, Ishizaki F, Tadara K, et al. The effects of phosphorus and magnesium on sclerotium formation in Rhizoctonia solani Kühn [J]. Ann Phytopathol Soc Japan, 1991, 57: 649~656.
[94] 潘以楼 吴汉章.磷对禾谷丝核菌菌核形成的影响[J].植物病理学报,1995,25:314.
[95] 吴文希 谢廷芳.各种元素对高粱纹枯病菌的影响[J].植物保护学会会刊(台湾).1990,32(4):265~276.
[96] 檀根甲 丁克坚 季伯衡等.小麦纹枯病菌氮素营养的研究[J].应用生态学报,1997,8(4):396~398.
[97] 潘以楼 吴汉章.磷对禾谷丝核菌菌核形成的影响[J].植物病理学报,1994,25:314.
[98] Behera B.影响稻纹枯病菌菌核生长和产生的因素[J].Indian Journal Mycology plant pathology,1984,14(3):252~255.
[99] 林清 陶家凤.立枯丝核菌对C、N营养的需求[J].四川农业大学学报,1992,10(3):484~490.
[100] 羽柴辉良.Quantitation changes in nitrogen and starch contents in rice sheaths blight causal by Rhizoctonia solani kühn [J]. Ann Phytopathol Soc Japan, 1977, 43:1~8.
[101] 陈莉 李晓凤 丁克坚等.氮素营养对水稻纹枯病菌生长的影响[J].安徽农业科学,2002.30(2):240~243.
[102] 沈会芳 周而勋 戚佩坤.金属离子对水稻纹枯病菌菌丝生长和菌核形成的影响[J].华南农业大学学报,2002,23(1):38~40.
[103] 李熙英 吕龙石 权成武等.氮、磷、钾不同施肥水平下的水稻纹枯病的危害模型的研究[J].延边大学农学学报,1998,20(2):88~92.
[104] 汪万宝 魏俊章 叶明珠.氮磷钾与水稻纹枯病发生综合效应研究[J].安徽农业大学学报,1996,23(1):22~24.
[105] 范坤成 康霄文 彭绍裘.肥、水、菌对水稻纹枯病发生流行的综合效应[J].植物保护学报,1993,20(2):97~102.
[106] 王勇 杨秀荣 杨依军.茄病镰刀菌敏感株系对多菌灵抗药性风险及敏感性影响因素的研究[J].天津农业科学,2002,8(2):5~8.
[107] Kishor Chand, Tripathi N.N. Effect of agrochemicals on population of Rhizoctonia solani, Meloidogyne incognite and fungal antagonists under screenhouse conditions [J]. Annuals of Biology, 2002, 18(1): 67~69.
[108] 史建荣 王裕中 方中达.三唑酮、三唑醇对小麦纹枯病菌形态和生理的影响[J].植物病理
学报,1992,22(3):205~208.
[109] 陈茹梅 李金玉 康振生等.戊唑醇对小麦纹枯菌超微结构的影响[J].菌物系统.2000,19(3):389~395.
[110] 刘西莉 李健强 张龙.药剂对水稻立枯丝核菌的毒力及形态毒理作用[J].植物保护学报,2001,28(4):352~356.
[111] 朱华 黄奔立 倪桂花等.10种除草剂对水稻纹枯病的影响[J].扬州大学学报(农业与生命科学版),2002,23(2):71~73.
[112] Black BD, Russin JS, Giriffin JI, et al. Impact of soybean(Glycine max)herbicides on growth and development of Rhizoctonia solani AG1 in vitro and in field [J]. Phytopathology, 1995, 85: 508.
[113] Pathak D, Roy AK, Deka SC. Effect of herbicides on the growth and sclerotial survival of Rhizoctonia solani(Kuehn) [J]. Annala of Biology, 1996, 12(2): 245~251.
[114] 史建荣 王裕中 杨新宇等.麦田除草剂对小麦纹枯病的影响简报[J].江苏农业科学,1993,(专辑):89.
[115] 谢标洪 王建新 周明国.黄瓜白粉病菌对嘧菌酯的抗药性监测方法和敏感性基线研究[A].华东植物病理学术研讨会论文集[C].2003:284~288.
[116] 马严明 周明国.小麦白粉病菌对三唑酮的抗药性监测[A].华东植物病理学术研讨会论文集[C].2003:289~292.
[117] 陈厚德 王彰明 倪桂花.用嵌入法接种小麦纹枯病菌的研究[J].江苏农业科学,2002,5:31~32.
[118] 檀根甲 丁克坚 季伯衡.小麦纹枯病药剂防治技术[J].植物保护学报,1999,26(4):358~362.
[119] 祁之秋 周明国.小麦纹枯病菌对几种杀菌剂的敏感性基线研究[J].中国植物病害化学防治研究,第三卷:203~208.
[120] 倪桂花.非杀菌剂农药对小麦纹枯病菌生长及致病力的影响[D].江苏扬州:扬州大学农学院,2002.
[121] 檀根甲 陈莉 胡道平等.化学药剂对水稻纹枯病菌的影响[J].安徽农业科学,2000,28(2):200~201
[122] 朱华 黄奔立 倪桂花等.10种除草剂对水稻纹枯病的影响[J].扬州大学学报(农业与生命科学版),2002,23(2):71~73.
[123] 胡建章 杨金生 陈良根.不同施氮量对杂交水稻纹枯病、紫鞘病及云形病的影响[J].植物保护学报,1984,11(2):143~144.
[2] 朱尔玺.小麦纹枯病危害情况的调查[J].河南农林科技,1982,12:13.
[3] 周凯南.小麦纹枯病研究初报[J].山东农业科学,1982,3:33~36.
[4] 孟庆忠 刘志恒 王鹤影等.水稻纹枯病研究进展[J].沈阳农业大学学报,2001,32(5):376~381.
[5] 吴汉章 潘以楼.小麦纹枯病的发生与药剂防治的技术关键[J].江苏农业科学,1983,11:34~37.
[6] 丁友珍.贵州小麦纹枯病病原丝核菌的初步研究[J].贵州农学院学报,1986,2:87~89.
[7] 沈素文 王裕中 史建荣等.菌龄与温度对小麦纹枯病菌致病力的影响[J].江苏农业科学,1997.6:35~37.
[8] 陈厚德 王彰明 胡广淦等.几种与小麦纹枯病相关症状初步研究[J].江苏农业科学,1993,(专辑):30~31.
[9] 刘志恒.水稻纹枯病[J].新农业,2003,9:41~42.
[10] Blair JD. Studies on growth in soil and the parasitic action of certain Rhizoctonia solani isolates from wheat [J]. Can. J. Res, 1942, 20:174~185.
[11] Bruehl GW. Rhizoctonia solani in relation to cereal crown and root rot [J]. Phytopathology, 1951,41:375~377.
[12] Parmetor JR, Sherwood RT, Platt WD. Anastomosis group of among isolates of Thanatephorus cucumeris [J]. Phytopathology, 1969, 59:1270~1278.
[13] Boerema GH, Vander Hoeven A. A. Check-list for scientific names of common parasitic fungi series 26: Fungi on field crops: cerealis and grasses [J]. Neth. J. Plant pathol., 1976,83:165~204.
[14] 陈延熙 唐文华 张敦华等.我国小麦纹枯病病原学的初步研究[J].植物保护,1986,13(1):39~44.
[15] 李清铣.江苏几种作物病原丝核菌生物学特性研究[J].江苏农学院学报,1988,9(3):23~26.
[16] 史建荣 王裕中 陈怀谷等.小麦纹枯病菌的菌丝融合群及其致病力测定[J].江苏农业科学,
1993,(专辑):25~29.
[17] 杨小军 杨立军 赵永玉等.湖北省小麦纹枯病病原菌菌丝融合群的致病力研究[J].华中农业大学学报,2000,19(2):106-110.
[18] 夏正俊 李清铣.江苏省大、小麦纹枯病病原学的初步研究[J].植物病理学报,1989,19(3):136~139.
[19] 陆家云主编.植物病害诊断[M].中国农业出版社,1995:177.
[20] 李华荣.丝核菌的菌丝融合群及其遗传多样性研究的新进展[J].菌物系统,1999,18(1):100~107.
[21] 陈延熙.关于Rhizoctonia solani菌丝融合群分类和有性世代的研究[J].植物病理学报,1985,15(3):139~142.
[22] 杜金池.关于Rhizoctonia solani之菌丝融合群及其对水稻之病原性[J].水稻病虫害,1987,12:263~285.
[23] 王裕中 杨新宁 史建荣等.麦类纹枯病防治研究Ⅰ:大、小麦及其轮作物丝核菌的生物学特性与致病力比较[J].江苏农业学报,1986,2(4):29~35.
[24] 檀根甲 季伯衡.小麦纹枯病的研究进展(综述)[J].安徽农业大学学报,1998,25(1):70~75.
[25] 江苏省麦类纹枯病综合防治研究协作组.江苏省麦类纹枯病病原学研究[J].江苏农业科学,1993,(专辑):17~24.
[26] 张敏 陶家凤.立枯丝核菌菌丝融合群培养性状比较[J].四川农业大学学报,1993,11(4):568~573.
[27] 潘以楼 吴汉章.江苏小麦纹枯病菌CAG_1群菌株的特性和致病力分化[J].江苏农业科学,1993,(专辑):35~39.
[28] 李华荣 颜思齐.四川省东、南部稻区水稻纹枯病菌系研究[J].真菌学报,1990,9(1):41~49.
[29] 邓先明.四川省西、北部稻区水稻纹枯病菌系研究[J].西南农业大学学报,1991,13(4):380~383.
[30] 王裕中 吴志凤 史建荣等.江苏省小麦纹枯病发生规律与病害消长因素分析[J].植物保护学报,1994,22(2):109~114.
[31] 李华荣.小麦纹枯病病情消长与气象因子研究[J].西南农业大学学报,1993,15(3):247~249.
[32] 路兴波.小麦品种抗纹枯病鉴定[J].植物保护学报,1999,26(3):283~284.
[33] 郑重.国外水稻纹枯病研究进展[J].植物保护,1992,16(2):52~53.
[34] 李清歌.小麦纹枯病发生与栽培因素关系调查[J].河南农业科学,1993,10:22.
[35] 刘文娟 任寿美 金志高.泰县小麦纹枯病发生规律研究[J].江苏农业科学,1993,(专辑):57~59.
[36] Musthafa K, Potty N.N. Incidence of pests and diseases in rice as influenced by fertilizer application and in situ green manuring [J]. Journal of Tropical Agriculture, 2001, 39(2):194~196.
[37] 刘述英 杨幼平 张晓平.小麦纹枯病发生规律及综合防治[J].四川农业科技,1997,3:18~19.
[38] 万有莲 付春坤 章永发.水稻纹枯病发生与防治[J].云南农业,1997,6:16.
[39] Roy AK. Indian Phytopathology, 1985, 38: 45~49.
[40] Laha GS, Venkataraman S. Sheath blight management in rice with biocontrol agents [J]. Indian Phytopathology, 2001, 54(4):461~464.
[41] 王金生 张学君 李洪连等.小麦纹枯病生防菌株B_3产生抗菌物质条件的研究[J].南京农业大学学报,1995,1(26):45~48.
[42] 赵洪义 郭凤芝.小麦纹枯病发生规律和防治技术[J].河南农业科学.1998,1:12~14.
[43] 史建荣 王裕中 陈怀谷等.戊唑醇种子处理防治小麦纹枯病[J].植物保护学报,2000,27(3):231~237.
[44] 史建荣.粉锈宁、利克菌等农药拌种防治小麦纹枯病试验初报[J].江苏农业科学,1989,8:15~16.
[45] 魏先锋.小麦纹枯病药剂防治试验初报[J].江苏农业科学,1989,4:24~25.
[46] 吴洵耻 高士仁.我国小麦纹枯病发生及防治研究现状[J].山东农业科学,1992,2:29~30.
[47] 吕国强 乔清建 丁存.小麦中后期综合施药技术[J].河南科技,1994,3:10.
[48] 潘以楼 张郭阳.稀唑醇拌种对大、小麦纹枯病防效[J].农药,1990,29(1):56~57.
[49] 王裕中.小麦纹枯病的发生与防治[J].植保技术推广,2001,21(8):39~41.
[50] Davis J.R. Sensitivity of sharp eyespot on wheat and Rhizoctonia cerealis to fungicide [J]. Test of agrochemicals and cultivars of aab., 1983, 102(4): 54~55.
[51] Marsh, U. H.W. Evaluation of fungicides for the control of sharp eyespot infection of wheat [J]. Test of agrochemicals and cultivars of aab., 1984, 104(5):46~47.
[52] Barnes, G.N. Control of eyespot with formulations of prochloraze and carbendazim, Med Fec [J]. Land-bouww, Rijksuniv Gent, 1983, 48(3):559~564.
[53] Dekker J. Bacterial plant disease control fungicides [J]. World Review of Pest Control, 1971, 10:9~23.
[54] 吴军林 林炜铁 彭运平等.防治植物病害的农用抗生素研究及应用[J].新农药,2003,4:27~30.
[55] 沈寅初.农用抗生素研究开发的新进展[J].国外医药抗生素分册,1998,19(2):155~160.
[56] 沈寅初.井岗霉素研究开发25年[J].植物保护,1996,22(4):44~45.
[57] 田中信号.抗菌素的作用机制[M].《抗菌素的作用机制》翻译组译.1977,北京:科学出版社.
[58] Trinci A.P.J. Effect of Validamycin A and L-sorbose on the growth and morphology of Rhizoctonia cerealis and Rhizoctonia solani [J]. Exp-Mycol, 1985, 9(1):20~27.
[59] Endo T, Matsuura K, Wakae O. Effect of Validamycin A on infection of Rhizoctonia solani in rice sheaths [J]. Ann Phytopathol Soc Jap, 1983, 49(5):689~697.
[60] Robson GD, Kuhn PJ, Trinci APJ. Effects of Validamycin A on the morphology, growth and sporulation of Rhizoctonia cerealis, Fusarium culmorum and other fungi [J]. J-Gen-Microbiol,Society for General Microbiology, 1988, 134(12):3187~3194.
[61] Hugh D. Sisler. Control of fungal diseases by compounds acting as antipenetrants [J]. Crop Protection, 1986, 5(5):306~313.
[62] 谢彦洁 张君成 陈育新等.多菌灵和井岗霉素对香蕉苗纹枯病的作用方式测定[J].广西植保,1999,12(2):2~4.
[63] 张穗 郭永霞 唐文华等.井岗霉素A对水稻纹枯病菌的毒力和作用机理研究[J].农药学学报,2001,3:31~37.
[64] Naoki Asano, Katsuhiko latsui, Satosi Takeda, et al. Microbial preparation of α,α'-[1, 1'-~(13)C] trehalose [J]. Carbohydrate Research, 1993,243(1):71~78.
[65] Muller J, Boller T, Wiemken A. Effects of Validamycin A, a potent trehalase inhibitor, and phytohormones on trehalose metabolism in roots and root nodules of soybean and cowpea [J]. Planta,1995, 197(2): 362~368.
[66] Wake O. First Intersect. Comgr[J]. IAMS, Sci Counc. Jap, 1975, 3: 65~67.
[67] 黄昌华 杨丹 姚学英.井岗霉素——不易产生抗性的抗菌素[J].湖北植保,1994,2:18~19.
[68] Dekker J. Development of resistance to agricultural antibiotic [J]. Fungicide Resistance in Crop Protection, 1982: 269~275.
[69] Miura H. Mode of occurance of Kasugamycin resistant rice blast fungus [J]. Ann, Phytopathol. Soc. Jpn, 1976, 41:117~123.
[70] Schroth MN. Streptomycin resistance in Erwinia amylovora [J]. Plant Path, 1978, 4: 527.
[71] Wolfe MS. Dynamics of the response of barley mildew to the use of sterol synthesis inhibitors [J]. EPPO Bull, 1985, 15: 451~457.
[72] 杨勤作.井岗霉素施药量已明显增加[J].农药通讯,1983,46(10):2.
[73] 周明国 叶钟音 刘经芬.稻纹枯病菌对井岗霉素抗药性检测、监测和诱导[J].中国水稻科学,1991,5(2):73~78.
[74] 周明国 叶钟音 刘经芬.杀菌剂抗性研究进展[J].南京农业大学学报,1994,17(3):33~41.
[75] 金梅松 蒋文烈.浙江省水稻纹枯病菌对井岗霉素的抗药性测定[J].浙江农业学报,1997,9(3):127~130.
[76] 张穗 周梅先.河南省固始等地稻纹枯病菌对井岗霉素的敏感性[J].植物保护学报,1999,26(2):189~190.
[77] 张穗 许文霞 薛银根等.郑州郊区水稻纹枯病菌对井岗霉素敏感性的初步研究[J].中国生物防治,1995,11(4):171~173.
[78] 沈永安 王力.吉林省水稻纹枯病发生与防治研究初报[J].吉林农业科学,1989,3:9~14.
[79] 史建荣 王裕中.三唑酮、三唑醇和井岗霉素对小麦纹枯病菌生长和侵染的影响[J].江苏农业科学,1993,(专辑):173~175.
[80] 刘经芬 周明国 叶钟音.江苏小麦纹枯病菌对井岗霉素敏感性研究初报[J].南京农业大学学报,1987,(增刊):152~153.
[81] 张承来 欧晓明.植物病原物对杀菌剂的抗药性机制概述[J].湖南化工,2000,30(5):7~10.
[82] Litterick AM, McQuilken MP. Chemical control of binucleate Rhizoctonia during propagation of Calluna vulgaris in Scotland [J]. Crop Protection, 1997, 16(2):173~178.
[83] Shu-Kang Chen, Clive A. Edwards, Scott Subler. Effects of the fungicides benomyl, captan and chlorothalonil on soil microbial activity and nitrogen dynamics in laboratory incubations [J]. Soil Biology&Biochemistry, 2001, 33:1971~1980.
[84] Cotterill PJ, Ballinger DJ, Kollmorgen JF. Evaluation of methods for the chemical control of rhizoctonia root rot of wheat [J]. Crop Protection, 1990, 9(4):275~280.
[85] 祁之秋.小麦纹枯病菌对常用杀菌剂敏感性基线及化学防治原理研究[D].江苏南京:南京农业大学,2001.
[86] Paparizas GP, Lewis JA, O'Neill NR. BAS 389, a new fungicide for control of Rhizoctonia solani [J]. Plant Disease, 1979, 63: 569~573.
[87] Martin SB, Lucas TL, Campbell CL. Comparative sensitivity of Rhizoctonia solani and Rhizoctonia-like fungi to selected fungicides in vitro [J]. Phytopathology, 1984, 74:778~781.
[88] Frisina TA, Benson DM. Sensitivity of binucleate Rhizoctonia spp. and R. solani to selected fungicides in vitro and on azalen under greenhouse conditions [J]. Plant Disease, 1988, 72:303~306.
[89] Thomas WD. Reaction of biotypes of Rhizoctonia solani to different fungicides [J]. Phytopathology, 1962, 52: 366.
[90] Ereniraut E. Adaptation of Rhizoctonia solani küehn to fungicides [J]. Communication V. UV induced mutants with complex resistance. 1977, 7(4):341~343.
[91] 郑丕尧主编.作物生理学导论[M].北京农业大学出版社,北京:1991,174~175.
[92] Allington WB. Sclerotial formation in Rhizoctonia solani was affected by nutritional and other factors [J]. Phytopathology, 1936, 26:831~844.
[93] Moromizatoz, Ishizaki F, Tadara K, et al. The effects of phosphorus and magnesium on sclerotium formation in Rhizoctonia solani Kühn [J]. Ann Phytopathol Soc Japan, 1991, 57: 649~656.
[94] 潘以楼 吴汉章.磷对禾谷丝核菌菌核形成的影响[J].植物病理学报,1995,25:314.
[95] 吴文希 谢廷芳.各种元素对高粱纹枯病菌的影响[J].植物保护学会会刊(台湾).1990,32(4):265~276.
[96] 檀根甲 丁克坚 季伯衡等.小麦纹枯病菌氮素营养的研究[J].应用生态学报,1997,8(4):396~398.
[97] 潘以楼 吴汉章.磷对禾谷丝核菌菌核形成的影响[J].植物病理学报,1994,25:314.
[98] Behera B.影响稻纹枯病菌菌核生长和产生的因素[J].Indian Journal Mycology plant pathology,1984,14(3):252~255.
[99] 林清 陶家凤.立枯丝核菌对C、N营养的需求[J].四川农业大学学报,1992,10(3):484~490.
[100] 羽柴辉良.Quantitation changes in nitrogen and starch contents in rice sheaths blight causal by Rhizoctonia solani kühn [J]. Ann Phytopathol Soc Japan, 1977, 43:1~8.
[101] 陈莉 李晓凤 丁克坚等.氮素营养对水稻纹枯病菌生长的影响[J].安徽农业科学,2002.30(2):240~243.
[102] 沈会芳 周而勋 戚佩坤.金属离子对水稻纹枯病菌菌丝生长和菌核形成的影响[J].华南农业大学学报,2002,23(1):38~40.
[103] 李熙英 吕龙石 权成武等.氮、磷、钾不同施肥水平下的水稻纹枯病的危害模型的研究[J].延边大学农学学报,1998,20(2):88~92.
[104] 汪万宝 魏俊章 叶明珠.氮磷钾与水稻纹枯病发生综合效应研究[J].安徽农业大学学报,1996,23(1):22~24.
[105] 范坤成 康霄文 彭绍裘.肥、水、菌对水稻纹枯病发生流行的综合效应[J].植物保护学报,1993,20(2):97~102.
[106] 王勇 杨秀荣 杨依军.茄病镰刀菌敏感株系对多菌灵抗药性风险及敏感性影响因素的研究[J].天津农业科学,2002,8(2):5~8.
[107] Kishor Chand, Tripathi N.N. Effect of agrochemicals on population of Rhizoctonia solani, Meloidogyne incognite and fungal antagonists under screenhouse conditions [J]. Annuals of Biology, 2002, 18(1): 67~69.
[108] 史建荣 王裕中 方中达.三唑酮、三唑醇对小麦纹枯病菌形态和生理的影响[J].植物病理
学报,1992,22(3):205~208.
[109] 陈茹梅 李金玉 康振生等.戊唑醇对小麦纹枯菌超微结构的影响[J].菌物系统.2000,19(3):389~395.
[110] 刘西莉 李健强 张龙.药剂对水稻立枯丝核菌的毒力及形态毒理作用[J].植物保护学报,2001,28(4):352~356.
[111] 朱华 黄奔立 倪桂花等.10种除草剂对水稻纹枯病的影响[J].扬州大学学报(农业与生命科学版),2002,23(2):71~73.
[112] Black BD, Russin JS, Giriffin JI, et al. Impact of soybean(Glycine max)herbicides on growth and development of Rhizoctonia solani AG1 in vitro and in field [J]. Phytopathology, 1995, 85: 508.
[113] Pathak D, Roy AK, Deka SC. Effect of herbicides on the growth and sclerotial survival of Rhizoctonia solani(Kuehn) [J]. Annala of Biology, 1996, 12(2): 245~251.
[114] 史建荣 王裕中 杨新宇等.麦田除草剂对小麦纹枯病的影响简报[J].江苏农业科学,1993,(专辑):89.
[115] 谢标洪 王建新 周明国.黄瓜白粉病菌对嘧菌酯的抗药性监测方法和敏感性基线研究[A].华东植物病理学术研讨会论文集[C].2003:284~288.
[116] 马严明 周明国.小麦白粉病菌对三唑酮的抗药性监测[A].华东植物病理学术研讨会论文集[C].2003:289~292.
[117] 陈厚德 王彰明 倪桂花.用嵌入法接种小麦纹枯病菌的研究[J].江苏农业科学,2002,5:31~32.
[118] 檀根甲 丁克坚 季伯衡.小麦纹枯病药剂防治技术[J].植物保护学报,1999,26(4):358~362.
[119] 祁之秋 周明国.小麦纹枯病菌对几种杀菌剂的敏感性基线研究[J].中国植物病害化学防治研究,第三卷:203~208.
[120] 倪桂花.非杀菌剂农药对小麦纹枯病菌生长及致病力的影响[D].江苏扬州:扬州大学农学院,2002.
[121] 檀根甲 陈莉 胡道平等.化学药剂对水稻纹枯病菌的影响[J].安徽农业科学,2000,28(2):200~201
[122] 朱华 黄奔立 倪桂花等.10种除草剂对水稻纹枯病的影响[J].扬州大学学报(农业与生命科学版),2002,23(2):71~73.
[123] 胡建章 杨金生 陈良根.不同施氮量对杂交水稻纹枯病、紫鞘病及云形病的影响[J].植物保护学报,1984,11(2):143~144.